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Negative moments of orthogonal polynomials

Published online by Cambridge University Press:  29 March 2023

Jihyeug Jang
Affiliation:
Department of Mathematics, Sungkyunkwan University, Suwon, South Korea; E-mail: 4242ab@gmail.com
Donghyun Kim
Affiliation:
Applied Algebra and Optimization Research Center, Sungkyunkwan University, Suwon, South Korea; E-mail: hyun923010@g.skku.edu
Jang Soo Kim
Affiliation:
Department of Mathematics, Sungkyunkwan University, Suwon, South Korea; E-mail: jangsookim@skku.edu
Minho Song
Affiliation:
Applied Algebra and Optimization Research Center, Sungkyunkwan University, Suwon, South Korea; E-mail: smh3227@skku.edu
U-Keun Song
Affiliation:
Department of Mathematics, Sungkyunkwan University, Suwon, South Korea; E-mail: sukeun319@gmail.com

Abstract

If a sequence indexed by nonnegative integers satisfies a linear recurrence without constant terms, one can extend the indices of the sequence to negative integers using the recurrence. Recently, Cigler and Krattenthaler showed that the negative version of the number of bounded Dyck paths is the number of bounded alternating sequences. In this paper, we provide two methods to compute the negative versions of sequences related to moments of orthogonal polynomials. We give a combinatorial model for the negative version of the number of bounded Motzkin paths. We also prove two conjectures of Cigler and Krattenthaler on reciprocity between determinants.

Type
Discrete Mathematics
Creative Commons
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Copyright
© The Author(s), 2023. Published by Cambridge University Press

1 Introduction

Suppose that there is a sequence $ (f_n)_{n\in \mathbb {Z}} $ indexed by all integers. If both $|f_n|$ and $|f_{-n}|$ count some combinatorial objects of size $ n\ge 1 $ , such a result is called a combinatorial reciprocity theorem, a term first used by Stanley [Reference Stanley15]. There are many combinatorial reciprocity theorems; three notable examples are when $f_n$ is the binomial coefficient $\binom {n}{k}$ , the chromatic polynomial $\chi _G(n)$ of a graph G and the Ehrhart polynomial $\mathrm {Ehr}_P(n)$ of a lattice polytope P. For more details on combinatorial reciprocity theorems, see the book by Beck and Sanyal [Reference Beck and Sanyal1].

Suppose now that we have a sequence $(f_n)_{n\ge 0}$ indexed by nonnegative integers. If the sequence satisfies a homogeneous linear recurrence relation, then one can extend the indices of this sequence to negative integers $ (f_{-n})_{n\ge 1} $ using the recurrence. Recently, Cigler and Krattenthaler [Reference Cigler and Krattenthaler3] showed that, for a fixed integer k, the negative counterpart of the number of Dyck paths from $ (0,0) $ to $(2n,0)$ with bounded height $2k-1$ is the number of alternating sequences $a_1\le a_2\ge a_3 \le \cdots \ge a_{2n-1}$ of positive integers at most k. They also showed many other interesting results, including a reciprocity between determinants of these numbers and their connection with orthogonal polynomials.

In this paper, motivated by the work of Cigler and Krattenthaler [Reference Cigler and Krattenthaler3], we find combinatorial reciprocity theorems for more general sequences related to moments of orthogonal polynomials. In particular, we give two methods to study such negative sequences. The first method uses continued fractions and the second one uses matrix inverses. Our first method is new, and the key idea of the second method is due to Hopkins and Zaimi [Reference Hopkins and Zaimi8]. We also prove two conjectures on reciprocity between determinants proposed by Cigler and Krattenthaler [Reference Cigler and Krattenthaler3, Conjectures 50, 53]. Before stating our results, we first review basic results in orthogonal polynomials and define some notation.

A sequence $ (P_n(x))_{n\ge 0} $ of polynomials is called an orthogonal polynomial sequence Footnote 1 with respect to a linear functional $ \mathcal {L} $ if for all $ m,n\ge 0 $ , we have $ \deg (P_n(x))=n $ and

(1) $$ \begin{align} \mathcal{L}(P_m(x)P_n(x)) = \delta_{m,n}K_n, \qquad K_n\ne0. \end{align} $$

In this case, we will simply say that $ P_n(x) $ are orthogonal polynomials (with respect to $ \mathcal {L} $ ).

It is well known [Reference Chihara2, Theorem 4.1, p.18] that monic orthogonal polynomials $ P_n(x) $ satisfy a three-term recurrence relation:

(2) $$ \begin{align} P_{n+1}(x) = (x-b_n)P_n(x) -\lambda_n P_{n-1}(x),\quad n\ge0, \qquad P_{-1}(x)=0,P_0(x)=1, \end{align} $$

for some sequences $ \boldsymbol {b}=(b_n)_{n\ge 0} $ and $ \boldsymbol {\lambda }=(\lambda _n)_{n\ge 1} $ with $ \lambda _n\ne 0 $ . Conversely, Favard’s theorem [Reference Chihara2, Theorem 4.4, p.21] states that if monic polynomials $ P_n(x) $ satisfy (2) for some sequences $ \boldsymbol {b}=(b_n)_{n\ge 0} $ and $ \boldsymbol {\lambda }=(\lambda _n)_{n\ge 1} $ with $ \lambda _n\ne 0 $ , then $ P_n(x) $ are orthogonal polynomials with respect to a unique linear function $ \mathcal {L} $ satisfying (1) and $ \mathcal {L}(1)=1 $ .

Let $ P_n(x;\boldsymbol {b},\boldsymbol {\lambda }) $ denote the polynomials satisfying (2). Then by Favard’s theorem, these are orthogonal polynomials with respect to a unique linear functional $ \mathcal {L} $ . The moment $ \mu _{n}(\boldsymbol {b