Abstract
We study the one-dimensional discrete time totally asymmetric simple exclusion process with parallel update rules on a spatially periodic domain. A multi-point space-time joint distribution formula is obtained for general initial conditions. The formula involves contour integrals of Fredholm determinants with kernels acting on certain discrete spaces. For a class of initial conditions satisfying certain technical assumptions, we are able to derive large-time, large-period limit of the joint distribution, under the relaxation time scale \(t=O(L^{3/2})\) when the height fluctuations are critically affected by the finite geometry. The assumptions are verified for the step and flat initial conditions. As a corollary we obtain the multi-point distribution of discrete time TASEP on the whole integer lattice \({\mathbb {Z}}\) by taking the period L large enough so that the finite-time distribution is not affected by the boundary. The large time limit for the multi-time distribution of discrete time TASEP on \({\mathbb {Z}}\) is then obtained for the step initial condition.
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1 Introduction
Models in the one-dimensional Kardar–Parisi–Zhang (KPZ) universality class are expected to have the same limiting height fluctuations under the \(t:t^{2/3}:t^{1/3}\) KPZ scaling for temporal correlations, spatial correlations and height fluctuations. Describing the universal limiting fluctuating field and proving the convergence of concrete models to the universal limiting field have been the main goals in the field and attracted active research over the last two decades. The convergence to the limiting fluctuating field (at one-point or multi-point level) have been obtained for a large class of models (mostly exactly solvable), either for the whole space models [2, 8,9,10,11, 13, 15, 16, 20, 21], or for half space models [1, 6, 7].
More recently similar limit theorems were obtained for models on periodic domains. Such models are defined on a finite ring of size L instead of on the infinite or semi-infinite lattices. The crucial interest here is to understand the effect of this finite geometry on the height fluctuations. For periodic models the one-point marginals of limiting height fluctuations were obtained for classical step, flat and stationary initial conditions in [3, 14], and independently in [19] under the so-called relaxation time scale \(t=O(L^{3/2})\) when the height fluctuations are critically affected by the finite geometry. Further extensions including formulas for multi-point space-time joint distributions were subsequently obtained in [4] for step initial condition and [5] for more general initial conditions. These limiting formulas are expected to be universal for all related models on periodic domains. So far all limiting distribution formulas were obtained as scaling limits of finite-time joint distributions of a single model in the KPZ universality class, namely the continuous time periodic totally asymmetric simple exclusion process (TASEP on a ring).
The goal of this paper is to study another classical model in the KPZ universality class, the discrete time totally asymmetric exclusion process with parallel updates, on periodic domains. On the infinite lattice \({\mathbb {Z}}\), this model has been well studied. The one-point marginal distribution was obtained in [11] for the equivalent geometric last passage percolation model and joint distributions of several locations at equal time was obtained in [9]. Recently the joint distributions along the time direction have also been studied, in [12] for two-time case and [13] for general multi-time joint distributions. However on the periodic domain there are fewer results concerning height fluctuations (see [18] for some results on transition probability and stationary distributions), which are the main focuses of this paper. The main results of this paper are summarized as follows:
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(1)
For general initial conditions we obtain a finite-time multi-point (in both space and time) joint distribution formula for discrete time parallel periodic TASEP. The formula consists of an m-fold (m is the number of space-time points being considered in the joint distribution) contour integral with integrand involving a Fredholm determinant, where the Fredholm determinant has kernels acting on certain discrete sets related to the roots of some polynomials.
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(2)
Under the relaxation time scale \(t=O(L^{3/2})\) and the 1 : 2 : 3 KPZ scaling, we obtain large-time, large-period limits for the multi-point joint distributions under certain assumptions on the initial condition, which are verified for the step and flat cases. These limiting formulas agree with those obtained in [4, 5], thus providing an evidence that the height fluctuations for periodic models in the KPZ class are in fact universal.
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(3)
We also obtain the same type of multi-point joint distribution formula for discrete time TASEP on the infinite lattice \({\mathbb {Z}}\), by relating it with the corresponding periodic model with large enough period so that the finite-time distribution is not affected by the boundary. The large time limit for the multi-time distribution formula under KPZ scaling is then derived for step initial condition, which agrees with the one in [15].
Comparing to the previous work [4, 5, 15] on the multi-point distributions of continuous time TASEP, on either periodic domain or \({\mathbb {Z}}\), our work consists of formulas with similar structures but involves an extra parameter p describing the hopping probability, which makes the algebraic properties a bit more complicated. In particular the polynomial whose roots are related to the kernels in the periodic formulas now depends on the extra parameter p. We point out that all the formulas for continuous time TASEP can be obtained from our formulas by rescaling the time and taking \(p\rightarrow 0\).
On the infinite lattice \({\mathbb {Z}}\), the multi-time distribution of discrete time TASEP (more precisely the equivalent geometric last passage percolation model) has been considered recently in [13], where a formula involving contour integrals of Fredholm determinants was obtained. We expect our formulas to agree with the formulas in [13], both in finite time and for the large time limit. Currently we are not able to prove the equivalence of the two types of formulas though they share a lot of similarities.
1.1 Outline of the paper
In Sect. 2 we describe the discrete time parallel TASEP models and state the main results involving several multi-point joint distribution formulas, for both periodic domain and infinite lattice \({\mathbb {Z}}\), finite time and large time limit. In Sects. 3, 4 and 5 we derive the main finite-time algebraic formulas for multi-point distribution of discrete time parallel periodic TASEP and we regard them as the main technical novelties in this paper. In particular in Sect. 3 we prove a novel transition probability formula for discrete time parallel TASEP on the periodic domain. The formula involves integral of determinants and is proved using coordinate Bethe ansatz. In Sect. 4 we derive the finite-time multi-point distribution formula by performing a multiple sum over the transition probabilities. The key ingredients are certain Cauchy-type summation identities over the eigenfunctions of the generator, which might be of independent interests so we discuss the proof in Sect. 5. In Sects. 6 and 7 we discuss the large time, large period asymptotics for the multi-point distribution under the relaxation time scale \(t=O(L^{3/2})\). Finally in Sect. 8 we derive the multi-time distribution for infinite discrete time parallel TASEP and perform large time asymptotics under KPZ scaling for the step initial condition.
2 Models and main results
Let \(N<L\) be positive integers. We consider discrete time TASEP with parallel updates with N particles on a spatially periodic domain of size L. It is convenient to view the dynamics as particles moving to the right on the integer lattice \({\mathbb {Z}}\) while periodicity forces particle configurations to be identical copies of each other every L sites. More precisely this means that the occupation functions \(\eta _j(t)\) which equals 1 if there is a particle at site \(j\in {\mathbb {Z}}\) at time t and equals 0 otherwise should satisfy
We fix a single period of size L and denote the locations of totally N particles in this period at time t as
Here \(x_i(t)\in {\mathbb {Z}}\) for \(1\le i\le N\) and we index the particles from right to left. The locations of all the particles then satisfy \(x_{i+kN}(t)= x_i(t)-kL\) for \(1\le i\le N\) and \(k\in {\mathbb {Z}}\) so that we have
Thus the natural configuration space for the particles should be
The discrete time parallel periodic TASEP with N particles, period L and hopping probability \(0<p<1\), which we denote by \(\mathrm {dpTASEP}(L,N,p)\), is the following Markovian dynamics on particle configurations \({\vec {x}}(t)\in {\mathcal {X}}_{N}^{(L)}\): at each time step, each particle in a single period hops to its right neighbor site independently with probability \(p=1-q\) provided that the site is empty, otherwise it stays at its current position. As a special case, the discrete time parallel TASEP on \({\mathbb {Z}}\) which we will denote by \(\mathrm {dTASEP}(p)\) corresponds to particles following the same evolution rules with the period \(L\rightarrow \infty \). In this case the configuration space for the first N particles (from right to left, we assume the existence of a right-most particle) becomes
Notation 2.1
Throughout the paper there will be several very similar formulas and quantities corresponding to either discrete time parallel TASEP on a periodic domain with size L or on the infinite lattice \({\mathbb {Z}}\), as well as their scaling limits. To avoid confusion we will always follow the convention used in (2.2) and (2.3) by putting superscripts (L) to any quantities related to periodic model in finite-time and \((\infty )\) to any quantities related to model on the infinite lattice \({\mathbb {Z}}\) in finite-time. On the other hand quantities describing the large-time limits will have superscripts \((\mathrm {per})\) and \((\mathrm {kpz})\) for periodic and infinite models, respectively.
The main results of the paper consist of several formulas for multi-point joint distributions of discrete time parallel TASEP on periodic domain and on \({\mathbb {Z}}\) as well as their large time scaling limits. All of them are expressed as contour integrals of Fredholm determinants. The main difference is that the formulas for periodic models are expressed in terms of discrete sets related to roots of certain algebraic equations, while the Fredholm determinant appearing in formulas for discrete time TASEP on \({\mathbb {Z}}\) has kernels acting on continuous contours.
2.1 Multi-point distribution formulas for \(\mathrm {dpTASEP}(L,N,p)\)
The first theorem is a finite-time multi-point joint distribution formula for discrete time TASEP on a periodic domain. This is the starting point of all other results in this paper.
Theorem 2.2
(Finite-time multi-point joint distribution for \(\mathrm {dpTASEP}(L,N,p,{\vec {y}})\)). Let \(N<L\) be integers. Consider discrete time periodic parallel TASEP with hopping probability \(0<p<1\), N particles and L sites per period (denoted by \(\mathrm {dpTASEP}(L,N,p,{\vec {y}})\)). Here \({\vec {y}}\in {\mathcal {X}}_{N}^{(L)}\) is the initial condition, i.e., \(x_i(0)=y_i\) for \(1\le i\le N\). Set \(\rho =N/L\). Fix a positive integer m and let \((k_i,t_i)\), \(1\le i\le m\) be m distinct points in \({\mathbb {Z}}\times {\mathbb {Z}}_{\ge 0}\) satisfying \(0\le t_1\le \cdots \le t_m \). Then for any integers \(a_1,\ldots ,a_m\),
Hre we denote \({\vec {z}}:=(z_1,\ldots ,z_m)\). The contours are over nested circles centered at the origin: \(0<|z_m|<\cdots<|z_1|<\mathbbm {r}_c\), where \(\mathbbm {r}_c\) is a parameter depending on p and \(\rho \) that is defined in (2.16). Here and in all the remaining results we suppress the dependence of the integrand on the parameters \(a_i,k_i,t_i\) as well as the hopping probability \(0<p<1\). The function \({\mathscr {C}}_{{\vec {y}}}^{(L)}({\vec {z}})\) is defined in Definition 2.14. The function \({\mathscr {D}}_{{\vec {y}}}^{(L)}({\vec {z}})\) is a Fredholm determinant
where the operators \({\mathscr {K}}_{1}^{(L)}\) and \({\mathscr {K}}_{{\vec {y}}}^{(L)}\) are defined in Definition 2.15.
Remark 2.3
Theorem 2.2 generalizes Theorem 3.1 of [5] (and also Theorem 4.6 of [4] for the special step initial condition) on the finite-time multi-point distribution of continuous time periodic TASEP. In fact their formulas can be obtained from our formula (2.4) by taking \(p=\epsilon \), \({\hat{t}}= \epsilon t\) and letting \(\epsilon \rightarrow 0\).
Next we state the theorem on the large-time, large-period scaling limit of (2.4) under the relaxation time scale \(t=O(L^{3/2})\). To emphasize the dependence on the initial condition, we add the subscript “\(\mathrm {ic}\)” for the terms in the limit which depend on the initial conditions. For convenience we make the following choice of labelling: we assume that \(x_1(0)\le 0 < x_{0}(0)\). This is equivalent with assuming that the initial condition satisfies \(y_1\le 0< y_N+L\).
Theorem 2.4
(Relaxation time limit). Consider a sequence of Markovian dynamics \(\mathrm {dpTASEP}(L, N, {\vec {y}}(L))\) depending on the period L, where \(\rho =\rho _L=N/L\) stays in a compact subset of (0, 1) and \(y_1\le 0<y_N+L\). Suppose that the sequence of initial conditions \({\vec {y}}(L)\) satisfies certain assumptions (see Assumption 6.2). Fix a positive integer m and let \(\mathrm {p}_j = (\gamma _j,\tau _j)\) be m points in the region
satisfying
Then for every fixed \(\mathrm {x}_1,\ldots ,\mathrm {x}_m\in {\mathbb {R}}\) and parameters \(a_i, k_i, t_i\), \(1\le i\le m\) given by
we have
Here the constants \(c_i\) depend explicitly on particle density \(0<\rho <1\) and hopping probability \(0<p<1\) and are given by
where we set \(\nu :=\sqrt{1-4p\cdot \rho (1-\rho )}\) for convenience. We recall that in (2.7) \({\mathbb {P}}^{(L)}\) denotes the probability associated to \(\mathrm {dpTASEP}(L, N, {\vec {y}}(L))\). The function \({\mathbb {F}}_{\mathrm {ic}}^{\mathrm {per}}(\cdot )\) agrees with the one defined in Section 6.4 of [5] as the relaxation time limit of multi-point distribution of continuous time periodic TASEP. We recall the definition of \({\mathbb {F}}_{\mathrm {ic}}^{\mathrm {per}}(\cdot )\) in Sect. 6.3 for completeness. The convergence is locally uniform in \(\mathrm {x}_j, \tau _j\), and \(\gamma _j\).
2.2 Multi-point distribution formulas for \(\mathrm {dTASEP}(p)\)
The finite-time multi-point joint distribution for discrete time parallel TASEP on \({\mathbb {Z}}\) can be obtained from Theorem 2.2 as a corollary. The rough idea is to take the period L sufficiently large so that the finite-time formula is unaffected by the boundary. The precise procedure is more delicate and will be explained in Sect. 8. For simplicity we will only state result on step initial condition but we point out that in [15] similar multi-time formulas for continuous time TASEP was obtained for general initial conditions and we believe their arguments can also be adapted to our model. The main result is the following:
Theorem 2.5
(Finite-time multi-point joint distribution for \(\mathrm {dTASEP}(p)\)). Assume \({\vec {y}}=(-1,-2,\ldots ,-N)\). Consider discrete time parallel TASEP on \({\mathbb {Z}}\) with initial particle locations \(x_i(0)=y_i\) for \(1\le i\le N\). Let \(m\ge 1\) be a positive integer and \((k_1,t_1),\ldots , (k_m,t_m)\) be m distinct points in \(\{1,\ldots ,N\}\times {\mathbb {Z}}_{\ge 0}\). Assume that \(0\le t_1\le \cdots \le t_m\). Then, for any integers \(a_1,\ldots ,a_m\),
where the integral contours are circles centered at the origin of radii less than 1. The function \({\mathcal {D}}_{\mathrm {step}}^{(\infty )}(\theta _1,\ldots ,\theta _{m-1})\) is defined in terms of a Fredholm determinant in Definition 2.16.
Remark 2.6
Under the standard coupling between discrete time parallel TASEP and geometric last passage percolation, we have the following equality in distributions:
where G(m, n) is the point-to-point last passage time from (0, 0) to (m, n) in the usual geometric last passage percolation model with parameter \(q=1-p\). For the right-hand side of (2.10) a formula of similar form as (2.9) was obtained in Theorem 2 of [13]. We expect the two formulas to be equivalent but currently we are not able to prove it for \(m\ge 2\).
Starting from the finite-time formula, we can then take large-time limit under the 1 : 2 : 3 KPZ scaling.
Theorem 2.7
Consider discrete time parallel TASEP on \({\mathbb {Z}}\) with step initial condition \(x_i(0)= -i\). We rescale the parameters such that
where \(q=1-p\). Then
Here \(\mathrm {D}_{\mathrm {step}}^{\mathrm {kpz}}(\theta _1,\ldots ,\theta _{m-1})\) is a Fredholm determinant defined in Definition 8.4. We remark that the right-hand side of (2.12) agrees with the right-hand side of equation (2.19) in [15], with the re-scaled parameters changed from \((\tau _i,\gamma _i, \mathrm {x}_i)\) to \((\tau _i,2x_i, h_i)\). Our parameters are chosen to be consistent with the periodic cases.
2.3 Bethe equations and Bethe roots
For our analysis on the discrete time periodic TASEP, the following polynomial and its roots play essential role:
Definition 2.8
(Bethe roots). Given \(z\in {\mathbb {C}}\) and \(0<p<1\). Define the degree L polynomial \(q_z(w)\) by
We call this polynomial the Bethe polynomial associated to z and its roots the Bethe roots. We denote the set of all roots of the Bethe polynomial \(q_z(w)\) by \({\mathcal {S}}_z\):
The Bethe root set \({\mathcal {S}}_z\) is contained in the level set \(\{w\in {\mathbb {C}}: |w|^\rho |1+w|^{1-\rho }=|z|\cdot |1+pw|^{\rho }\}\), which is sometimes called a deformed Cassini oval. For given jumping rate p and density \(\rho \), there exists a critical radius \(|z|=\mathbbm {r}_c\) for the level sets. For such critical z, the level set contains a self-intersecting point at \(w=w_c\). Here
and
It is not hard to check that for \(|z|<\mathbbm {r}_c\), the level set consists of two disjoint contours while for \(|z|>\mathbbm {r}_c\) the two contours merge to a single contour. For \(z=\mathbbm {r}_c\) there is a self-intersecting point for the contour at \(w=w_c\). See Fig. 1 for an illustration. We remark that the Bethe polynomials (and their roots) we are considering here are one-parameter generalizations of those considered in [3,4,5] which is related to continuous time periodic TASEP and corresponds to \(p= 0\) degenerations of (2.13).
Definition 2.9
(Left and right Bethe roots). For \(|z|<\mathbbm {r}_c\), we define the sets
where \(w_c\) and \(\mathbbm {r}_c\) are defined in (2.15) and (2.16). Then it is straightforward to check that \(|{\mathcal {L}}_z|=L-N\) and \(|{\mathcal {R}}_z|=N\). Roots in \({\mathcal {L}}_z\) and \({\mathcal {R}}_z\) are called left and right Bethe roots, respectively. We also define the left and right Bethe polynomials \(q_{z,\mathrm {L}}(w)\) and \(q_{z,\mathrm {R}}(w)\) as the monic polynomials with roots in \({\mathcal {L}}_z\) and \({\mathcal {R}}_z\):
Then by definition we have
2.4 A symmetric function related to initial conditions
In our finite-time multi-point distribution formula (2.4), the quantities encoding information in the initial condition are all related to the following symmetric function:
Definition 2.10
(Symmetric function). Given \(p\in {\mathbb {C}}\) and \(\lambda = (\lambda _1,\ldots ,\lambda _N)\in {\mathbb {Z}}^N\) with \(\lambda _{1}\ge \cdots \ge \lambda _N\). We define
Remark 2.11
The symmetric function \({\mathcal {F}}_\lambda \) defined here is a one-parameter generalization of the Grothendieck-like symmetric function defined in equation (3.6) of [5] which corresponds to the \(p=0\) degeneration in our situation.
The following two quantities related to \({\mathcal {F}}_{\lambda }\) encode the initial condition:
Definition 2.12
(Global energy and characteristic function) For \({\vec {y}}\in {\mathcal {X}}_{N}^{(L)}\), we set
For \(|z|<\mathbbm {r}_c\), we define the global energy \({\mathcal {E}}_{{\vec {y}}}(z)\) by
When \({\mathcal {E}}_{{\vec {y}}}(z)\ne 0\), we define the characteristic function \(\chi _{{\vec {y}}}(v,u;z)\) for a left Bethe root u and a right Bethe root v by
Remark 2.13
A straightforward calculation shows that for step initial condition \({\vec {y}}=(-1,\ldots ,-N)\), we have \({\mathcal {F}}_{\lambda ({\vec {y}})}\equiv 1\). Hence the global energy function and characteristic function are both constant 1 for the step initial condition. In general since the roots of the Bethe polynomial \(q_z(w)\) depend analytically on z, the function \({\mathcal {E}}_{{\vec {y}}}(z)\) is analytic for \(|z|<\mathbbm {r}_c\). Furthermore \({\mathcal {E}}_{{\vec {y}}}(z)\) can not be constant zero. In fact \({\mathcal {E}}_{{\vec {y}}}(0)=1\) since when \(|z|\rightarrow 0\) all the right Bethe roots converge to 0. As a consequence \({\mathcal {F}}_{\lambda ({\vec {y}})}({\mathcal {R}}_z;p)\) is nonzero for all but finitely many z in any compact subset of \(\{|z|<\mathbbm {r}_c\}\), which means \(\chi _{{\vec {y}}}(v,u;z)\) is a well-defined meromorphic function in z on \(\{|z|< \mathbbm {r}_c\}\) for fixed u, v.
2.5 Definition of \({\mathscr {C}}_{{\vec {y}}}^{(L)}({\vec {z}})\) and \({\mathscr {D}}_{{\vec {y}}}^{(L)}({\vec {z}})\)
Definition 2.14
(Definition of \({\mathscr {C}}_{{\vec {y}}}^{(L)}({\vec {z}})\)) With the global energy function \({\mathcal {E}}_{{\vec {y}}}(z)\) defined in (2.21), we define
where
Here
for \(1\le i\le m\) and \(E_0(z):=1\).
\({\mathscr {D}}_{{\vec {y}}}^{(L)}({\vec {z}})\) is a Fredholm determinant with kernel acting on certain \(\ell ^2\) space over discrete sets related to the Bethe roots. More precisely for m distinct complex numbers \(z_i\) satisfying \(|z_i|<\mathbbm {r}_c\), we define the discrete sets
and
Definition 2.15
(Definition of \({\mathscr {D}}_{{\vec {y}}}^{(L)}({\vec {z}})\)) Let \(0<|z_m|<\cdots< |z_1|<\mathbbm {r}_c\). Assume \({\mathcal {E}}_{{\vec {y}}}(z_1)\ne 0\) so that \(\chi _{{\vec {y}}}(v,u;z_1)\) is well defined. Define
where \({\mathscr {K}}_{1}^{(L)} : \ell ^2({\mathscr {S}}_2) \rightarrow \ell ^2({\mathscr {S}}_1)\) and \({\mathscr {K}}_{{\vec {y}}}^{(L)}:\ell ^2({\mathscr {S}}_1) \rightarrow \ell ^2({\mathscr {S}}_2)\) have kernels given by
and
for
with \(1\le i,j\le m\). Here
The functions J(w) and \(Q_i(j)\) are defined as follows:
and
for \(j=1,\ldots ,m\). Here we set \(z_{m+1}:=0\) for convenience.
To define \(H_z(w)\) and \(f_i(w)\) we recall the definition of left and right Bethe polynomials and Bethe roots discussed in Sect. 2.3. With the notation there we set
Finally the functions \(f_i(w)\) encodes the information of the parameters \(a_i,k_i,t_i\)’s:
where
for \(1\le \ell \le m\) and \(F_0(w):=1\).
2.6 Definition of \({\mathcal {D}}_{\mathrm {step}}^{(\infty )}(\theta _1,\ldots ,\theta _{m-1})\)
The function \({\mathcal {D}}_{\mathrm {step}}^{(\infty )}(\theta _1,\ldots ,\theta _{m-1})\) has a similar structure as \({\mathscr {D}}_{{\vec {y}}}^{(L)}({\vec {z}})\) defined in Definition 2.15. It is also a Fredholm determinant of the form \(\det (I-{\mathcal {K}}_1^{(\infty )}{\mathcal {K}}_{\mathrm {step}}^{(\infty )})\). The kernels also share certain similarities and we will illustrate the relationship between the two in Sect. 8.
2.6.1 Spaces of the operators
Instead of discrete sets, the operators appearing in \({\mathcal {D}}_{\mathrm {step}}^{(\infty )}(\theta _1,\ldots ,\theta _{m-1})\) are defined on specific spaces of nested contours defined as follows: Let \(\Omega _\mathrm {L}\) and \(\Omega _\mathrm {R}\) be two simply connected regions on the complex plane such that
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(1)
\(\Omega _\mathrm {L}\subset \{w\in {\mathbb {C}}: \mathrm {Re}(w)<-\frac{1}{1+\sqrt{1-p}}\}\) and \(\Omega _\mathrm {L}\) contains the point \(-1\) but not \(-1/p\).
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(2)
\(\Omega _\mathrm {R}\subset \{w\in {\mathbb {C}}: \mathrm {Re}(w)>-\frac{1}{1+\sqrt{1-p}}\}\) and \(\Omega _\mathrm {R}\) contains the point 0.
Let \(\Sigma _{m,\mathrm {L}}^{+},\ldots ,\Sigma _{2,\mathrm {L}}^{+}\), \(\Sigma _{1,\mathrm {L}}\), \(\Sigma _{2,\mathrm {L}}^{-},\ldots ,\Sigma _{m,\mathrm {L}}^-\) be \(2m-1\) nested simple closed contours, from outside to inside, in \(\Omega _\mathrm {L}\) enclosing the point \(-1\) but not \(-1/p\). Similarly, \(\Sigma _{m,\mathrm {R}}^{+},\ldots ,\Sigma _{2,\mathrm {R}}^{+}\), \(\Sigma _{1,\mathrm {R}}\), \(\Sigma _{2,\mathrm {R}}^{-},\ldots ,\Sigma _{m,\mathrm {R}}^-\) be \(2m-1\) nested simple closed contours, from outside to inside, in \(\Omega _\mathrm {R}\) enclosing the point 0. We define
and
and
2.6.2 Operators \({\mathcal {K}}_1^{(\infty )}\) and \({\mathcal {K}}_{\mathrm {step}}^{(\infty )}\)
Now we introduce the operators \({\mathcal {K}}_1^{(\infty )}\) and \({\mathcal {K}}_{\mathrm {step}}^{(\infty )}\) to define \({\mathcal {D}}_{\mathrm {step}}^{(\infty )}(\theta _1,\ldots ,\theta _{m-1})\) in Theorem 2.5.
Definition 2.16
We define
where two operators
are defined by the kernels
and
where \(1\le i,j\le m\). Here the function \(f_i(w)\) is the same as the one appearing in the kernels for periodic case defined in (2.35) and we define
and
We also define
3 Transition probability
In this section we give an explicit integral formula for the transition probability of discrete time parallel TASEP in the configuration space \({\mathcal {X}}_{N}^{(L)}\). This is the starting point for deriving the finite-time joint distribution formulas.
Proposition 3.1
Given two particle configurations \({\vec {x}}=(x_1,\ldots ,x_N),\ {\vec {y}}=(y_1,\ldots ,y_N) \in {\mathcal {X}}_{N}^{(L)}\). Let \(P_t({\vec {y}}\rightarrow {\vec {x}})\) be the transition probability of observing configuration \({\vec {x}}\) at time t under the discrete time periodic TASEP dynamics with initial configuration \({\vec {y}}\). With the convention \(x_0:= x_N+L\) we have
Here \(\Gamma \) is any simple closed contour with 0 inside and \({\mathcal {S}}_z\) consists of all the roots of the degree L polynomial \(q_z(w):= w^N(w+1)^{L-N}-z^L(1+pw)^N\), i.e.,
The functions \(F_{i,j}(w;t)\) and J(w) are given by
and
Remark 3.2
We remark that a different formula for the transition probability of discrete time parallel TASEP on a ring was obtained in [18]. The key difference is that the formula in [18] is expressed as an infinite sum of determinants while our formula is a single contour integral of determinants. The main reason for this is that in [18] the authors do not distinguish particle configurations which differ by a translation of an integer multiple of the period, so in our language their transition probability really is
We believe our formula is simpler and more suitable for deriving finite-time joint distributions.
Remark 3.3
If we take the continuous time limit by setting \(p=\epsilon \), \(t= T/\epsilon \) and send \(\epsilon \rightarrow 0\), the dynamics then becomes continuous time periodic TASEP considered in [3] and our formula (3.1) reduces to equation (5.4) in [3] for the transition probability of continuous time periodic TASEP up to an index reversing.
We first list a few elementary properties of the transition probability formula (3.1) before discussing the proof of Proposition 3.1.
Proposition 3.4
(Properties of the transition probability formula) The right hand side of (3.1) satisfies the following properties:
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(i)
The right hand side of (3.1) can also be written as:
$$\begin{aligned} \begin{aligned} \prod _{i=1}^N (1-p{\mathbf {1}}_{x_{i-1}-x_i=1})\oint _{\Gamma } \frac{{\mathrm {d}}z}{2\pi \mathrm {i}z} \det \left[ \oint _{\Gamma _{{\mathcal {S}}_z}}\frac{{\mathrm {d}}w}{2\pi \mathrm {i}} F_{i,j}(w;{\vec {x}},{\vec {y}},t)\left( 1+\frac{z^L}{{\hat{q}}_z(w)}\right) \right] _{i,j=1}^N, \end{aligned}\nonumber \\ \end{aligned}$$(3.5)where \({\hat{q}}_{z}(w)=q_z(w)(1+pw)^{-N}=w^N(1+pw)^{-N}(1+w)^{L-N}-z^L\) has the same roots as \(q_z(w)\) for any \(|z|>0\) and \(\Gamma _{{\mathcal {S}}_z}\) is any simple closed contour with all the roots in \({\mathcal {S}}_z\) inside and \(-1\) and \(-1/p\) outside.
-
(ii)
The outer integral with respect to z in (3.1) (and also (3.5)) does not depend on the contour \(\Gamma \).
-
(iii)
Assume further that \(L\ge x_1-y_N+2\). Then the right-hand side of (3.1) can be further written as
$$\begin{aligned} \prod _{i=1}^N (1-p{\mathbf {1}}_{x_{i-1}-x_i=1}) \det \left[ \oint _{\Gamma _{0,-1}}\frac{{\mathrm {d}}w}{2\pi \mathrm {i}} F_{i,j}(w;{\vec {x}},{\vec {y}},t) \right] _{i,j=1}^N, \end{aligned}$$(3.6)where \(\Gamma _{0,-1}\) is any simple closed contour enclosing 0 and \(-1\) as the only possible poles for the integrand. Note that (3.6) agrees with the transition probability for discrete time parallel TASEP on \({\mathbb {Z}}\), see for example equation (3.21) of [9].
-
(iv)
The right-hand side of (3.1) is invariant under cyclic translation and re-indexing. Namely, for any fixed \(1\le k\le N\), set \({\vec {x}}':= (x_k,x_{k+1},\ldots ,x_N,x_1-L,x_2-L,\ldots ,x_{k-1}-L)\) and \({\vec {y}}':= (y_k,y_{k+1},\ldots ,y_N,y_1-L,y_2-L,\ldots ,y_{k-1}-L)\). Then the right-hand side of (3.1) is invariant if we replace \({\vec {x}}\) and \({\vec {y}}\) by \({\vec {x}}'\) and \({\vec {y}}'\).
Proof
-
(i)
It is easy to check that \(J(w)=\frac{{\hat{q}}_z(w)+z^L}{\frac{{\mathrm {d}}}{{\mathrm {d}}w}{\hat{q}}_z(w)}\). Hence by the residue theorem we have
$$\begin{aligned} \sum _{w\in {\mathcal {S}}_z} F_{i,j}(w;{\vec {x}},{\vec {y}},t)J(w) =\oint _{\Gamma _{{\mathcal {R}}_z}} \frac{{\mathrm {d}}w}{2\pi \mathrm {i}} F_{i,j}(w;{\vec {x}},{\vec {y}},t)\frac{{\hat{q}}_z(w)+z^L}{{\hat{q}}_z(w)}. \end{aligned}$$Note that \(F_{i,j}(w,{\vec {x}},{\vec {y}},t)\frac{{\hat{q}}_z(w)+z^L}{{\hat{q}}_z(w)}\) is analytic at \(w=0\) for any \(1\le i,j\le N\) and the only possible poles of the integrand besides \({\mathcal {S}}_z\) are \(w=-1\) and \(w=-1/p\).
-
(ii)
Choose \(R>0\) large enough and \(\epsilon >0\) small enough so that all the roots in \({\mathcal {S}}_z\) are inside the region \(\{\epsilon<|w+1|<R\}\backslash \{|1+pw|\le \epsilon \}\). Then
$$\begin{aligned}&\sum _{w\in {\mathcal {S}}_z} F_{i,j}(w;{\vec {x}},{\vec {y}},t)J(w)\nonumber \\&\quad =\left( \oint _{|w+1|=R}-\oint _{|w+1|=\epsilon }-\oint _{|pw+1|=\epsilon }\right) \frac{{\mathrm {d}}w}{2\pi \mathrm {i}} F_{i,j}(w;{\vec {x}},{\vec {y}},t)\frac{{\hat{q}}_z(w)+z^L}{{\hat{q}}_z(w)}.\nonumber \\ \end{aligned}$$(3.7)Since R and \(\epsilon \) can be arbitrarily large or small, the right hand side of (3.7) as a function in z is analytic for any \(|z|>0\). Hence the integral with respect to z in (3.1) is independent of \(\Gamma \) since the integrand has an analytic continuation to \(\{|z|>0\}\).
-
(iii)
For \(L>x_1-y_N+2\), we have \(-x_{N-i+1}+y_{N-j+1}+i-j+L-N-1\ge 0\) for all \(1\le i,j\le N\). Hence for any \(|z|>0\), the integrand \(F_{i,j}(w;{\vec {x}},{\vec {y}},t)\frac{{\hat{q}}_z(w)+z^L}{{\hat{q}}_z(w)}\) in (3.7) is analytic at \(w=-1\). This implies that
$$\begin{aligned}&\sum _{w\in {\mathcal {S}}_z} F_{i,j}(w;{\vec {x}},{\vec {y}},t)J(w)\nonumber \\&\quad =\left( \oint _{|w+1|=R}-\oint _{|pw+1|=\epsilon }\right) \frac{{\mathrm {d}}w}{2\pi \mathrm {i}} F_{i,j}(w;{\vec {x}},{\vec {y}},t)\frac{{\hat{q}}_z(w)+z^L}{{\hat{q}}_z(w)}. \end{aligned}$$(3.8)Now for fixed R large enough and \(\epsilon \) small enough, the right hand side of (3.8) is an analytic function in z for |z| sufficiently small such that all the roots of \({\hat{q}}_z\) are in the region \(\{|w+1|\le R\}\backslash \{|pw+1|\le \epsilon \}\). Now by the residue theorem the outer contour integral with respect to z in (3.5) equals the integrand evaluated at \(z=0\), which equals
$$\begin{aligned} \det \left[ \left( \oint _{|w+1|=R}-\oint _{|pw+1|=\epsilon }\right) \frac{{\mathrm {d}}w}{2\pi \mathrm {i}} F_{i,j}(w;{\vec {x}},{\vec {y}},t)\right] _{i,j=1}^N. \end{aligned}$$ -
(iv)
We remark that this property can be easily understood if we use the probabilistic interpretation since \({\vec {x}}\) and \({\vec {x}}'\) (and also \({\vec {y}}\) and \({\vec {y}}'\)) actually represent the same particle configuration on \({\mathbb {Z}}\) (we just use particles in different period as representatives), hence the transition probability between \({\vec {y}}\) and \({\vec {x}}\) and \({\vec {y}}'\) and \({\vec {x}}'\) should be the same. Here however we can not directly use this since we have not proven (3.1). In fact, we will need this fact in our proof of (3.1) so we give an independent algebraic proof here. It suffices to assume \(k=2\). Then \({\vec {x}}'=(x_2,\ldots ,x_N,x_1-L)\), \({\vec {y}}'=(y_2,\ldots ,y_N,y_1-L)\). Clearly we have \(\prod _{i=1}^{N}(1-p{\mathbf {1}}_{x_{i-1}-x_i}=1) = \prod _{i=1}^{N}(1-p{\mathbf {1}}_{x'_{i-1}-x'_i}=1)\). So it suffices to show
$$\begin{aligned} \det \left[ \sum _{w\in {\mathcal {S}}_z} F_{i,j}(w;{\vec {x}},{\vec {y}},t)J(w)\right] _{i,j=1}^N = \det \left[ \sum _{w\in {\mathcal {S}}_z} {\tilde{F}}_{i,j}(w;{\vec {x}},{\vec {y}},t)J(w)\right] _{i,j=1}^N, \end{aligned}$$where \({\tilde{F}}_{i,j}(w;{\vec {x}},{\vec {y}},t)= w^{j-i}(w+1)^{-x'_{N-i+1}+y'_{N-j+1}+i-j-1}(1+pw)^{t+i-j}\). By multi-linearity we have
$$\begin{aligned}&\det \left[ \sum _{w\in {\mathcal {S}}_z} F_{i,j}(w;{\vec {x}},{\vec {y}},t)J(w)\right] _{i,j=1}^{N} = \sum _{w_1,\ldots ,w_N\in {\mathcal {S}}_z} \det \left[ F_{i,j}(w_i;{\vec {x}},{\vec {y}},t)J(w_i)\right] _{i,j=1}^{N}\\&\quad = \sum _{w_1,\ldots ,w_N\in {\mathcal {S}}_z} \sum _{\sigma \in S_N} \text {sgn}(\sigma )\prod _{i=1}^N w_i^{\sigma (i)-i}(w_i+1)^{-x_{N-i+1}+y_{N-\sigma (i)+1}+i-\sigma (i)-1}\\&\qquad (1+pw_i)^{t+i-\sigma (i)}\\&\quad = \sum _{w_1,\ldots ,w_N\in {\mathcal {S}}_z} \sum _{\sigma \in S_N} \text {sgn}(\sigma )\prod _{i=1}^N w_i^{\sigma (i)-i}(w_i+1)^{-x'_{N-i}+y'_{N-\sigma (i)}+i-\sigma (i)-1}\\&\qquad (1+pw_i)^{t+i-\sigma (i)}. \end{aligned}$$Here again \(x'_0=x'_N+L=x_1-L+L=x_1\). Now we fix a permutation \(\tau :=(N\cdots 21)\in S_N\) and set \({\tilde{w}}_i:=w_{\tau (i)}\) for \(1\le i\le N\) and \({\tilde{\sigma }}:=\tau ^{-1}\sigma \tau \). Then the last line in the above equation equals
$$\begin{aligned}&\sum _{{\tilde{w}}_1,\ldots ,{\tilde{w}}_N\in {\mathcal {S}}_z} \sum _{{\tilde{\sigma }}\in S_N} \text {sgn}({\tilde{\sigma }})\prod _{i=1}^N {\tilde{w}}_i^{\tau {\tilde{\sigma }}(i)-\tau (i)}({\tilde{w}}_i+1)^{-x'_{N-\tau (i)}+y'_{N-\tau {\tilde{\sigma }}(i)}+\tau (i)-\tau {\tilde{\sigma }}(i)-1}\nonumber \\&\quad (1+p{\tilde{w}}_i)^{t+\tau (i)-\tau {\tilde{\sigma }}(i)}. \end{aligned}$$(3.9)We claim that for any fixed \({\tilde{\sigma }}\in S_N\),
$$\begin{aligned}&\prod _{i=1}^N {\tilde{w}}_i^{\tau {\tilde{\sigma }}(i)-\tau (i)}({\tilde{w}}_i+1)^{-x'_{N-\tau (i)}+y'_{N-\tau {\tilde{\sigma }}(i)}+\tau (i)-\tau {\tilde{\sigma }}(i)-1}(1+p{\tilde{w}}_i)^{t+\tau (i)-\tau {\tilde{\sigma }}(i)}\\&\quad =\prod _{i=1}^N {\tilde{w}}_i^{{\tilde{\sigma }}(i)-i}({\tilde{w}}_i+1)^{-x'_{N-i+1}+y'_{N-{\tilde{\sigma }}(i)+1}+i-{\tilde{\sigma }}(i)-1}(1+p{\tilde{w}}_i)^{t+i-{\tilde{\sigma }}(i)}. \end{aligned}$$This then implies
$$\begin{aligned}&\det \left[ \sum _{w\in {\mathcal {S}}_z} F_{i,j}(w;{\vec {x}},{\vec {y}},t)J(w)\right] _{i,j=1}^{N} \\&\quad = \sum _{{\tilde{w}}_1,\ldots ,{\tilde{w}}_N\in {\mathcal {S}}_z} \sum _{{\tilde{\sigma }}\in S_N} \text {sgn}({\tilde{\sigma }})\prod _{i=1}^N {\tilde{w}}_i^{{\tilde{\sigma }}(i)-i}({\tilde{w}}_i+1)^{-x'_{N-i+1}+y'_{N-{\tilde{\sigma }}(i)+1}+i-{\tilde{\sigma }}(i)-1}\\&\qquad (1+p{\tilde{w}}_i)^{t+i-{\tilde{\sigma }}(i)}\\&\quad = \det \left[ \sum _{w\in {\mathcal {S}}_z} {\tilde{F}}_{i,j}(w;{\vec {x}},{\vec {y}},t)J(w)\right] _{i,j=1}^{N}. \end{aligned}$$To see the claim note that for \(i\ne 1\) we have \(\tau (i)=i-1\) and for \({{\tilde{\sigma }}}(i)\ne 1\) we have \(\tau {\tilde{\sigma }}(i)={{\tilde{\sigma }}}(i)-1\). Hence
$$\begin{aligned}&{\tilde{w}}_i^{\tau {\tilde{\sigma }}(i)-\tau (i)}({\tilde{w}}_i+1)^{-x'_{N-\tau (i)}+y'_{N-\tau {\tilde{\sigma }}(i)}+\tau (i)-\tau {\tilde{\sigma }}(i)-1}(1+p{\tilde{w}}_i)^{t+\tau (i)-\tau {\tilde{\sigma }}(i)}\\&\quad = {\tilde{w}}_i^{{\tilde{\sigma }}(i)-i}({\tilde{w}}_i+1)^{-x'_{N-i+1}+y'_{N-{\tilde{\sigma }}(i)+1}+i-{\tilde{\sigma }}(i)-1}(1+p{\tilde{w}}_i)^{t+i-{\tilde{\sigma }}(i)}, \end{aligned}$$for \(i\ne 1\) and \({\tilde{\sigma }}(i)\ne 1\). For the other situations we split into two cases:
Case 1 \({\tilde{\sigma }}(1)\ne 1\). Then we have
$$\begin{aligned}&{\tilde{w}}_1^{\tau {\tilde{\sigma }}(1)-\tau (1)}({\tilde{w}}_1+1)^{-x'_{N-\tau (1)}+y'_{N-\tau {\tilde{\sigma }}(1)}+\tau (1)-\tau {\tilde{\sigma }}(1)-1}(1+p{\tilde{w}}_1)^{t+\tau (1)-\tau {\tilde{\sigma }}(1)}\\&\quad = {\tilde{w}}_1^{{\tilde{\sigma }}(1)-1}({\tilde{w}}_1+1)^{-x'_{N}+y'_{N-{\tilde{\sigma }}(1)+1}-{\tilde{\sigma }}(1)}(1+p{\tilde{w}}_i)^{t+1-{\tilde{\sigma }}(1)}\cdot {\tilde{w}}_1^{-N}({\tilde{w}}_1\\&\qquad +1)^{N-L}(1+p{\tilde{w}}_1)^{N}\\&\quad ={\tilde{w}}_1^{{\tilde{\sigma }}(1)-1}({\tilde{w}}_1+1)^{-x'_{N}+y'_{N-{\tilde{\sigma }}(1)+1}-{\tilde{\sigma }}(1)}(1+p{\tilde{w}}_i)^{t+1-{\tilde{\sigma }}(1)}\cdot z^{-L}. \end{aligned}$$Similarly if we denote \({\tilde{\sigma }}^{-1}(1)=j\), then the term involving \({\tilde{w}}_j\) among the sum in (3.9) equals
$$\begin{aligned}&{\tilde{w}}_{j}^{\tau (1)-\tau (j)}({\tilde{w}}_{j}+1)^{-x'_{N-\tau (j)}+y'_{N-\tau (1)}+\tau (j)-\tau (1)-1}(1+p{\tilde{w}}_{j})^{t+\tau (j)-\tau (1)}\\&\quad = {\tilde{w}}_j^{{\tilde{\sigma }}(j)-j}({\tilde{w}}_1+1)^{-x'_{N-j+1}+y'_{N-{\tilde{\sigma }}(j)+1}-{\tilde{\sigma }}(j)+j-1}(1+p{\tilde{w}}_j)^{t+j-{\tilde{\sigma }}(j)}\cdot {\tilde{w}}_j^{N}({\tilde{w}}_j\\&\qquad +1)^{L-N}(1+p{\tilde{w}}_j)^{-N}\\&\quad = {\tilde{w}}_j^{{\tilde{\sigma }}(j)-j}({\tilde{w}}_1+1)^{-x'_{N-j+1}+y'_{N-{\tilde{\sigma }}(j)+1}-{\tilde{\sigma }}(j)+j-1}(1+p{\tilde{w}}_j)^{t+j-{\tilde{\sigma }}(j)}\cdot z^{L}. \end{aligned}$$Hence
$$\begin{aligned}&\prod _{i=1}^N {\tilde{w}}_i^{\tau {\tilde{\sigma }}(i)-\tau (i)}({\tilde{w}}_i+1)^{-x'_{N-\tau (i)}+y'_{N-\tau {\tilde{\sigma }}(i)}+\tau (i)-\tau {\tilde{\sigma }}(i)-1}(1+p{\tilde{w}}_i)^{t+\tau (i)-\tau {\tilde{\sigma }}(i)}\\&\quad = z^L\cdot z^{-L}\cdot \prod _{i=1}^N {\tilde{w}}_i^{{\tilde{\sigma }}(i)-i}({\tilde{w}}_i+1)^{-x'_{N-i+1}+y'_{N-{\tilde{\sigma }}(i)+1}+i-{\tilde{\sigma }}(i)-1}(1+p{\tilde{w}}_i)^{t+i-{\tilde{\sigma }}(i)}\\&\quad = \prod _{i=1}^N {\tilde{w}}_i^{{\tilde{\sigma }}(i)-i}({\tilde{w}}_i+1)^{-x'_{N-i+1}+y'_{N-{\tilde{\sigma }}(i)+1}+i-{\tilde{\sigma }}(i)-1}(1+p{\tilde{w}}_i)^{t+i-{\tilde{\sigma }}(i)}. \end{aligned}$$Case 2 \({\tilde{\sigma }}(1)=1\). Then we have
$$\begin{aligned}&{\tilde{w}}_1^{\tau {\tilde{\sigma }}(1)-\tau (1)}({\tilde{w}}_1+1)^{-x'_{N-\tau (1)}+y'_{N-\tau {\tilde{\sigma }}(1)}+\tau (1)-\tau {\tilde{\sigma }}(1)-1}(1+p{\tilde{w}}_1)^{t+\tau (1)-\tau {\tilde{\sigma }}(1)}\\&\quad = {\tilde{w}}_1^{{\tilde{\sigma }}(1)-1}({\tilde{w}}_1+1)^{-x'_{N}+y'_{N-{\tilde{\sigma }}(1)+1}-{\tilde{\sigma }}(1)}(1+p{\tilde{w}}_i)^{t+1-{\tilde{\sigma }}(1)}, \end{aligned}$$so the claim follows and this completes the proof of the cyclic invariance. \(\square \)
3.1 Proof of the transition probability formula
Now we turn to the proof of formula (3.1). The proof basically follows the idea of [3, 9] where we replace the Kolmogorov forward equation by a free evolution equation with additional boundary conditions. The main extra difficulty here is that due to parallel update rule, the stationary distribution for the dynamics is non-uniform. In fact one can check \(\mu ({\vec {x}})\propto \prod _{i=1}^{N}(1-p{\mathbf {1}}_{x_{i-1}-x_i=1})\) is the stationary distribution. As a result it turns out that \(\frac{P_t({\vec {y}}\rightarrow {\vec {x}})}{\prod _{i=1}^{N}(1-p{\mathbf {1}}_{x_{i-1}-x_i=1})}\) satisfies a relatively simpler dynamics than \(P_t({\vec {y}}\rightarrow {\vec {x}})\). More precisely we have:
Lemma 3.5
Given \({\vec {x}},{\vec {y}}\in {\mathbb {Z}}^N\). Let \(G({\vec {x}},t;{\vec {y}},0)\) be the (unique) solution of the following free evolution equation
together with the boundary conditions:
and the initial condition:
Then
Note that we have used the convention \(x_0=x_N+L\) so when \(i=1\), (3.11) should be interpreted as
Proof
Set
It suffices to show that for \({\vec {x}},{\vec {y}}\in {\mathcal {X}}_{N}^{(L)}\), \(H({\vec {x}},t;{\vec {y}},0)\) and \(G({\vec {x}},t;{\vec {y}},0)\) satisfy the same evolution equation. This then implies that \(H({\vec {x}},t;{\vec {y}},0)=G({\vec {x}},t;{\vec {y}},0)\) for all \({\vec {x}},{\vec {y}}\in {\mathcal {X}}_{N}^{(L)}\) since they satisfy the same initial condition. To better describe the evolution equation for \(H({\vec {x}},t;{\vec {y}},0)\), it is convenient to introduce the notion of clusters of a particle configuration \({\vec {x}}\). Given \({\vec {x}}=(x_1,\ldots ,x_N)\in {\mathcal {X}}_{N}^{(L)}\), for \(1\le i\le N\) and \(1\le k\le N\) we say \([x_i, x_{i-1},\ldots ,x_{i-k+1}]\) is a cluster of size k of \({\vec {x}}\) if
Namely particle i through \(i-k+1\) are right next to each other while there are at least one empty site to the left of \(x_i\) and right of \(x_{i-k+1}\). Here we abuse notation by allowing the index to exceed \(\{1,\ldots ,N\}\) and this should be understood with the convention \(x_{i+kN}=x_{i}-kL\) for \(1\le i\le N\) and \(k\in {\mathbb {Z}}\). For convenience when \([x_i,x_{i-1},\ldots ,x_1,x_0,\ldots x_{-j}]\) is a cluster for some \(0\le j<N\), we will also say \([x_i,\ldots ,x_1,x_N,\ldots ,x_{N-j}]\) forms a cluster so that all the indices appearing will be between 1 and N.
Let \({\mathcal {N}}_c({\vec {x}})\) be the number of clusters in configuration \({\vec {x}}\) and let \(x_{c_j}\), \(1\le j\le {\mathcal {N}}_c({\vec {x}})\) be the locations of the left-most particles in each cluster. Then it is straightforward to check that \(H({\vec {x}},t;{\vec {y}},0)\) satisfies
where \({\vec {e}}_{c_j}\in {\mathbb {Z}}^N\) has 1 in the \(c_j\)-th coordinate and 0 in the other coordinates.
We claim that for \({\vec {x}},{\vec {y}}\in {\mathcal {X}}_{N}^{(L)}\), (3.16) and (3.10) take the same form (with H replaced by G) provided that \(G({\vec {x}},t;{\vec {y}},0)\) satisfies boundary conditions (3.11). Due to the sum of products form of (3.16) and (3.10) it suffices to check
for \({\vec {x}},{\vec {y}}\in {\mathcal {X}}_{N}^{(L)}\) and a single cluster \([x_i,x_{i-1},\ldots ,x_{i-m+1}]\) of size m. We will show the stronger statement: (3.17) actually holds for any \({\vec {x}}=(x_1,\ldots ,x_N)\in {\mathbb {Z}}^N\) with \(x_i,x_{i-1},\ldots ,x_{i-m+1}\) merely satisfying \(x_i=x_{i-1}-1=\cdots =x_{i-m+1}-m+1\). We do not require empty sites at the left and right ends so they may not form a cluster.
We prove this by induction on m. For \(m=1\) this is trivial. Assume the claim is true for any clusters of size \(\le m\). Now let \({\vec {x}}\in {\mathbb {Z}}^N\) with \(x_i=x_{i-1}-1=\cdots =x_{i-m}-m\) for some \(1\le i\le N\). Here without loss of generality we can assume \(i-m\ge 1\), otherwise replace j by \(j+N\) for indices \(j\le 0\). Then
where we used the induction hypothesis in the second equality of (3.18) for the sum inside the brackets. For notational conveniece we have suppressed the dependence on \({\vec {y}}\) in the last line to save space. Now by the boundary conditions (3.11) (possibly (3.14)) we have
Inserting (3.19) into (3.18) we see the last line of (3.18) simplifies to
which is precisely the left hand side of (3.17) and this completes the proof of Lemma 3.5. \(\square \)
Now we discuss the proof of Proposition 3.1.
Proof of Proposition 3.1
By Lemma 3.5 it suffices to prove
To see this, we check that the right-hand side of (3.21) satisfies the free evolution equation (3.10), the boundary conditions (3.11) and the initial condition (3.12).
For the free evolution equation (3.10), note first that it is straightforward to check
Here \({\vec {e}}_i\in {\mathbb {Z}}^N\) has 1 in the i-th entry and 0 for the others. By multi-linearity of determinants we have
Here in the last equality above we used the fact that \(F_{i,j}(w;{\vec {x}},{\vec {y}},t)\) only depends on the \((N-i+1)\)-th entry of \({\vec {x}}\). Now (3.10) follows from linearity of the integral.
Next we check the boundary conditions (3.11). Given \(1\le k\le N\), assume that \({\vec {x}}=(x_1,\ldots ,x_N)\in {\mathbb {Z}}^N\) satisfies \(x_{k-1}=x_k+1\). Note that when \(k=1\) this means \(x_1=x_N+L-1\). Then the boundary conditions (3.11) can be expressed as
for \(2\le k\le N\), and
for \(k=1\). We prove (3.23) first. Note that for \(2\le k \le N\) and \(x_{k-1}=x_k+1\) we have
Hence by multi-linearity we have
Similarly
Now since \( F_{i,j}(w;{\vec {x}}-{\vec {e}}_k,{\vec {y}},t) = F_{i,j}(w;{\vec {x}},{\vec {y}},t)\) for \(i\ne N-k+1\) and
we have
Here \(M_{i,j}^{(k)}({\vec {x}},{\vec {y}},t) = \sum _{w\in {\mathcal {S}}_z} F_{i,j}(w;{\vec {x}},{\vec {y}},t)J(w)\) for \(i\ne N-k+1, N-k+2\) and \(M_{N-k+1,j}^{(k)}({\vec {x}},{\vec {y}},t) = -M_{N-k+2,j}^{(k)}({\vec {x}},{\vec {y}},t) =\sum _{w\in {\mathcal {S}}_z} F_{N-k+2,j}(w;{\vec {x}},{\vec {y}},t)J(w)\cdot w\). The determinant is 0 since there are two proportional rows. Now (3.23) follows from linearity of the integral.
The proof of (3.24) is similar. The only thing changes is that when \(k=1\), we have \(M_{i,j}^{(1)}({\vec {x}},{\vec {y}},t) = \sum _{w\in {\mathcal {S}}_z} F_{i,j}(w;{\vec {x}},{\vec {y}},t)J(w)\) for \(i\ne 1,N\) while
Hence \(\det [M^{(1)}_{i,j}({\vec {x}},{\vec {y}},t)]=0\) since row 1 and N are proportional. Note that in the last equality of (3.25) we used the fact that \(w\in {\mathcal {S}}_z\).
Finally we check the initial condition (3.12). We need to show
Thanks to the cyclic-shift invariance of both sides of (3.26) (see (iv) of Proposition 3.4) we can assume without loss of generality that \({\vec {x}}=(x_1,\ldots ,x_N)\in {\mathcal {X}}_{N}^{(L)}\) satisfies \(x_1<x_{N}+L-1\). In fact since \(N<L\) there is at least one \(1\le i\le N\) such that \(x_{i}<x_{i-1}-1\) and we can replace \({\vec {x}}\) and \({\vec {y}}\) by \({\vec {x}}':=(x_{i},x_{i+1},\ldots ,x_{N},x_{1}-L,\ldots , x_{i-1}-L)\) and \({\vec {y}}':=(y_{i},y_{i+1},\ldots ,y_{N},y_{1}-L,\ldots , y_{i-1}-L)\). Then the two sides of (3.26) remain the same and \(x_1'< x_N'+L-1\). By (3.7) we have
where \(I_1(i,j),I_2(i,j),I_3(i,j)\) are the integrals over the three contours, respectively. Here we recall that R and \(\epsilon \) are chosen to be large (small) enough so that \({\mathcal {S}}_z\) is contained in the region \(\{\epsilon<|w+1|<R\}\backslash \{|1+pw|\le \epsilon \}\). For \(I_3(i,j)\) we note that
where the second term vanishes since \(F_{i,j}(w;{\vec {x}},{\vec {y}},0)(1+pw)^N\) is analytic at \(w=-1/p\) for all \(1\le i,j\le N\) and \(q_z(w)\) is nonzero at \(w=-1/p\). For the other parts we write
and
Depending on the analytical properties of the integrands in \(I_1'\) and \(I_2'\) we split into two cases:
Case 1 \(x_1<y_1\). First note the basic fact that for any \({\vec {x}},{\vec {y}}\in {\mathcal {X}}_{N}^{(L)}\) we have
Now if \(x_1<y_1\), then for any \(1\le i,j\le N\) we have
Hence the integrand of \(I_2'(i,j)\) is analytic at \(w=-1\), so \(I_2'(i,j)=0\). Therefore in this case we have
Here in the last equality of (3.30) we take the outer integral contour \(\Gamma \) to be \(|z|=r\) and let \(r\rightarrow 0\). \(\Gamma _{0,-1}\) is any simple closed contour with 0 and \(-1\) inside and \(-1/p\) outside.
Case 2 \(x_1\ge y_1\). Write
Again by (3.29) we have
We claim that the first inequality in (3.32) is strict and hence \(-x_{N-i+1}+y_{N-j+1}+i-j-1-L+N\le -2\). This is due to our original assumption that \(x_N+L-1>x_1\) and hence \(x_{N-i+1}>x_1-L+i\) for all \(1\le i\le N\). Owing to this fact, the integrand in (3.31) is \(O(R^{-2})\) since \(w^{j-i-N}(1+pw)^{i-j+N}\) remains bounded. Hence \(I_1'(i,j)\rightarrow 0\) as \(R\rightarrow \infty \). But since it is independent of large enough R , we have \(I_1'(i,j)=0\) for all R large enough. Now a similar argument as in (3.30) with \(\Gamma \) instead be a large circle \(|z|=r\) with \(r\rightarrow \infty \) implies:
In conclusion we have reduced checking (3.26) to checking the following:
for any \({\vec {x}},{\vec {y}}\in {\mathcal {X}}_{N}^{(L)}\) with \(x_1<x_{N}+L-1\). But this is precisely equation (3.30) of [9] which appears in checking that the determinantal formula for the transition probability of discrete parallel TASEP on \({\mathbb {Z}}\) satisfies the initial condition. We will not repeat the proof here but point out that due to the assumption \(x_1<x_{N}+L-1\), we have \(1-p{\mathbf {1}}_{x_0-x_1=1}=1\) so (3.34) is really identical to equation (3.30) of [9]. \(\square \)
4 Finite-time multi-point joint distribution under general initial conditions
4.1 A Toeplitz-like determinant formula
In this section we derive a formula for the finite-time multi-point joint distributions of discrete time parallel periodic TASEP under arbitrary initial condition. The proof basically follows the strategy of [4] by performing a multiple sum of transition probabilities over suitable particle configurations. The main technical part is a Cauchy-type identity for summation of left and right eigenfunctions (see Proposition 5.4) which generalizes Proposition 3.4 of [4] and some new difficulties appear.
Theorem 4.1
(Multi-point joint distribution for discrete time parallel TASEP in \({\mathcal {X}}_{N}^{(L)}\)) Given \({\vec {y}} \in {\mathcal {X}}_{N}^{(L)}\). Let \({\vec {x}}(t)=(x_1(t),\ldots , x_N(t))\in {\mathcal {X}}_{N}^{(L)}\) be particle configurations evolving according to the discrete time parallel TASEP in \({\mathcal {X}}_{N}^{(L)}\) at time t with initial configuration \({\vec {x}}(0)={\vec {y}}\). Fix a positive integer m. Let \((k_1,t_1),\ldots ,(k_m,t_m)\in \{1,\ldots ,N\}\times {\mathbb {N}}\) be distinct with \(0\le t_1\le \cdots \le t_m\). Let \(a_{i}\in {\mathbb {Z}}\) for \(1\le i\le m\). Then
where the contours for the integrals are nested circles \(0<|z_m|<\cdots <|z_1|\). Here \({\vec {z}}=(z_1,\ldots ,z_m)\). The functions \({\mathcal {C}}^{(L)}({\vec {z}})\) and \({\mathcal {D}}^{(L)}_{{\vec {y}}}({\vec {z}})\) are defined by
and
where for \(1\le \ell \le m\),
Here \(k_0=t_0=a_0:=0\) and we suppress the dependence on \(a_i\), \(k_i\) and \(t_i\)’s in \({\mathcal {C}}^{(L)}({\vec {z}})\) and \({\mathcal {D}}_{{\vec {y}}}^{(L)}({\vec {z}})\).
Proof
We start with the case \(m=1\) for a warm-up. First by Cauchy–Binet formula we can rewrite the transition probability (3.1) as
where
and
Now to get the one-point distribution \({\mathbb {P}}_{{\vec {y}}}^{(L)}(x_{k}(t)\ge a)\) we perform a summation over all configurations \({\vec {x}}\in {\mathcal {X}}_{N}^{(L)}\) with \(x_k\ge a\) of the transition probability and interchange the order of integration and summation:
Now by Corollary 5.3 in Sect. 5 we have \(\sum _{{\vec {x}}\in {\mathcal {X}}_{N}^{(L)}\cap \{x_k\ge a\}}\Psi _{{\vec {x}}}^{r}({\vec {w}})\) equals
Inserting (4.9) back to (4.8) and use Cauchy–Binet formula backwards we conclude that
Here in order to interchange the order of summation and integration as in (4.8) we need to make sure that the summation over \({\vec {x}}\in {\mathcal {X}}_{N}^{(L)}\cap \{x_k\ge a\}\) converges absolutely. This is guaranteed if we assume \(|w+1|>1\) for all \(w\in {\mathcal {S}}_z\) (see the discussion in Proposition 5.2). By choosing the contour \(\Gamma \) to be a circle with large radius R we can make sure that \(|w+1|>1\) for all \(w\in {\mathcal {S}}_z\) since for \(|z|=R\) and all w satisfying \(w^N(1+pw)^{-N}(w+1)^{L-N}=z^L\) we have \(|w+1|=O(|z|^{\frac{L}{L-N}})>1\). Finally a similar argument as in (ii) of Proposition 3.4 shows that the right-hand side of (4.10) does not depend on the choice of \(\Gamma \), so we can deform \(\Gamma \) to be any simple closed contour containing 0.
Now assume \(m\ge 2\). Then
where \(t_0:= 0\). As in the \(m=1\) case we rewrite the transition probability using Cauchy–Binet formula and interchange the order of summation and integration (will be justified later) so that \({\mathbb {P}}_{{\vec {y}}}(\cap _{i=1}^m \{x_{k_i}(t_i)\ge a_i\})\) equals
Here \({\vec {w}}^{(\ell )}=(w^{(\ell )}_1,\ldots ,w^{(\ell )}_m)\) and
Where
Now similar as in the \(m=1\) case we evaluate the sums appearing in (4.13) and (4.14) using Corollaries 5.3 and 5.6 in Sect. 5 and apply Cauchy–Binet formula backwards to conclude that
for \({\mathcal {C}}^{(L)}({\vec {z}})\) and \({\mathcal {D}}_{{\vec {y}}}^{(L)}({\vec {z}})\) defined in (4.2) and (4.3). Similar as the discussion before, in order to interchange summation and integration we need the absolute convergence of all the infinite sums which is guaranteed if we assume
By the same reasoning as in \(m=1\) case this can be achieved assuming the integral contours for \(z_i\)’s are large nested contours \(|z_\ell |=r_\ell \) with \(r_{\ell }-r_{\ell +1}\) also large enough for all \(1\le \ell \le m\). Finally we can deform the integral contours in (4.1) into arbitrary nested contours with 0 inside, not necessarily with large radius. This is due to the analyticity of \({\mathcal {C}}^{(L)}({\vec {z}})\) and \({\mathcal {D}}_{{\vec {y}}}^{(L)}({\vec {z}})\) in \({\vec {z}}\) for any \(z_i\)’s nonzero and distinct, which can be shown in a similar way as (ii) of Proposition 3.4. \(\square \)
4.2 Toeplitz-like determinant to Fredholm determinant
The finite time formula obtained in Theorem 4.1 contains a factor \({\mathcal {D}}_{{\vec {y}}}^{(L)}({\vec {z}})\) inside the integrals which is a Toeplitz-like determinant and is hard to take large-time limits. In this section we rewrite the formula based on a remarkable finite determinantal identity obtained in [5]. It is an identity between a Toeplitz-like determinant with symbol supported on a finite set and a Fredholm determinant with kernel acting on the \(\ell ^2\) space supported on the same finite set.
Proof of Theorem 2.2
The proof is almost verbatim to the proof of Theorem 3.1 in [5] so we omit most of the details. We apply Proposition 4.1 of [5] with the functions \(p_i(w)\), \(q_i(w)\) and \(h_i(w)\) given by
for \(1\le i\le N\) and
Then the Toepliz-like determinant \({\mathcal {D}}_{{\vec {y}}}^{(L)}({\vec {z}})\) can be rewritten as the product of a function and a Fredholm determinant. Combining with the definition of the function \({\mathcal {C}}_{{\vec {y}}}^{(L)}({\vec {z}})\) and using the algebraic relation satisfied by the Bethe roots we obtain the identity
\(\square \)
5 Summation identities of eigenfunctions
In this section we state and prove the summation identities used in computing the multi-point joint distribution in Sect. 4. First we recall the left and right eigenfunctions defined in (4.5) and (4.6). They are certain (anti)-symmetric functions appearing naturally in the transition probability formula (3.1). Our summation identities should be viewed as Littlewood or Cauchy type identities for these symmetric functions, but over configuration spaces \(x_N+L>x_1>\cdots >x_N\) (partitions wrapped on a cylinder).
Definition 5.1
(Left and right eigenfunctions) Given \({\vec {x}}= (x_1,\ldots ,x_N)\in {\mathcal {X}}_N^{(\infty )}\) and \(p\in {\mathbb {C}}\), we define the functions \(\Psi _{{\vec {x}}}^{\ell }({\vec {w}})\) and \(\Psi _{{\vec {x}}}^r({\vec {w}})\) for \({\vec {w}}\in {\mathbb {C}}^N\) as follows:
The rest of this section is organized as follows: we list all the summation identities we need in Sect. 5.1 and postpone the proofs to the next few subsections. The proof of the summation identity over a single eigenfunction (Proposition 5.2) consists of straightforward manipulations of determinants and will be discussed in Sect. 5.2. The summation identity over left and right eigenfunctions (Proposition 5.4) is more involved and the proof will be splitted into three steps discussed in Sects. 5.3, 5.4, 5.5 and 5.6. Throughout the proof several rank-one perturbation formulas for Cauchy determinants are frequently used so we collect all these elementary formulas in a separate section for convenience, see Sect. 5.7 for details. Finally in Sect. 5.8 we discuss the proof of Corollaries 5.3 and 5.6 which are simple consequences of the previous propositions and the periodic nature of the identities.
5.1 Summation identities over eigenfunctions
We start with a summation identity for \(\Psi _{{\vec {x}}}^{r}({\vec {w}})\):
Proposition 5.2
(Summation over a single eigenfunction) Let \(z\in {\mathbb {C}}\) be nonzero. Let \(\Psi _{{\vec {x}}}^{r}({\vec {w}})\) be as in (4.6) where \({\vec {w}}=(w_1,\ldots ,w_N)\in ({\mathcal {S}}_z)^N\) satisfies \(\prod _{j=1}^{N}|w_j+1|>1\). Then
The following corollary which allows slightly more general constraints on the summation is a simple consequence of Proposition 5.2 and the periodic nature of \({\mathcal {X}}_{N}^{(L)}\).
Corollary 5.3
Under the same assumption as in Proposition 5.2 we have
for all \(0\le k\le N-1\) and \(a\in {\mathbb {Z}}\).
The above summation identities over a single eigenfunction are sufficient for computing the one-point distribution. To get the multi-point distribution we also need the following Cauchy-type summation identities over products of left and right eigenfunctions.
Proposition 5.4
(Cauchy-type summation identity over left and right eigenfunctions) Let \(z,z'\in {\mathbb {C}}\) be nonzero such that \((z')^L\ne z^L\). Let \({\vec {x}}=(x_1,\ldots ,x_N)\in {\mathcal {X}}_{N}^{(L)}\) and \(\Psi _{{\vec {x}}}^{r}({\vec {w}})\) and \(\Psi _{{\vec {x}}}^{\ell }({\vec {w}}')\) be as in (4.5) and (4.6), where \({\vec {w}}=(w_1,\ldots ,w_N)\in ({\mathcal {S}}_z)^N\) and \({\vec {w}}'=(w_1',\ldots ,w_N')\in ({\mathcal {S}}_{z'})^N\) satisfy \(\prod _{j=1}^{N}|w_j+1|>\prod _{j=1}^{N}|w_j'+1|\). Then
Remark 5.5
It is interesting to note that the right-hand side of (5.5) does not depend on p explicitly (of course the \(w_i\)’ should satisfy certain algebraic equations which depend on p). Taking \(p\rightarrow 0\), Proposition 5.4 degenerates to Proposition 3.4 of [4], which can be understood as the Cauchy identity (a periodic version) for the Grothendieck polynomial (and its dual), and can be derived from the finite-sum Cauchy identity for Grothendieck polynomials obtained in Theorem 5.3 of [17]. For \(0<p<1\), to the best of our knowledge the corresponding Cauchy-type identity (5.5) has not been discussed in the existing literature, at least for the periodic case. The key point here is instead of summing over all configuration \({\vec {x}}\) with \(0\le x_N<x_{N-1}<\cdots <x_1\) as in the usual Cauchy identity, we are only summing over those configurations satisfying the extra constraint \(x_1<x_{N}+L\). For general spectral parameters \({\vec {w}}\) and \({\vec {w}}'\) this sum only gives a deformed or generalized Cauchy determinant. It further reduces to a genuine Cauchy determinant when we impose the conditions as in Proposition 5.4 that the spectral parameters satisfy suitable Bethe equations.
Similar as in Corollary 5.3, we can easily extend Proposition 5.4 using periodicity to the summations over \({\vec {x}}\in {\mathcal {X}}_{N}^{(L)}\cap \{x_{N-k}\ge a\}\) for any \(0\le k\le N-1\) and \(a\in {\mathbb {Z}}\):
Corollary 5.6
Under the same assumption as in Proposition 5.4 we have
for all \(0\le k\le N-1\) and \(a\in {\mathbb {Z}}\).
5.2 Proof of Proposition 5.2
First we write
where \({\vec {x}}' = {\vec {x}}-(a,\ldots ,a)\). The summation over a converges absolutely provided that \(\prod _{j=1}^{N}|1+w_j|>1\). Thus we have reduced the computation to a summation with constraint \(x_N=0\) which is a finite sum so there is no convergence issue. We will see the telescoping nature of the summation over a.
The main difficulty for computing the sum comes from the \(\prod _{i=1}^{N}(1-p{\mathbf {1}}_{x_{i-1}-x_i=1})\) factor in \(\Psi _{{\vec {x}}}^{r}({\vec {w}})\) which gives different weights to different terms in the sum. To handle this we first split the sum according to the position of the first empty site to the right of \(x_N\) in the configuration \({\vec {x}}\). More precisely we set
Intuitively \({\mathcal {X}}_{N,k}^{(L)}\) consists of all configurations in \({\mathcal {X}}_{N}^{(L)}\cap \{x_N=0\}\) with the first empty site to the right of \(x_N\) (which equals 0) be at \(k+1\). Then clearly we have \({\mathcal {X}}_{N}^{(L)}\cap \{x_N=0\}=\cup _{k=0}^{N-1}{\mathcal {X}}_{N,k}^{(L)}\). Hence
We will first compute the summations over \({\mathcal {X}}_{N,k}^{(L)}\) for each k and then sum over k. The results for each of these steps are summarized in the following two lemmas, whose proofs will be at the end of this subsection.
Lemma 5.7
We have
where
Lemma 5.8
Furthermore,
Now by Lemma 5.8 and (5.7) we see that
This completes the proof of Proposition 5.2.
Proof of Lemma 5.7
Note that configurations \({\vec {x}}\in {\mathcal {X}}_{N,k}^{(L)}\) take the form \((x_1,\ldots ,x_{N-k-1}, k,\ldots ,0)\) where \(x_{N-k-1}>k+1\). Hence for \({\vec {x}}\in {\mathcal {X}}_{N,k}^{(L)}\) we have
where
We sum over configurations in \({\mathcal {X}}_{N,k}^{(L)}\) in the following order:
Note that
Adding the \((k+3)\)-th column to the \((k+2)\)-th column we get
where
Now we repeat this procedure and perform the sum over \(x_{N-k-2},\ldots , x_2\) to get
where
Finally note that
where we used the fact that \(w_i\in {\mathcal {S}}_z\). Thus we conclude that
where
\(\square \)
Proof of Lemma 5.8
For the purpose of summing over k we further rewrite \(R_{i,j}^{(k)}({\vec {w}})\) slightly. Given \(0\le k\le N-3\), we add the j-th column of \(R^{(k)}({\vec {w}})\) to its \((j+1)\)-th column, \(j=N,\ldots , k+2\) so that
where
For \(k=N-2,N-1\) we just set \({\hat{R}}_{i,j}^{(k)}({\vec {w}}) =R_{i,j}^{(k)}({\vec {w}})\). Now we perform the sum over k in the order \(k=N-1,N-2,\ldots ,0\). Note that for each \(0\le k\le N-1\), \({\hat{R}}_{i,j}^{(k)}({\vec {w}}) = {\hat{R}}^{(k+1)}_{i,j}({\vec {w}})\) except for \(j=k+1\). Hence by multi-linearity of the determinants we have
where
Here to simplify the expression we have multiplied the \((N-1)\)-th column by \(-p(1-p)\) and added it to the sum of the N-th column of \({\hat{R}}^{(N-1)}({\vec {w}})\) and \({\hat{R}}^{(N-2)}({\vec {w}})\), using the simple identity that
Repeating this procedure we get
where
Multiplying the j-th column of \(T^{(0)}({\vec {w}})\) by \(-p\) and adding to the \((j+1)\)-th column for \(j=N-1,\ldots ,2\), we get
where
This completes the proof of Lemma 5.8. \(\square \)
5.3 Proof of Proposition 5.4: Strategy
The proof of Proposition 5.4 is rather lengthy so we divide it into three steps and discuss them one by one in the next few subsections. The proof mainly follows the proof strategy of Proposition 3.4 of [4] but there are several new technicalities. The non-uniform term \(\prod _{i=1}^{N}(1-p{\mathbf {1}}_{x_{i-1}-x_i=1})\) appearing in \(\Psi _{{\vec {x}}}^r({\vec {w}})\) leads to extra difficulty for the sum. In Step 1 we overcome this by introducing a different way (and slightly more convenient way in our opinion) of expressing the sum in (5.5) comparing to the proof in [4], see Lemma 5.9 for details. In Step 2 we establish a key summation identity (see Lemma 5.12) which generalizes Lemma 5.4 in [4] while the computation is more delicate. Finally in Step 3 we combine the formula obtained in Step 1 and the summation identity obtained in Step 2 to conclude the final result.
5.4 Proof of Proposition 5.4: Step 1
Similar as in the proof of Proposition 5.2 we first write
so that it suffices to compute the sum over \({\vec {x}}\in {\mathcal {X}}_{N}^{(L)}\cap \{x_N=0\}\), which is a finite sum so there is no convergence issue. The summation over a converges absolutely by our assumption that \(\prod _{j=1}^{N}|w_j+1|>\prod _{j=1}^{N}|w_j'+1|\). Expanding the determinants in \(\Psi _{{\vec {x}}}^{\ell }({\vec {w}})\) and \(\Psi _{{\vec {x}}}^{r}({\vec {w}}')\) we get
where
By Lemma 5.9 below we have \({\mathcal {H}}^{(N)}_{\sigma ,\sigma '}({\vec {w}},{\vec {w}}')\) equals
Hence
Lemma 5.9
Let \(N\ge 1\) be an integer and \(w_1,\ldots ,w_N\) and \(w_1',\ldots ,w_N'\) be distinct complex numbers. Then for any integer \(L>N\) we have
Here any empty product is set to be 1.
Proof
We use an induction on N. For \(N=1\) the identity is obvious. Assume now \(N\ge 2\) and the identity holds for all indices less than N. We split the sum into two sums depending on whether \(x_1=L-1\) or not:
For \(T_1\) we first relabel the indices so that \((x_0',x_1',\ldots ,x_{N-1}'):=(x_1,x_2,\ldots ,x_N)\) and \(L':=L-1\). Then by induction hypothesis we have
Where
for \(1\le k\le N-1\) and we set \(T_1^{(N)}({\vec {w}},{\vec {w}}'):=0\) for convenience.
For \(T_2\) we calculate the sum directly in the order \(L-1>x_1>\cdots >x_N=0\) using Lemma 5.10 below which gives:
Where
for \(1\le k\le N-1\) and \(T_2^{(N)}({\vec {w}},{\vec {w}}'):= 1\). Here we are summing over all possible partitions of \(\{k+1,\ldots , N\}\) and \(s_{i+1}:= N+1\). Now comparing (5.11) and (5.12) with (5.10) we see that it suffices to prove
for all \(1\le k\le N\). Using the simple identity
(5.13) is further reduced to showing
which follows from Lemma 5.11 below by taking \(z_j= \frac{w_j'+1}{w_j+1}\) and properly shifting the indices. \(\square \)
Lemma 5.10
For complex numbers \(f_j\), set
Then
Where we set \(s_{\ell +1}=N+1\).
Proof
This lemma is a slightly modified version of Lemma 5.3 of [4]. The proof is an elementary computation of geometric sums and almost identical to the proof in [4] so we omit it. \(\square \)
Lemma 5.11
Let \(n\ge 1\) be an integer and \(z_1,\ldots ,z_n\) be complex numbers such that \(\prod _{j=\ell }^{k}z_j\ne 1\) for all \(1\le \ell \le k\le n\). Then
Proof
Fixing an integer \(M>n\), consider the following sum:
We calculate the sum in two different ways: from right to left or from left to right. Namely we set
and
Then clearly \(S^{r\rightarrow \ell }_M=S^{\ell \rightarrow r}_M \). Now the two sums are calculated by calculating the (almost) geometric sums one by one either from left to right or vice versa. There are \(2^n\) terms in total for both sums since every single term produces two terms after performing the geometric sum once. Each of the terms contains of a factor of the form \(\prod _{j= n-k+1}^{n} z_j^{M-n+1}\) for some \(0\le k\le n\) where \(k=0\) corresponds to the terms containing no such factor. For each k we combine all the terms with the same factor \(\prod _{j= n-k+1}^{n} z_j^{M-n+1}\) and write
and
Where the coefficients \(C^{r\rightarrow \ell }_{k}(z_1,\ldots ,z_n)\)’s and \(C^{\ell \rightarrow r}_{k}(z_1,\ldots ,z_n)\)’s are some very explicit functions in \(z_1,\ldots ,z_n\) independent of M which are analytic for all \(z_i\)’s satisfying the assumption that \(\prod _{j=\ell }^{k} z_j\ne 1\) for all \(1\le k\le \ell \le n\). In particular it is straightforward to check (see Lemma 5.10 for example) that
We claim that \(C^{r\rightarrow \ell }_{k}(z_1,\ldots ,z_n)= C^{\ell \rightarrow r}_{k}(z_1,\ldots ,z_n)\) for all \(0\le k\le n\). This in particular implies (5.18). Due to analyticity it suffices to check this for the \(z_j\)’s satisfying \(|z_j|<1\) for all \(1\le j\le n\). In this case by letting \(M\rightarrow \infty \) in the equality \(S^{r\rightarrow \ell }_M=S^{\ell \rightarrow r}_M\) we see \(C_0^{r\rightarrow \ell }= C_0^{\ell \rightarrow r}\). Similarly
Repeat this procedure we see \(C_k^{r\rightarrow \ell }= C_k^{\ell \rightarrow r}\) for all \(0\le k\le n\). \(\square \)
5.5 Proof of Proposition 5.4: Step 2
In this section we simplify the sum (5.9). We rewrite the sum further by first choosing two index sets J and \(J'\) with \(|J|=|J'|=k\) and then expressing the sum in terms of summation over index sets \(J,J'\):
where \(\#(J,J^c):= |\{(m,n)\in (J,J^c): m>n\}|\) and similar for \(\#(J',(J')^c)\). The functions \({\mathscr {H}}_1(J,J')\) and \({\mathscr {H}}_2(J^c,(J')^c)\) are defined as follows:
and
By Lemma 5.12 below (which is of interest on its own) we have
To simplify \({\mathscr {H}}_2(J^c,(J')^c)\) we use the assumption that \({\vec {w}}\in ({\mathcal {S}}_z)^N\) and \({\vec {w}}'\in ({\mathcal {S}}_{z'})^N\). Namely for all \(1\le i,i'\le N\) we have
Inserting (5.23) into (5.21) we get
Now in order to apply Lemma 5.12 we reflect the permutations by defining \({\hat{\pi }}:\{1,\ldots ,N-k\}\rightarrow J^c\) as \({\hat{\pi }}(j):=\pi (N-j+1)\) for \(1\le j\le N\) and similarly for \({\hat{\pi }}':\{1,\ldots ,N-k\} \rightarrow (J')^c\). Then
Now apply Lemma 5.12 again with the role of \({\vec {w}}\) and \({\vec {w}}'\) exchanged we have
Here the extra factor in (5.25) comes from the fact that in (5.24) the product starts from \(i=1\) instead of \(i=2\) and the exponent is i instead of \(i-1\) comparing to (5.26). This completes Step 2 of the proof.
Lemma 5.12
Let \(n\in {\mathbb {N}}\). Given any complex numbers \(w_i\) and \(w_{i'}'\), \(i=1,\ldots ,n\) such that \(w_i\ne w_{i'}\), for all \(1\le i,i'\le n\). Then for any \(0< p<1\) we have
Remark 5.13
Equation (5.26) should be understood also as a Cauchy summation identity (simpler version than Proposition 5.4, for summation over all partitions \(\lambda =(x_1-n+1, x_2-n+2,\ldots ,x_n)\) with at most \(n-1\) rows) of the symmetric funtions \(\Psi _{{\vec {x}}}^{r}({\vec {w}})/\Delta ({\vec {w}})\) and \(\Psi _{{\vec {x}}}^{\ell }({\vec {w}}')/\Delta ({\vec {w}}')\), where \(\Delta ({\vec {w}})\) is the usual Vandermonde determinant. In fact formally we have
assuming all the infinite geometric series converge absolutely.
Proof of Lemma 5.12
The proof is based on induction on n. The main tools are several rank-one perturbation formulas for the Cauchy determinants. Since we will use them several times we will collect them in a separate section, see Sect. 5.7. For \(n=1\), (5.26) is trivial. Let \(n\ge 2\) and assume (5.26) is true for all indices \(\le n-1\). Given \(\sigma ,\sigma '\in S_n\) we first choose two indices \(\ell =\sigma (1)\) and \(\ell '=\sigma '(1)\) and shift the restriction of \(\sigma \) and \(\sigma '\) on \(\{2,\ldots ,n\}\) by 1 but still denote them by \(\sigma \) and \(\sigma '\). Then
By the induction hypothesis the term inside the big bracket above equals
Hence
Here we set \(A(z):=\prod _{i=1}^{n}(z-w_i)\) and \(B(z):= \prod _{i=1}^{n}(z-w_i')\) and \(D_1\), \(D_2\) represent the first and second sum over \(\ell , \ell '\) respectively. Now by (5.44) and Lemma 5.17 we have
and
Inserting (5.29) and (5.30) into (5.28), after necessary cancellation we obtain
This completes the proof of Lemma 5.12. \(\square \)
Finally inserting (5.22) and (5.25) into (5.19) and apply Lemma 5.14 below we obtain
where
Note that in the first equality of (5.32) we have added an extra term corresponding to \(|J|=|J'|=0\) comparing to (5.19) which is harmless since the summand is 0 in this case.
Lemma 5.14
(Lemma 5.9 of [4]) For two \(n\times n\) matrices A and B,
5.6 Proof of Proposition 5.4: Step 3
In this section we further simplify equation (5.32) to conclude the proof of Proposition 5.4. We compute \(\det [{\hat{C}}(i,i')]\) first. For notational convenience we set \((z'/z)^L:=\mu \). Note that
Hence by Lemma 5.16 and Lemma 5.17 we have
Here \(C(i,i') = \frac{1}{w_i-w_{i'}'}\) and A(0) is the evaluation at \(z=0\) of the polynomial \(A(z):=\prod _{j=1}^{N}(z-w_j)\). The other terms involving \(A(\cdot )\) and \(B(\cdot )\) are defined in a similar way with \(B(z):= \prod _{j=1}^{N}(z-w_{j}')\). Now by Lemma 5.15 we have
where \({\hat{C}}^{\ell ,k}\) is the matrix obtained by removing row \(\ell \) and column k from \({\hat{C}}\). Similarly
Now since \({\hat{C}}^{\ell ,k}\) has the same entries as \({\hat{C}}\) only omitting row \(\ell \) and column k, by (5.35) we have
Where \(C^{\ell ,k}\) is obtained from removing row \(\ell \) and column k from the \(N\times N\) Cauchy matrix C with \(C(i,i')=\frac{1}{w_i-w_{i'}'}\) and \(A(z):=\prod _{j=1}^{N}(z-w_j)\) and \(B(z):=\prod _{j=1}^{N}(z-w_j')\). Inserting (5.38) into (5.36) we see
Similarly
Now by (5.45) and Lemma 5.17 we have
Inserting (5.41) into (5.39) and (5.40) and combine with (5.32), after some tedious simplification we conclude that
This completes the proof of Proposition 5.4.
5.7 Perturbation formulas for Cauchy determinants
In this section we collect all the elementary linear algebra facts needed in the proof of Proposition 5.4. Some of them have already been discussed in [4]. First we state a general linear algebra lemma on rank-one perturbations:
Lemma 5.15
Let \(D=[D_{ij}]_{i,j=1}^n\) be an \(n\times n\) matrix. Then for any function \(f,g: {\mathbb {C}}\rightarrow {\mathbb {C}}\) and complex numbers \(x_1,\ldots ,x_n\), \(y_1,\ldots ,y_n\) we have
where \(D^{\ell ,k}\) is obtained by removing row \(\ell \) and column k from D.
Proof
For D invertible, by the rank-one property and the Cramer’s rule we have
For general matrix D we pick \(\{\epsilon _k\}_{k=1}^\infty \) such that \(\epsilon _k\rightarrow 0\) as \(k\rightarrow \infty \) and \(D+\epsilon _k I_n\) are invertible for all \(\epsilon _k\). Now apply the above argument for \(D+\epsilon _k I_n\) and let \(k\rightarrow \infty \). \(\square \)
Next we specialize to the case of C being a Cauchy matrix when the minors can be explicitly calculated:
Lemma 5.16
Assume further that the matrix C is a Cauchy matrix with (i, j)-th entry \(\frac{1}{x_i-y_j}\) for distinct complex numbers \(x_1,\ldots , x_n\) and \(y_1,\ldots ,y_n\). Then we further have
Here \(A(z):= \prod _{i=1}^{n}(z-x_i)\) and \(B(z):= \prod _{i=1}^{n}(z-y_i)\) are monic polynomials with roots at \(x_i\)’s and \(y_i\)’s.
Proof
For Cauchy matrix C we have
Note that \(C^{\ell ,k}\) is also a Cauchy matrix so we have
Hence
Now (5.43) and (5.45) imply (5.44). \(\square \)
For special choices of f and g, (5.44) can be further simplified using the residue theorem. We list here all the situations encountered in the proof of Proposition 5.4.
Lemma 5.17
Given distinct complex numbers \(x_1,\ldots ,x_n\) and \(y_1,\ldots ,y_n\). Let C be the Cauchy matrix with (i, j)-th entry \(\frac{1}{x_i-y_j}\) and \(A(z)= \prod _{i=1}^{n}(z-x_i)\) and \(B(z)= \prod _{i=1}^{n}(z-y_i)\). Then
-
(1)
For \(f(x) = \frac{x}{(1+x)(1+px)}\) and \(g(y)=\frac{1+py}{y}\) we have \(\sum _{k,\ell =1}^{n}\frac{f(x_\ell )B(x_\ell )A(y_k)g(y_k)}{(x_\ell -y_k)A'(x_\ell )B'(y_k)}\) equals
$$\begin{aligned} -\frac{1}{1-p}\cdot \left[ \left( \frac{A(0)}{B(0)}-1\right) \frac{B(-1/p)}{A(-1/p)}+ \left( p-\frac{A(0)}{B(0)}\right) \frac{B(-1)}{A(-1)}+1-p\right] .\nonumber \\ \end{aligned}$$(5.46) -
(2)
For \(f(x) = \frac{x}{1+px}\) and \(g(y)=\frac{1+py}{y(1+y)}\) we have \(\sum _{k,\ell =1}^{n}\frac{f(x_\ell )B(x_\ell )A(y_k)g(y_k)}{(x_\ell -y_k)A'(x_\ell )B'(y_k)}\) equals
$$\begin{aligned} -\frac{1}{p}\cdot \left[ \left( 1-\frac{B(-1/p)}{A(-1/p)}\right) \frac{A(0)}{B(0)}+ \left( p-1+\frac{B(-1/p)}{A(-1/p)}\right) \frac{A(-1)}{B(-1)}-p\right] .\nonumber \\ \end{aligned}$$(5.47) -
(3)
For \(f(x) = \frac{1}{1+x}\) and \(g(y)= 1\) we have
$$\begin{aligned} \sum _{k,\ell =1}^{n}\frac{f(x_\ell )B(x_\ell )A(y_k)g(y_k)}{(x_\ell -y_k)A'(x_\ell )B'(y_k)} = \frac{B(-1)}{A(-1)}-1. \end{aligned}$$(5.48)
Proof
We will only prove part (1) since the arguments for the other parts are similar. For \(f(z) = \frac{z}{(1+z)(1+pz)}\) and \(g(\xi )=\frac{1+p\xi }{\xi }\) we consider the following double contour integral:
Where \(R>r\) are both large enough so that all the possible poles of the integrand are inside the integral contours. Now since for fixed r the integrand is of order \(O(R^{-2})\), the double integral goes to 0 as \(R\rightarrow \infty \). Thus for all R large enough the double contour integral equals 0. On the other hand by the residue theorem we have
Where in the first equality the first contour integral is \(O(R^{-2})\) hence 0 for R large enough. The single sum over \(1\le k\le n\) can be obtained as the residue terms for the following single contour integral:
Here r is large enough so that \(|\xi |=r\) contains all possible poles of the integrand inside. On the other hand by considering the residue at \(\infty \) we have \(\oint _{|\xi |=r} \frac{d\xi }{2\pi i}\frac{1+p\xi }{\xi (1+\xi )}\frac{A(\xi )}{B(\xi )} = p\). Hence
Similar residue analysis on the contour integral \(\oint _{|\xi |=r} \frac{{\mathrm {d}}\xi }{2\pi \mathrm {i}}\frac{1}{\xi }\frac{A(\xi )}{B(\xi )}\) gives
Inserting (5.50) and (5.51) into (5.49) we obtain
This completes the proof of part (1). \(\square \)
5.8 Proof of Corollary 5.3 and 5.6
Finally we discuss how Corollaries 5.3 and 5.6 follows from the Propositions using periodicity. For given \({\vec {x}}=(x_1,\ldots ,x_N)\in {\mathcal {X}}_{N}^{(L)}\) and \(0\le k\le N-1\), set \({\vec {x}}':=(x_1',\ldots ,x_N')=(x_{N-k+1}+L,\ldots , x_N+L,x_1,\ldots ,x_{N-k})\). Then the condition \({\vec {x}}\in {\mathcal {X}}_{N}^{(L)}\cap \{x_{N-k}\ge a\}\) is the same as \({\vec {x}}'\in {\mathcal {X}}_{N}^{(L)}\cap \{x_N'\ge a\}\). Now consider
We move the first k columns of the matrix to the end. The resulting determinant equals \((-1)^{k(N-1)}\) times the determinant of the matrix whose (i, j)-th entry has the form \(\left( \frac{w_i}{1+pw_i}\right) ^{1-j-k}(1+w_i)^{-x_{N-j+1}'+j+k-1}\) for \(1\le j\le N-k\) and the form \(\left( \frac{w_i}{1+pw_i}\right) ^{1-j-k+N}(1+w_i)^{-x_{N-j+1}'+j+k-1+L-N}\) for \(N-k+1\le j\le N\). But since \(\left( \frac{w_i}{1+pw_i}\right) ^N(1+w_i)^{L-N}=z^L\) for all \(1\le i\le N\), we have
After factoring out the common factor \(\left( \frac{w_i}{1+pw_i}\right) ^{-k}(1+w_i)^{k}\) from each row and \(z^L\) from the last k columns we conclude that
Hence
Corollary 5.6 follows from Proposition 5.4 in a similar way.
6 Large-time asymptotics under relaxation time scale
In this section we discuss the large time limit of the multi-point distribution of dpTASEP(\(L,N,{\vec {y}}\)) under the relaxation time scale \(t=O(L^{3/2})\). In Theorem 2.4 we state the limit theorem for general initial condition satisfying certain assumptions. Below are the precise assumptions on the initial conditions we need:
6.1 Assumptions on the initial condition
We now state the assumptions on the sequence of the initial conditions \({\vec {y}}(L)\) under which we prove the limit theorem. The conditions are in terms of the global energy function and the characteristic function defined in Definition 2.12.
Recall that the finite-time formula (2.4) involves a m-fold contour integral with respect to \({\vec {z}}=(z_1,\ldots ,z_m)\) for \(0<|z_m|<\cdots<|z_1|<\mathbbm {r}_c\) where the critical radius \(\mathbbm {r}_c\) is defined in (2.16). It turns out that we need to rescale the parameters \(z_i\) to be close to the critical value \(\mathbbm {r}_c\) in order to make the large time limits converge.
Notation 6.1
For given complex parameter z with \(0<|z|<\mathbbm {r}_c\), we introduce the rescaled parameter \(\mathrm {z}\) defined by
The constraint \(0<|z|<\mathbbm {r}_c\) then translates to \(0<|\mathrm {z}|<1\). We introduce a similar rescaling for the parameters \({\vec {z}}=(z_1,\ldots ,z_m)\). Then for \(0<|z_m|<\cdots<|z_1|<\mathbbm {r}_c\), the rescaled parameters satisfy \(0<|\mathrm {z}_m|<\cdots<|\mathrm {z}_1|<1\). Throughout the rest of the paper we will always use \(z_i\) to represent the unscaled parameters and \(\mathrm {z}_i\) to represent the rescaled ones satisfying (6.1).
Assumption 6.2
We assume that the sequence of the initial profiles \({\vec {y}}={\vec {y}}(L)\) satisfies the following three conditions as \(L\rightarrow \infty \).
-
(A)
(Convergence of global energy) There exist a constant \(r\in (0,1)\) and a non-zero function \(E_{\mathrm {ic}}(\mathrm {z})\) such that for every \(0<\epsilon <1/2\),
$$\begin{aligned} {\mathcal {E}}_{{\vec {y}}} (z) = E_{\mathrm {ic}}(\mathrm {z}) \left( 1+ O(L^{\epsilon -1/2})\right) , \end{aligned}$$uniformly for \( |\mathrm {z}|< {r}\) as \(L\rightarrow \infty \).
-
(B)
(Convergence of characteristic function) There exist constants \(0<r_1<r_2<1\) and a function \(\mathrm {ch}_{\mathrm {ic}}(\eta ,\xi ;\mathrm {z})\) such that for every \(0<\epsilon <1/8\),
$$\begin{aligned} \chi _{{\vec {y}}}(v,u; z) = \mathrm {ch}_{\mathrm {ic}}(\eta ,\xi ;\mathrm {z}) + O(L^{4\epsilon - 1/2}), \end{aligned}$$uniformly for \( r_1<|\mathrm {z}|< r_2\), \(u\in {\mathcal {L}}_z^{(\epsilon )}\) and \(v \in {\mathcal {R}}_z^{(\epsilon )}\) as \(L\rightarrow \infty \) where
$$\begin{aligned} \xi = {\mathcal {M}}_{L,\mathrm {left}} (u)\in \mathrm {L}_{\mathrm {z}} \quad \text {and}\quad \eta = {\mathcal {M}}_{L,\mathrm {right}}(v) \in \mathrm {R}_{\mathrm {z}} \end{aligned}$$are the images under the maps defined in Lemma 7.4.
-
(C)
(Tail estimates of characteristic function) Let \(r_1\) and \(r_2\) be same as in (B). There are constants \(\epsilon '', C'>0\) such that
$$\begin{aligned} |\chi _{{\vec {y}}}(v,u; z)| \le C' L^{\epsilon ''}, \end{aligned}$$(6.2)for all \((v,u)\in {\mathcal {R}}_z\times {\mathcal {L}}_z\) for all \(r_1<|\mathrm {z}|<r_2\).
6.2 Step and flat initial conditions
It turns out that Assumption 6.2 is not easy to check in general. Nevertheless we are able to verify them for at least the classical step and flat initial conditions. The following proposition combined with Theorem 2.4 gives the corresponding limit theorems for dpTASEP starting with step and flat initial conditions.
Proposition 6.3
-
(i)
For the step initial condition \({\vec {y}}_{\mathrm {step}}=(-1,-2,\ldots -N)\), Assumption 6.2 holds with
$$\begin{aligned} E_{\mathrm {step}}(\mathrm {z}) = 1 \quad \text {and}\quad \mathrm {ch}_{\mathrm {step}} (\eta ,\xi ;\mathrm {z}) = 1. \end{aligned}$$(6.3) -
(ii)
For the flat initial condition \({\vec {y}}_{\mathrm {flat}}=(-d,\ldots ,-Nd)\), where we assume \(d=L/N\in {\mathbb {N}}\), Assumption 6.2 holds with
$$\begin{aligned} E_{\mathrm {flat}}(\mathrm {z}) = (1-\mathrm {z})^{-1/4} e^{-B(\mathrm {z})} \quad \text {and}\quad \mathrm {ch}_{\mathrm {flat}} (\eta ,\xi ;\mathrm {z}) = e^{-\mathrm {h}(\xi ,\mathrm {z})-\mathrm {h}(\eta ,\mathrm {z})}\eta (\eta -\xi ){\mathbf {1}}_{\xi =-\eta }\nonumber \\ \end{aligned}$$(6.4)for \(0<|\mathrm {z}|<1\), where \(B(\mathrm {z})\) is defined in (6.14), \(\mathrm {h}(\zeta ,\mathrm {z})\) is defined in (6.15) and (6.16).
The step case is trivial since by the discussion in Remark 2.13 we have \({\mathcal {E}}_{\mathrm {step}}(z)=\chi _{\mathrm {step}}(v,u;z)\equiv 1\). The calculation for the flat case is a bit more involved and we postpone the proof to Sect. 7.5.
6.3 Formula for the limiting distribution
The following formula for the relaxation-time limiting distribution was first obtained in [4] for the step initial condition and [5] for more general initial conditions. The formula involves \(\mathrm {C_{\mathrm {ic}}^{\mathrm {per}}}({\vec {\mathrm {z}}})\) which are limits of \({\mathscr {C}}_{{\vec {y}}}^{(L)}({\vec {z}})\) and operators \(\mathrm {K}_{1}^{\mathrm {per}}\) and \(\mathrm {K}_{\mathrm {ic}}^{\mathrm {per}}\) which are limits of \({\mathscr {K}}_{1}^{(L)}\) and \({\mathscr {K}}_{{\vec {y}}}^{(L)}\). The operators \(\mathrm {K}_{1}^{\mathrm {per}}\) and \(\mathrm {K}_{\mathrm {ic}}^{\mathrm {per}}\) are defined on the sets
and
where \(\mathrm {L}_{\mathrm {z}}\) and \(\mathrm {R}_{\mathrm {z}}\) are the sets defined in Definition 6.4. We express the limiting distribution function \({\mathbb {F}}_{\mathrm {ic}}^{\mathrm {per}}\) in terms of the above terms.
Definition 6.4
Given \(0<|\mathrm {z}|<1\), we define the discrete sets \(\mathrm {S}_{\mathrm {z}}:= \mathrm {L}_{\mathrm {z}}\cup \mathrm {R}_{\mathrm {z}}\) where
Definition 6.5
(Limiting function) Let \({\mathbf {x}} = (\mathrm {x}_1,\ldots ,\mathrm {x_m})\), \(\varvec{\gamma } = (\gamma _1,\ldots ,\gamma _m)\), and \(\varvec{\tau } = (\tau _1,\ldots ,\tau _m)\) be points in \(\mathrm {R}^m\) such that \(\mathrm {p}_j = (\gamma _j,\tau _j) \in [0,1]\times {\mathbb {R}}_{>0}\). Assume that
and that \(\mathrm {x}_i<\mathrm {x}_{i+1}\) when \(\tau _i=\tau _{i+1}\) for \(i=1,\ldots ,m-1\). Define
where \({\vec {\mathrm {z}}} = (\mathrm {z}_1,\ldots ,\mathrm {z}_m)\) and the contours are nested circles satisfying \(0<|\mathrm {z}_m|<\cdots<|\mathrm {z}_1|<1\) and also, \(r_1<|\mathrm {z}_1|<r_2\) with \(r_1,r_2\) being the constants in Assumption 6.2 (B). The first function in the integrand is given by
The second function is given by
where \(\mathrm {K}_{1}^{\mathrm {per}}: \ell ^2(\mathrm {S}_2) \rightarrow \ell ^2(\mathrm {S}_1)\) and \(\mathrm {K}_{\mathrm {ic}}^{\mathrm {per}}: \ell ^2(\mathrm {S}_1) \rightarrow \ell ^2(\mathrm {S}_2)\) are given by \(\mathrm {K}_{1}^{\mathrm {per}}:= \mathrm {K}_{\mathrm {step},1}^{\mathrm {per}}\) and
The function \(\mathrm {C}_{\mathrm {step}}^{\mathrm {per}}({\vec {\mathrm {z}}})\) and kernels \(\mathrm {K}_{\mathrm {step},1}^{\mathrm {per}}\) and \(\mathrm {K}_{\mathrm {step},2}^{\mathrm {per}}\) are first obtained in [4] and the definitions will be recalled in the next two sections for completeness.
6.4 The factor \(\mathrm {C}_{\mathrm {step}}^{\mathrm {per}} ({\vec {\mathrm {z}}})\)
Let \(\mathrm {Li}_s(\mathrm {z})\) be the polylogarithm function which is defined by
for \(|\mathrm {z}|<1\) and \(s\in {\mathbb {C}}\). Set
Let \(\log \mathrm {z}\) denote the principal branch of the logarithm function with branch cut \({\mathbb {R}}_{\le 0}\). Set
for \(0<|\mathrm {z}|, |\mathrm {z}'|<1\) where the integral contours are the vertical lines \(\mathrm {Re}(\xi ) = \mathrm {a}\) and \(\mathrm {Re}(\eta ) = \mathrm {b}\) with constants \(\mathrm {a}\) and \(\mathrm {b}\) satisfying \(-\sqrt{-\log |\mathrm {z}|}<\mathrm {a}<0<\mathrm {b} <\sqrt{-\log |\mathrm {z}'|}\). We also set \(B(\mathrm {z}):= B(\mathrm {z},\mathrm {z})\). One can check that
Definition 6.6
For \({\vec {\mathrm {z}}} = (\mathrm {z}_1,\ldots ,\mathrm {z}_m)\) satisfying \(0<|\mathrm {z}_j|<1\) and \(\mathrm {z}_j \ne \mathrm {z}_{j+1}\) for all j, we define
where we set \(\mathrm {z}_{m+1}=0\).
Note that \(\mathrm {C}_{\mathrm {step}}^{\mathrm {per}}({\vec {\mathrm {z}}})\), and hence \(\mathrm {C}_{\mathrm {ic}}^{\mathrm {per}}({\vec {\mathrm {z}}})\), depend on \(\mathrm {x}_i\) and \(\tau _i\), but not the spatial parameters \(\gamma _i\).
6.5 The operators \(\mathrm {K}_{\mathrm {step},1}^{\mathrm {per}}\) and \(\mathrm {K}_{\mathrm {step},2}^{\mathrm {per}}\)
Set
and define
For each i, define
where we set \(\tau _0=\gamma _0=\mathrm {x}_0=0\). We also define
where we set \(\mathrm {z_0} =\mathrm {z}_{m+1}=0\).
Definition 6.7
Let \(\mathrm {S}_1\) and \(\mathrm {S}_2\) be the discrete sets defined in (6.5) and (6.6). Let
denote the operators defined by their kernels
and
for
with \(1\le i,j\le m\). Here \(\mathrm {L}_{\mathrm {z}_i}\) and \(\mathrm {R}_{\mathrm {z}_i}\) are again defined in Definition 6.4.
7 Proof of Theorem 2.4
In this section we discuss the proof of Theorem 2.4. The ideas are similar to the one in [4, 5] so we omit some technical details. Clearly the theorem follows immediately from the following two lemmas, dealing with the asymptotics of \({\mathscr {C}}_{{\vec {y}}}^{(L)}(z)\) and \({\mathscr {D}}_{{\vec {y}}}^{(L)}(z)\) appearing in the finite-time formula (2.4), respectively.
Lemma 7.1
(Asymptotics of \({\mathscr {C}}_{{\vec {y}}}^{(L)}({\vec {z}})\)) Under the same assumption as in Theorem 2.4, we have for fixed \(0<\epsilon <1/2\)
The functions \({\mathscr {C}}_{{\vec {y}}}^{(L)}(z)\) and \(\mathrm {C}_{\mathrm {ic}}^{\mathrm {per}}(\mathrm {z})\) are defined in (2.23) and (6.9) respectively, with \(z_i^L=(-1)^N\mathbbm {r}_c^L\mathrm {z}_i\), for \(1\le i\le m\).
Lemma 7.2
(Asymptotics of \({\mathscr {D}}_{{\vec {y}}}^{(L)}({\vec {z}})\)) Under the same assumption as in Theorem 2.4, we have the convergence
where the Fredholm determinants \({\mathscr {D}}_{{\vec {y}}}^{(L)}({\vec {z}})\) and \(\mathrm {D}_{\mathrm {ic}}^{\mathrm {per}}({\vec {\mathrm {z}}})\) are defined in Definition 2.15 and (6.10), respectively, and the convergence is locally uniform in \({\vec {\mathrm {z}}}\). Here again \(z_i\) and \(\mathrm {z}_i\) are related by the equation \(z_i^L=(-1)^N\mathbbm {r}_c^L\mathrm {z}_i\).
The rest of the section is devoted to proving Lemmas 7.1 and 7.2. We start with a discussion on the asymptotic behaviors of the roots of the Bethe polynomial \(q_z(w)= w^N(1+w)^{L-N}-z^L(1+pw)^N\) under the critical re-scaling in Sect. 7.1. Then in Sect. 7.2 we list a few lemmas discussing the asymptotics of several products involving these roots under the critical re-scaling. With these preparations we prove Lemmas 7.1 and 7.2 in Sects. 7.3 and 7.4, respectively. Finally in Sect. 7.5 we verify the Assumption 6.2 for the classical step and flat initial conditions.
7.1 Asympotics of the Bethe roots
We assume that the particle density \(\rho :=N/L\) stays within a compact subset of (0, 1) for all L. From the discussion in Sect. 2.3 we know the level set \(\{w\in {\mathbb {C}}: |w^N(1+w)^{L-N}|=|z^L(1+pw)^N|\}\) consists of two disjoint closed contour for \(|z|<\mathbbm {r}_c\) so we can define:
Definition 7.3
Given \(|z|<\mathbbm {r}_c\), we define two closed contours \(\Lambda _L\) and \(\Lambda _R\) by
A formal Taylor expansion at \(w=w_c\) indicates that as \(L\rightarrow \infty \), the Bethe equation \(w^N(1+w)^{L-N}=z^L(1+pw)^N\) converges to the equation
where \(z^L = (-1)^{N}\mathbbm {r}_c^L \mathrm {z}\) and
where \(\nu := \sqrt{1-4p\cdot \rho (1-\rho )}\) and \(c_0:=\frac{1+\nu -2\rho }{1+\nu }\sqrt{\frac{\rho }{(1-\rho )\nu }} \). The solution of equation (7.4) is a discrete set given by \(\{\pm \sqrt{-2\log \mathrm {z}+4k\pi i}: k\in {\mathbb {Z}}\}\) for an arbitrary choice of branch of the logarithm and square root, see Fig. 2. Lemma 7.4 below precisely quantifies the convergence of the Bethe roots near \(w=w_c\) to the corresponding roots of the limiting equation.
Lemma 7.4
For any \(0<\epsilon <1/8\) and \(|z|<\mathbbm {r}_c\) fixed, we define
where \({\mathbb {D}}(a, r)\) is a disc centered at a with radius r and \(c_0\) is defined in (7.5). Then for the re-scaled parameter \(\mathrm {z}= (-1)^N z^L\mathbbm {r}_c^{-L}\) we have an injective map \({\mathcal {M}}_{L,\text {left}}: {\mathcal {L}}_{z}^{(\epsilon )}\rightarrow \mathrm {L}_{\mathrm {z}}\) satisfying
for all \( u\in {\mathcal {L}}_{z}^{(\epsilon )}\) and L large enough. Furthermore, the map satisfies
Similar results hold if we replace \({\mathcal {L}}_{z}\) and \(\mathrm {L}_{\mathrm {z}}\) by \({\mathcal {R}}_{z}\) and \(\mathrm {R}_{\mathrm {z}}\).
Proof
This lemma is a minor generalization of Lemma 8.1 of [3] by allowing one extra parameter p in the Bethe equation. The proof is almost identical to the one in [3] so we omit the details. \(\square \)
7.2 Asymptotics of various products over Bethe roots
In this section we collect all the results involving limits of products of the Bethe roots appearing in the finite-time formula that are independent of the parameters \({\vec {y}}\), \(a_i\), \(t_i\) and \(k_i\). The starting point is the following simple integral formula for the sums of functions evaluated at the left or right Bethe roots.
Lemma 7.5
Let \(\phi (w)\) be a function analytic in the interior and a neighborhood of \(\Lambda _R\). Then
where we recall that \(J(w)=\frac{w(w+1)(1+pw)}{N+Lw+p(L-N)w^2}\). Similarly if \(\phi (w)\) be a function analytic in the interior and a neighborhood of \(\Lambda _L\), then
Here \(\Sigma _{\mathrm {L}}\) and \(\Sigma _{\mathrm {R}}\) are simple closed contours lie in the half-plane \(\{w:\mathrm {Re}(w)<w_c\}\,(\)respectively \(\{w:\mathrm {Re}(w)>w_c\})\) with \(\Lambda _{\mathrm {L}}\) (respectively \(\Lambda _{\mathrm {R}}\)) inside. Taking the function \(\phi \) to be the constant function 1 implies in particular that
Proof
A direct differentiation shows
Hence by the residue theorem we know
The proof for (7.10) is similar. \(\square \)
As taking logarithm transforms products into sums, the following lemma is a direct consequence of Lemma 7.5 and the method of steepest descent.
Lemma 7.6
Given \(|z|<\mathbbm {r}_c\) and \(\mathrm {z}=(-1)^N z^L \mathbbm {r}_c^{-L}\). Suppose \(\rho =N/L\) stays in a compact subset of (0, 1), then for every \(0<\epsilon <1/2\) the following holds for all large enough L.
-
(i)
For \(w=w_c + c_0\zeta L^{-1/2}\) with \(|\zeta |\le L^{\epsilon /4}\), where \(c_0=\frac{1+\nu -2\rho }{1+\nu }\sqrt{\frac{\rho }{(1-\rho )\nu }}\) and \(\nu =\sqrt{1-4p\cdot \rho (1-\rho )}\),
$$\begin{aligned} \frac{z^L(1+pw)^N}{q_z(w)} = \frac{\mathrm {z}}{e^{-\zeta ^2/2}-\mathrm {z}}\cdot \left( 1+O(L^{-1/2+\epsilon })\right) . \end{aligned}$$(7.12) -
(ii)
On the other hand if \(|w-w_c|\ge C\cdot L^{\epsilon -1/2}\) for some \(C>0\), we have for some \(c>0\) and \(\alpha >0\) ,
$$\begin{aligned} \left| \frac{z^L(1+pw)^N}{q_z(w)}\right| \le e^{-cL^{\alpha }}. \end{aligned}$$(7.13) -
(iii)
For w of O(1) distance away from \(0,-1\) and \(-1/p\) we have \(\left| \frac{1}{J(w)}\right| \le C\cdot L\) for some constant \(C>0\). Furthermore if \(w=w_c + c_0\zeta L^{-1/2}\) with \(|\zeta |\le C\cdot L^{\epsilon }\) we have
$$\begin{aligned} \frac{1}{J(w)} = -c_0^{-1}\zeta L^{1/2}\cdot \left( 1+O(L^{\epsilon -1/2})\right) . \end{aligned}$$(7.14) -
(iv)
For \(w= w_c +c_0\zeta L^{-1/2}\) with \(|\zeta |\le L^{\epsilon /4}\), we have
$$\begin{aligned} \begin{aligned} \prod _{u\in {\mathcal {L}}_z} \sqrt{w-u}&= (\sqrt{w+1})^{L-N} e^{\frac{1}{2} \mathrm {h} (\zeta ,\mathrm {z}) } \left( 1+ O(L^{\epsilon -1/2}\log L)\right) \quad \text {if }\mathrm {Re}(\zeta ) \ge 0,\\ \prod _{v\in {\mathcal {R}}_z} \sqrt{v-w}&= (\sqrt{-w})^N e^{\frac{1}{2} \mathrm {h} (\zeta ,\mathrm {z}) } \left( 1+ O(L^{\epsilon -1/2}\log L)\right) \qquad \text {if }\mathrm {Re}(\zeta ) \le 0, \end{aligned} \end{aligned}$$(7.15)where \(\mathrm {h} (\zeta ,\mathrm {z})\) is the function defined in (6.15). When \(\mathrm {Re}(\zeta )=0\), \(\mathrm {h}(\zeta , \mathrm {z})\) is the limit of \(\mathrm {h}(\eta , \mathrm {z})\) as \(\eta \rightarrow \zeta \) from \(\mathrm {Re}(\eta )>0\) for the first case and from \(\mathrm {Re}(\eta )<0\) for the second case.
-
(v)
For w of a finite distance O(1) away from the trajectory \(\Lambda _{\mathrm {L}}\cup \Lambda _{\mathrm {R}}\),
$$\begin{aligned} \begin{aligned} \prod _{u\in {\mathcal {L}}_z} \sqrt{w-u}&= (\sqrt{w+1})^{L-N} \left( 1+ O(L^{\epsilon -1/2})\right) \quad \text {if}\, \mathrm {Re}(w)>w_c, \\ \prod _{v\in {\mathcal {R}}_z} \sqrt{v-w}&= (\sqrt{-w})^N \left( 1+ O(L^{\epsilon -1/2})\right) \qquad \text {if}\, \mathrm {Re}(w)<w_c. \end{aligned} \end{aligned}$$(7.16) -
(vi)
There is a constant \(C>0\) such that for every w satisfying \(|w-w_c|\ge L^{\epsilon -1/2}\),
$$\begin{aligned} e^{-CL^{-\epsilon }}\le \left| \frac{q_{z,\mathrm {L}}(w)}{(w +1)^{L-N}} \right| \le e^{CL^{-\epsilon }} \quad \text {if }\mathrm {Re}(w)>w_c, \end{aligned}$$and
$$\begin{aligned} e^{-CL^{-\epsilon }}\le \left| \frac{q_{z,\mathrm {R}}(w)}{w^N} \right| \le e^{CL^{-\epsilon }} \qquad \text {if }\mathrm {Re}(w)< w_c. \end{aligned}$$ -
(vii)
We have
$$\begin{aligned} \frac{\prod _{v\in {\mathcal {R}}_z} \prod _{u\in {\mathcal {L}}_{z'}} \sqrt{v-u}}{\prod _{u\in {\mathcal {L}}_{z'}} \left( \sqrt{-u}\right) ^N \prod _{v\in {\mathcal {R}}_z} \left( \sqrt{v+1} \right) ^{L-N}} = e^{-B(\mathrm {\mathrm {z},\mathrm {z}'})} \left( 1+O(L^{\epsilon -1/2})\right) ,\nonumber \\ \end{aligned}$$(7.17)where \(B(\mathrm {\mathrm {z},\mathrm {z}'})\) is the function defined in (6.13).
Proof
These estimates are again one-parameter generalizations of Lemma 8.2 and Lemma 8.4 of [3]. The main difference is due to the extra parameter p in the Bethe polynomial \(q_z(w)=w^N(1+w)^{L-N}-z^L(1+pw)^N\), the proper critical point for steepest descent analysis now is at \(w_c=-\frac{2\rho }{1+\sqrt{1-4p\cdot \rho (1-\rho )}}\), which comes from the larger root of the quadratic equation \(p(L-N)w^2+Lw+N=0\), as opposed to \(w=-\rho \) for the \(p=0\) degeneration discussed in [3]. A standard steepest descent analysis using integral representations obtained in Lemma 7.5 with critical point \(w_c\) yields all the estimates. We omit the details. \(\square \)
7.3 Asymptotics of \({\mathscr {C}}_{{\vec {y}}}^{(L)}({\vec {z}})\)
Now we are ready to prove Lemma 7.1. Recall that (see Definition 2.14), \({\mathscr {C}}_{{\vec {y}}}^{(L)}({\vec {z}})= {\mathcal {E}}_{{\vec {y}}}(z_1){\mathscr {C}}_{\mathrm {step}}^{(L)}({\vec {z}})\) where \({\mathcal {E}}_{{\vec {y}}}(z_1)= E_{\mathrm {ic}}(\mathrm {z}_1)\left( 1+O(L^{\epsilon -1/2})\right) \) as \(L\rightarrow \infty \) due to Assumption 6.2. Hence it suffices to prove
where \(\mathrm {C}_{\mathrm {step}}^{\mathrm {per}}({\vec {\mathrm {z}}})\) is defined in Definition 6.6 and \({\mathscr {C}}_{\mathrm {step}}^{(L)}({\vec {z}})\) is defined as follows (see also Definition 2.14):
Here \(E_{\ell }(z):= \prod _{u\in {\mathcal {L}}_z} (-u)^{-k_\ell }\prod _{v\in {\mathcal {R}}_z}(v+1)^{-a_\ell -k_\ell }(pv+1)^{t_\ell -k_\ell }\) with \(E_0(z):=1\). Under the re-scaling \(z_\ell ^L= (-1)^N \mathbbm {r}_c^L \mathrm {z}_\ell \) we clearly have \(\prod _{\ell =2}^{m}\frac{z_{\ell -1}^L}{z_{\ell -1}^L-z_{\ell }^L}= \prod _{\ell =2}^{N}\frac{\mathrm {z}_{\ell -1}}{\mathrm {z}_{\ell -1}-\mathrm {z}_{\ell }}\). On the other hand by Lemma 7.6 (iv)
Hence (7.18) follows immediately once we establish the following lemma on the asymptotics of \(E_{\ell }(z)\).
Lemma 7.7
Let \(E(z)= E(z;a,k,t):= \prod _{u\in {\mathcal {L}}_z} (-u)^{-k}\prod _{v\in {\mathcal {R}}_z}(v+1)^{-a-k}(pv+1)^{t-k}\) where \(a,k\in {\mathbb {Z}}\) and \(t\in {\mathbb {N}}\) are given parameters. Then for \(z^L= (-1)^N\mathbbm {r}_c^L\mathrm {z}\) with \(0<|\mathrm {z}|<1\) and the parameters satisfying
we have for L large enough and fixed \(0<\epsilon <1/2\)
where \(A_1(\mathrm {z})\) and \(A_2(\mathrm {z})\) are scaled polylogarithm functions as in (6.12). The constants \(c_i\) are the same as in (2.8) and the re-scaled parameters are chosen such that \(\tau >0\), \(\gamma \in [0,1]\) and \(\mathrm {x}\in {\mathbb {R}}\).
Proof
Note that \(\log E(z) = \sum _{u\in {\mathcal {L}}_z}(-k)\log (-u)+\sum _{v\in {\mathcal {R}}_z}\big [(-a-k)\log (v+1)+(t-k)\log (1+pv)\big ]\). Apply Lemma 7.5 to the two sums over left and right Bethe roots and deform both contours \(\Sigma _{\mathrm {L}}\) and \(\Sigma _{\mathrm {R}}\) to the vertical line with real part \(w_c= -\frac{2\rho }{1+\sqrt{1-4p\rho (1-\rho )}}\) we have
where \(G(w)= (-k)\log (-w)+(a+k)\log (w+1)+(-t+k)\log (1+pw)\). Note that in (7.21) we have used the fact discussed in Lemma 7.5 that
Now a Taylor expansion at \(w=w_c\) shows
Set \(w=w_c+c_0\zeta L^{-1/2}\) where \(c_0\) is the same as in (7.5) and assume the parameters are re-scaled as in (7.19). After a tedious but straightforward calculation we see that for \(|\zeta |\le L^{\epsilon /4}\) with \(0<\epsilon <1/2\),
Splitting the integral representation for \(\log E(\mathrm {z})\) into two parts with \(|\zeta |\le L^{\epsilon /4}\) and \(|\zeta |> L^{\epsilon /4}\) and using the estimates for \(\frac{z^L(1+pw)^N}{q_z(w)}\) and \(\frac{1}{J(w)}\) obtained in Lemma 7.6 we see
for some constants \(c,\alpha >0\). Now (7.20) follows from integral representations of polylogarithm (6.11). \(\square \)
7.4 Asymptotics of \({\mathscr {D}}_{{\vec {y}}}^{(L)}({\vec {z}})\)
Next we discuss the asymptotics of the Fredholm determinant part \({\mathscr {D}}_{{\vec {y}}}(z)\). Note first that by a standard series expansion of Fredholm determinants we have
where \({\vec {n}}=(n_1,\ldots ,n_m)\) and
where \(U^{(\ell )}= (u^{(\ell )}_{1},\ldots u^{(\ell )}_{n_\ell })\) and \(V^{(\ell )}= (v^{(\ell )}_{1},\ldots v^{(\ell )}_{n_\ell })\) and
and
A similar series expansion holds for the limiting Fredholm determinant \(\mathrm {D}_{\mathrm {ic}}^{\mathrm {per}}({\vec {\mathrm {z}}})\) with \({\mathcal {L}}_{z_{\ell }}\) and \({\mathcal {R}}_{z_{\ell }}\) replaced by the limiting roots \(\mathrm {L}_{\mathrm {z}_{\ell }}\) and \(\mathrm {R}_{\mathrm {z}_{\ell }}\) and the kernels replaced by the limiting kernels \(\mathrm {K}_{1}^{\mathrm {per}}\) and \(\mathrm {K}_{\mathrm {ic}}^{\mathrm {per}}\) defined in Definition 6.7.
We will prove the convergence of each of these \({\mathscr {D}}_{{\vec {y}},{\vec {n}}}^{(L)}({\vec {z}})\) as well as some exponential bounds.
Lemma 7.8
Under the same assumption in Theorem 2.4, for every fixed \({\vec {n}}\in ({\mathbb {Z}}_{\ge 0})^m\), we have
-
(i)
\({\mathscr {D}}_{{\vec {y}},{\vec {n}}}^{(L)}({\vec {z}})\rightarrow \mathrm {D}_{\mathrm {ic},{\vec {n}}}^{\mathrm {per}}(\mathrm {z})\) as \(L\rightarrow \infty \).
-
(ii)
There exists constant \(C>0\) such that \(|{\mathscr {D}}_{{\vec {y}},{\vec {n}}}^{(L)}({\vec {z}})|\le C^{|{\vec {n}}|}\) for all L large enough.
It is clear that Lemma 7.2 follows immediately from Lemma 7.8 by dominated convergence theorem. To prove Lemma 7.8 we will prove the convergence of the kernels after proper conjugation for points inside the critical region as well as exponential decay estimates for the kernel at points outside the critical region. The conjugation is as follows: we replace \({\mathscr {K}}_{1}^{(L)}\) and \({\mathscr {K}}_{{\vec {y}}}^{(L)}\) defined in Definition 2.15 by \(\tilde{{\mathscr {K}}}_{1}^{(L)}\) and \(\tilde{{\mathscr {K}}}_{{\vec {y}}}^{(L)}\) where
for \(w \in ({\mathcal {L}}_{z_i} \cup {\mathcal {R}}_{z_i}) \cap {\mathscr {S}}_1\) and \(w' \in ({\mathcal {L}}_{z_j} \cup {\mathcal {R}}_{z_j}) \cap {\mathscr {S}}_2\). Here
We define the square root to be \(\sqrt{w}= r^{1/2}e^{i\theta /2}\) for \(w=re^{i\theta }\) with \(-\pi <\theta \le \pi \). Note that the product of determinants will always be continuous even though the square root function is not since every \(({\tilde{f}}_i)^{1/2}\) is multiplied twice. We change the limiting kernels in a similar way by replacing \(\mathrm {f_i}\) or \(\mathrm {f}_j\) in the kernels with \(\sqrt{\mathrm {f_i}}\sqrt{\mathrm {f_j}}\) and denote them as \(\tilde{\mathrm {K}}_{1}^{\mathrm {per}}\) and \(\tilde{\mathrm {K}}_{\mathrm {ic}}^{\mathrm {per}}\). Then we have the following asymptotics for the conjugated kernels, which easily implies Lemma 7.8.
Lemma 7.9
Fix \(0<\epsilon <1/(1+2m)\). Let
be a disk centered at \(w_c\). Under the same assumption in Theorem 2.4 we have
-
(i)
As \(L\rightarrow \infty \), uniformly for \(w\in {\mathscr {S}}_1\cap \Omega \) and \(w'\in {\mathscr {S}}_2\cap \Omega \)
$$\begin{aligned}&|\tilde{{\mathscr {K}}}_{1}^{(L)}(w,w')| = |\tilde{\mathrm {K}}_{1}^{\mathrm {per}}(\zeta , \zeta ')| +O(L^{\epsilon -1/2}\log L), \quad \nonumber \\&|\tilde{{\mathscr {K}}}_{{\vec {y}}}^{(L)}(w,w')| = |\tilde{\mathrm {K}}_{\mathrm {ic}}^{\mathrm {per}}(\zeta , \zeta ')| +O(L^{\epsilon -1/2}\log L), \end{aligned}$$(7.32)where \(\zeta \in \mathrm {S}_1, \zeta '\in \mathrm {S}_2\) are the image of \(w, w'\) under either the map \({\mathcal {M}}_{L,\text {left}}\) or \({\mathcal {M}}_{L,\text {right}}\) in Lemma 7.4.
-
(ii)
As \(L\rightarrow \infty \), for \(w_i\in {\mathscr {S}}_1\cap \Omega \) and \(w_i'\in {\mathscr {S}}_2\cap \Omega \),
$$\begin{aligned}&\det \left[ \tilde{{\mathscr {K}}}_{1}^{(L)}(w_i, w'_j)\right] _{i,j=1}^{|{\vec {n}}|} \rightarrow \det \left[ \tilde{\mathrm {K}}_{1}^{\mathrm {per}}(\zeta _i, \zeta '_j)\right] _{i,j=1}^{|{\vec {n}}|}, \quad \\&\det \left[ \tilde{{\mathscr {K}}}_{{\vec {y}}}^{(L)}(w_i, w'_j)\right] _{i,j=1}^{|{\vec {n}}|} \rightarrow \det \left[ \tilde{\mathrm {K}}_{\mathrm {ic}}^{\mathrm {per}}(\zeta _i, \zeta '_j)\right] _{i,j=1}^{|{\vec {n}}|}, \end{aligned}$$for each \({\vec {n}}\in ({\mathbb {Z}}_{\ge 0})^m\), where \(\zeta \in \mathrm {S}_1, \zeta '\in \mathrm {S}_2\) are the image of \(w, w'\) under either the map \({\mathcal {M}}_{L,\text {left}}\) or \({\mathcal {M}}_{L,\text {right}}\) in Lemma 7.4.
-
(iii)
There are positive constants c and \(\alpha \) such that
$$\begin{aligned} |\tilde{{\mathscr {K}}}_{1}^{(L)}(w,w')|= O(e^{-cL^{\alpha }} ), \qquad |\tilde{{\mathscr {K}}}_{{\vec {y}}}^{(L)}(w',w)|= O(e^{-cL^{\alpha }} ) \end{aligned}$$(7.33)as \(L\rightarrow \infty \), uniformly for \(w\in {\mathscr {S}}_1\cap \Omega ^c\) and \(w'\in {\mathscr {S}}_2\), and also for \(w'\in {\mathscr {S}}_2\cap \Omega ^c\) and \(w\in {\mathscr {S}}_1\).
Proof
Due to the structure of the kernel (7.29), the lemma is proved once we establish the corresponding asymptotics and tail estimates for the functions J(w), \(H_{z_i}(w)\) and \({\tilde{f}}_{i}(w)\). For J(w) and \(H_z(w)\) these have already been discussed in Lemma 7.6 (iii), (iv) and (vi). The needed estimates for \({\tilde{f}}_i(w)\) is summarized in the following Lemma 7.10, the proof of which is similar to that of Lemma 7.7 so we omit the details. \(\square \)
Lemma 7.10
Under the same assumption as in Theorem 2.4 for the parameters \(a_i,k_i,t_i\), for \(w=w_c+c_0\zeta L^{-1/2}\) with \(w\in {\mathcal {L}}_z\cup {\mathcal {R}}_z\) we have for fixed \(0<\epsilon <1/2\)
for \(1\le j\le m\), where \(\mathrm {f}_j(\zeta )\) is defined in (6.17).
7.5 Proof of Theorem 6.3
In this section we verify that the flat initial condition satisfies Assumption 6.2 with the limiting functions \(E_{\mathrm {flat}}\) and \(\mathrm {ch}_{\mathrm {flat}}\) given by (6.4). We start with a product formula for the pre-limit functions \({\mathcal {E}}_{\mathrm {flat}}(z)\) and \(\chi _{\mathrm {flat}}(v,u;z)\).
Lemma 7.11
Recall the global energy function \({\mathcal {E}}_{{\vec {y}}}(z)\) and characteristic function \(\chi _{{\vec {y}}}(v,u;z)\) defined in Definition 2.12. For the flat initial condition \({\vec {y}}=(-d,-2d,\ldots ,-Nd)\) with \(d=L/N\in {\mathbb {N}}\) we have
-
(i)
With the standard square root function \(\sqrt{w}\) with branch cut \({\mathbb {R}}_{\le 0}\),
$$\begin{aligned} {\mathcal {E}}_{\mathrm {flat}}(z)= & {} \frac{\prod _{v\in {\mathcal {R}}_z}\left( \sqrt{v+1}\right) ^{2-d}}{\prod _{v\in {\mathcal {R}}_z}\sqrt{p(d-1)v^2+dv+1}}\nonumber \\&\left[ \frac{\prod _{v\in {\mathcal {R}}_z}\prod _{u\in {\mathcal {L}}_z}\sqrt{v-u}}{\prod _{u\in {\mathcal {L}}_z}\left( \sqrt{-u}\right) ^N\prod _{v\in {\mathcal {R}}_z}\left( \sqrt{v+1}\right) ^{L-N}}\right] . \end{aligned}$$(7.35) -
(ii)
For \(v\in {\mathcal {R}}_z\) and \(u\in {\mathcal {L}}_z\),
$$\begin{aligned} \chi _{\mathrm {flat}}(v,u;z) = {\left\{ \begin{array}{ll} \frac{1}{J(v)}\frac{(v+1)^{L-N}u^N}{q_{z,\mathrm {L}}(v)q_{z,\mathrm {R}}(u)}\frac{1+pv}{1+pu}(u-v)\quad &{}\text {if }\ \frac{u(u+1)^{d-1}}{1+pu}=\frac{v(v+1)^{d-1}}{1+pv},\\ 0 &{}\text {otherwise}, \end{array}\right. }\nonumber \\ \end{aligned}$$(7.36)where \(J(w)=\frac{w(w+1)(1+pw)}{p(L-N)w^2+Lw+N}\), \(q_{z,\mathrm {L}}(w):=\prod _{u\in {\mathcal {L}}_z}(w-u)\) and \(q_{z,\mathrm {R}}(w):=\prod _{v\in {\mathcal {R}}_z}(w-v)\).
Proof
The proof is similar to the proof of Lemma 10.2 and Lemma 10.3 in [5]. The key observation is the existence of a \(d-1\) to 1 map \({\mathcal {M}}\) from \({\mathcal {L}}_z\) to \({\mathcal {R}}_z\) satisfying that if \(v={\mathcal {M}}(u)\) for \(u\in {\mathcal {L}}_z\), then \(\frac{u(u+1)^{d-1}}{1+pu}=\frac{v(v+1)^{d-1}}{1+pv}\). Using this relation we can express the global energy and characteristic functions in terms of products over the Bethe roots. We omit the details. \(\square \)
Combining Lemma 7.11 with the asymptotics obtained in Lemma 7.6 we can now prove Theorem 6.3.
Proof of Theorem 6.3
For fixed \(0<\epsilon <1/2\) by Lemma 7.6 (viii) we have
Similarly by Lemma 7.6 (v) we have
On the other hand we have \(p(d-1)v^2+dv+1=p(d-1)(v-w_c)(w-w_c^{*})\) where
Hence by Lemma 7.6 (iv) and (v) we have
where we used the fact that \(w_c\cdot w_{c}^{*}=\frac{1}{p(d-1)}\) and also \(e^{h(0,\mathrm {z})}=(1-\mathrm {z})^{1/2}\) which follows from (6.15). Combining (7.37), (7.38) and (7.39) we conclude that \({\mathcal {E}}_{\mathrm {flat}}(z)= E_{\mathrm {flat}}(\mathrm {z})(1+O(L^{\epsilon -1/2}))\) as \(L\rightarrow \infty \).
The argument for the characteristic function part is quite similar. To verify part (B) of Assumption 6.2 we note that given \(0<\epsilon <1/8\), for \(u\in {\mathcal {L}}_z^{(\epsilon )}\) and \(v\in {\mathcal {R}}_z^{(\epsilon )}\) as defined in Lemma 7.4 we have
where \(\xi ={\mathcal {M}}_{L,\mathrm {left}}(u)\) and \(\eta ={\mathcal {M}}_{L,\mathrm {right}}(v)\) with the injective maps \({\mathcal {M}}_{L,\mathrm {left}}\) and \({\mathcal {M}}_{L,\mathrm {right}}\) defined in Lemma 7.4 satisfying \(\left| \xi -c_0^{-1}L^{1/2}(u-w_c)\right| \le L^{-1/2+3\epsilon }\log L\), \(\quad \left| \eta -c_0^{-1}L^{1/2}(v-w_c)\right| \le L^{-1/2+3\epsilon }\log L\). This then implies that
A straightforward Taylor expansion combined with the injectivity of \({\mathcal {M}}_{L,\mathrm {left}}\) and \({\mathcal {M}}_{L,\mathrm {right}}\) shows
Finally by Lemma 7.6 (iii) we have
Combining (7.40), (7.41), (7.42) and (7.43) we conclude that
Finally part (C) in Assumption 6.2 is clearly true since by Lemma 7.6 every factor in for \(\chi _{\mathrm {flat}}(v,u;z)\) is O(1) except \(\frac{1}{J(v)}\) which is O(L). Thus \(|\chi _{\mathrm {flat}}(v,u;z)|\le C\cdot L\) and part (C) of Assumption 6.2 is satisfied. \(\square \)
8 Multi-time distribution of discrete time parallel TASEP on \({\mathbb {Z}}\)
So far we have been focusing on the so-called relaxation time scale when the period L is comparable to \(t^{2/3}\) and the height fluctuation is critically affected by the boundary conditions. In this section we discuss another important regime, the sub-relaxation time scale \(L\gg t^{2/3}\) when the particles are not affected by the boundary and are expected to behave the same as when the underlying space has infinite-volume.
8.1 Discrete time parallel TASEP with large period
Instead of taking the re-scaled time parameter \(\tau \rightarrow 0\) in the relaxation-time limiting distribution formula, we will start with the pre-limit joint distribution formula (2.4). The following elementary proposition confirms the intuition that for fixed spatial and time parameters \(a_i, k_i\) and \(t_i\), when L is large enough, the joint distribution \({\mathbb {P}}_{{\vec {y}}}^{(L)}(\cap _{i=1}^m\{x_{k_i}(t_i)\ge a_i\})\) agrees with the one when the underlying space is the whole integer lattice \({\mathbb {Z}}\), hence should be independent of L.
Proposition 8.1
Given \({\vec {y}}=(y_1,\ldots ,y_N)\in {\mathcal {X}}_{N}\). Let m be a positive integer and \(k_i\) be integers in \(\{1,\ldots ,N\}\), for \(1\le i\le m\). Then for any integers \(a_i\), \(1\le i\le m\), as long as L is large enough such that
we have
for any positive integers \(t_1,\ldots ,t_m\). Here \({\mathbb {P}}_{{\vec {y}}}^{(L)}\) is the probability with respect to discrete time parallel TASEP on a periodic domain with period L and \({\mathbb {P}}_{{\vec {y}}}^{(\infty )}\) is the probability with respect to an independent discrete time parallel TASEP on the infinite lattice \({\mathbb {Z}}\), both starting with the initial condition satisfying \(x_i(0)=y_i\) for \(1\le i\le N\).
Proof
The proof is almost identical to the similar statement for continuous time TASEP as in Lemma 8.1 of [4] where the particle ordering is reversed. We omit the details. \(\square \)
In principle for every L satisfying (8.1), the left-hand side of (8.2) which has an expression as contour integrals of Fredholm determinant given by (2.4) gives a formula for the multi-point joint distribution of discrete time parallel TASEP on \({\mathbb {Z}}\) for fixed parameters \(a_i,k_i\) and \(t_i\). The main obstacle here is the dependence on the extra parameter L for the left-hand side of (8.2). The key idea to get rid of the dependence on L was already illustrated in Proposition 3.4 (iii) and can be summarized as follows:
-
(1)
By rewriting the sum over the Bethe roots as contour integrals using the residue theorem we get an analytic continuation of the integrand (for the outer integral with respect to z) to \(\{|z|>0\}\).
-
(2)
Under proper assumption on the parameter L (in fact exactly (8.1)), one can further show the integrand is analytic at \(z=0\), thus the outer integral with respect to z equals the evaluation of the integrand at \(z=0\), which turns out to be independent of L.
Now as in the above discussion, we would like to send \(z_1, \ldots , z_m\) all to 0 in (2.4) while still keep the nested relation \(0<|z_m|< \cdots< |z_1|<\mathbbm {r}_c\). For this we change the integral variables as follows: for given L satisfying (8.1), we set
where \(z_0:=1\) and \(0<|z_m|< \cdots< |z_1|<\mathbbm {r}_c\). Then the corresponding relations between \(\theta _i\)’s are precisely \(0<|\theta _0|<\mathbbm {r}_c^{L}:= {\mathbf {r}}_c\) and \(0<|\theta _i|<1\) for \(1\le i\le m-1\). After this change of variable, the finite-time multi-point joint distribution formula (2.4) can be rewritten as
where the integral contours are circle centered at origin with radius smaller than \({\mathbf {r}}_c\) for \(\theta _0\) and circles centered at origin with radii less than 1 for \(\theta _i\), \(1\le i\le m-1\). Here the integrand is defined such that
for any \(z_1,\ldots ,z_m\) satisfying the relations \(z_i^L=\prod _{j=0}^{i-1}\theta _j\) for \(1\le i\le m\). Note that by definition (see Sect. 2.5), \({\mathscr {C}}_{\mathrm {step}}^{(L)}(z_1,\ldots ,z_m)\) and \({\mathscr {D}}_{\mathrm {step}}^{(L)}(z_1,\ldots ,z_m)\) only depend on \(z_1^L,\ldots ,z_m^L\) so \(\hat{{\mathscr {C}}}^{(L)}\) and \(\hat{{\mathscr {D}}}^{(L)}\) are well-defined functions analytic in \({\mathbb {D}}_0({\mathbf {r}}_c)\times ({\mathbb {D}}_0(1))^{m-1}\), where \({\mathbb {D}}_0(r)\) is the disk centered at 0 with radius r with the origin removed.
8.2 Proof of Theorem 2.5
As discussed above, Theorem 2.5 follows immediately once we establish the analyticity of \(\hat{{\mathscr {C}}}_{{\vec {y}}}^{(L)}(\theta _0,\ldots ,\theta _{m-1})\) and \(\hat{{\mathscr {D}}}_{{\vec {y}}}^{(L)}(\theta _0,\ldots ,\theta _{m-1})\) at \(\theta _0=0\) so that we can get rid of the integral with respect to \(\theta _0\) whose value equals the integrand evaluated at \(\theta _0=0\). The precise statement needed are summarized in the following two lemmas which will be proved in the next two subsections.
Lemma 8.2
The function \(\hat{{\mathscr {C}}}_{\mathrm {step}}^{(L)}(\theta _0,\ldots ,\theta _{m-1})\) is in fact analytic in \({\mathbb {D}}({\mathbf {r}}_c)\times ({\mathbb {D}}(1))^{m-1}\), where \({\mathbb {D}}(r)\) is a disk centered at 0 with radius r. Moreover we have
Lemma 8.3
For large enough integer L satisfying (8.1), the function \(\hat{{\mathscr {D}}}_{{\vec {y}}}^{(L)}(\theta _0,\ldots ,\theta _{m-1})\) is analytic in \({\mathbb {D}}({\mathbf {r}}_c)\times ({\mathbb {D}}_0(1))^{m-1}\). Moreover we have for any \((\theta _1,\ldots ,\theta _{m-1})\in ({\mathbb {D}}_0(1))^{m-1}\)
where \({\mathcal {D}}_{\mathrm {step}}^{(\infty )}(\theta _1,\ldots ,\theta _{m-1})\) is defined in Sect. 2.6.
Combing Lemmas 8.2 and 8.3 we conclude that
Finally using (8.2) we complete the proof of Theorem 2.5.
8.3 Proof of Lemma 8.2
By the definition of the function \({\mathscr {C}}_{\mathrm {step}}^{(L)}\) (see Definition 2.14) we know
where \(E_{\ell }(z)= \prod _{u\in {\mathcal {L}}_z} (-u)^{-k_\ell }\prod _{v\in {\mathcal {R}}_z}(v+1)^{-a_\ell -k_\ell }(pv+1)^{t_\ell -k_\ell }\) and the functions \({\mathscr {A}}_i\) represents the products inside each brackets. The parameters \(\theta _i\) and \(z_i\) are related by the equations \(z_i^L=\prod _{j=0}^{i-1}\theta _j\) for \(1\le i\le m\). Now if we send \(\theta _0\rightarrow 0\), then all the \(z_i\)’s will converge to 0. As a result, all the roots in \({\mathcal {L}}_{z_i}\) converge to \(-1\) while all the roots in \({\mathcal {R}}_{z_i}\) converge to 0, for all \(1\le i\le m\). It is then easy to see that for \(j=1,2,3\)
is well-defined and hence \(\hat{{\mathscr {C}}}_{\mathrm {step}}^{(L)}(\theta _0,\theta _1,\ldots ,\theta _{m-1})\) can be analytically continued to the point \(\theta _0=0\) with
8.4 Proof of Lemma 8.3
This Lemma is an analogue of Lemma 5.2 of [15] and the proof is similar so we omit most of the details. What we want to prove is an identity between two Fredholm determinants, with the first one acting on discrete sets consisting of roots of certain polynomials and the other one acting on continuous contours. By looking at the standard series expansions of both Fredholm determinants, it suffices to show that every term in the two series expansions matches. These type of identities between multiple sums over roots of certain algebraic equations and multiple contour integrals can be understood as a highly nontrivial consequence of the residue theorem, which is stated and proved with enough generality for our purpose in Proposition 4.4 of [15]. We take \(q(w)=w^{N}(w+1)^{L-N}(1+pw)^{-N}\) in the proposition and follow the same argument as in Lemma 5.2 of [15].
8.5 KPZ scaling limit
In this final section we briefly discuss the large-time asymptotics for the multi-time distribution of discrete time parallel TASEP on \({\mathbb {Z}}\) under the 1 : 2 : 3 KPZ scaling. For completeness we first recall the definition of the limiting distribution function \({\mathbb {F}}_{\mathrm {step}}^{\mathrm {kpz}}\) which essentially agrees with the function \(F_{\mathrm {step}}\) appearing in Theorem 2.20 of [15] with a slight different choices of the parameters. The structure of \({\mathbb {F}}_{\mathrm {step}}^{\mathrm {kpz}}\) is similar to the finite-time distribution as contour integrals of a Fredholm determinant \(\mathrm {D}_{\mathrm {step}}^{\mathrm {kpz}}(\theta _{1},\ldots ,\theta _{m-1})\).
8.5.1 Spaces of the operators
Given integer \(m\ge 1\). We first define the contour in the complex plane
oriented from \(e^{-\frac{\pi \mathrm {i}}{3}}\infty \) to \(e^{\frac{\pi \mathrm {i}}{3}}\infty \). Then for \(2\le j\le m\), we define the contours
The left contours \(\Gamma _{j,\mathrm {L}}^{\pm }\), \(j=2,\ldots ,m\) and \(\Gamma _{1,\mathrm {L}}\) are defined simply as the reflections of the corresponding right contours about the y-axis, with orientation from \(e^{-\frac{2\pi \mathrm {i}}{3}}\infty \) to \(e^{\frac{2\pi \mathrm {i}}{3}}\infty \). We further denote
and
and
8.5.2 Operators \(\mathrm {K}_1^{\mathrm {kpz}}\) and \(\mathrm {K}_{\mathrm {step}}^{\mathrm {kpz}}\)
Now we introduce the operators \(\mathrm {K}_1^{\mathrm {kpz}}\) and \(\mathrm {K}_{\mathrm {step}}^{\mathrm {kpz}}\) to define \( \mathrm {D}_{\mathrm {step}}^{\mathrm {kpz}}\) in Theorem 2.7.
Definition 8.4
We define
where the two operators
are defined by the kernels
and
where \(1\le i,j\le m\). Here the function \(\mathrm {f}_i(\zeta )\) is the same as the one appearing in the kernels for periodic case defined in (6.17) and \(Q_1^{(\infty )}\) and \(Q_2^{(\infty )}\) are defined in (2.39) and (2.40). We also set
Proof of Theorem 2.7
The proof is a standard steepest descent analysis and most of the key ingredients are similar to Lemma 7.8 so we only provide the essential calculations. First it is not difficult to see that for any nonzero constants \(c_1,\ldots ,c_m\), the Fredholm determinant part \({\mathcal {D}}_{\mathrm {step}}^{(\infty )}\) is invariant if we replace the functions \(F_i\) appearing in the kernels by \({\tilde{F}}_i:= c_i F_i\) for \(1\le i\le m\). For our purpose we set \(c_i=\frac{1}{F_i(w_c)}\) where \(w_c = -\frac{1}{1+\sqrt{q}}\). We point out that this agrees with the critical point for periodic cases defined in (2.15) when \(\rho =1/2\) so the notation is consistent. To ensure the kernels have sufficiently fast decay on each variable we make the same conjugation as in (7.29) by setting
for \(w'\in \Sigma _j\cap {\mathcal {S}}_2,\ w\in \Sigma _i\cap {\mathcal {S}}_1\). Here \({\tilde{f}}_i\) is obtained by replacing \(F_i\) with \({\tilde{F}}_i\) in (2.35). We also conjugate the limiting kernels in a similar way:
for \(\zeta '\in \Gamma _j\cap {\mathbb {S}}_2,\ \zeta \in \Gamma _i\cap {\mathbb {S}}_1\). These conjugations do not change the Fredholm determinants.
Now a straightforward Taylor expansion shows that for \(w=w_c+ \frac{q^{1/4}}{1+\sqrt{q}}\zeta T^{-1/3}\) with \(|\zeta |\le T^{\epsilon /4}\) for \(0<\epsilon <1/3\) we have
where the parameters \(a_i, k_i\) and \(t_i\) satisfies (2.11). On the other for w far away from \(w_c\), \(\frac{F_i(w)}{F_i(w_c)}\) decays or grows exponentially fast. Hence it is straightforward to show that for \(w= -\frac{1}{1+\sqrt{q}}+ \frac{q^{1/4}}{1+\sqrt{q}}\zeta T^{-1/3}\) and \(0<\epsilon <1/3\) we have
Now we deform the contours \(\Sigma _{j}\) to be sufficiently close to the critical points \(w_c=-\frac{1}{1+\sqrt{q}}\) such that locally they look like the limiting contours \(\Gamma _j\). More concretely we deform \(\Sigma _{j,\mathrm {R}}^{+}\) such that
and similar for other contours. Then by (8.15) it is straightforward to show that
-
(1)
For each \(n\in {\mathbb {N}}\) and \(0<|\theta _i|<1\) we have
$$\begin{aligned} \lim _{T\rightarrow \infty } \mathrm {Tr}\left( \tilde{{\mathcal {K}}}_{1}^{(\infty )}\tilde{{\mathcal {K}}}_{\mathrm {step}}^{(\infty )}\right) ^n = \mathrm {Tr}\left( \tilde{\mathrm {K}}_{1}^{\mathrm {kpz}}\tilde{\mathrm {K}}_{\mathrm {step}}^{\mathrm {kpz}}\right) ^n. \end{aligned}$$ -
(2)
There exists constant \(C>0\) independent of T and n such that for all \(n\in {\mathbb {N}}\)
$$\begin{aligned} \left| \oint _{{\mathcal {S}}_1}\cdots \oint _{{\mathcal {S}}_1}\det \left[ \left( \tilde{{\mathcal {K}}}_{1}^{(\infty )}\tilde{{\mathcal {K}}}_{\mathrm {step}}^{(\infty )}\right) (w_i,w_j)\right] _{i,j=1}^n \frac{{\mathrm {d}}w_1}{2\pi \mathrm {i}}\cdots \frac{{\mathrm {d}}w_n}{2\pi \mathrm {i}}\right| \le C^n. \end{aligned}$$
Now (1) and (2) immediately implies \({\mathcal {D}}_{\mathrm {step}}^{(\infty )}(\theta _1,\ldots ,\theta _{m-1}) \text { converges to } \mathrm {D}_{\mathrm {step}}^{\mathrm {kpz}}(\theta _1,\ldots ,\theta _{m-1})\) locally uniformly for \(0<|\theta _i|<1\) as \(T\rightarrow \infty \), thus proving Theorem 2.7. \(\square \)
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Acknowledgements
I would like to thank Jinho Baik for suggesting this problem and for useful discussions. I would also like to thank Zhipeng Liu and Mustazee Rahman for helpful discussions. I am grateful to the two anonymous referees for catching up several typos and to their valuable suggestions which help improve the quality of the paper. This work is supported in part through Jinho Baik’s NSF grants DMS-1664531.
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Liao, Y. Multi-point distribution of discrete time periodic TASEP. Probab. Theory Relat. Fields 182, 1053–1131 (2022). https://doi.org/10.1007/s00440-021-01107-8
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DOI: https://doi.org/10.1007/s00440-021-01107-8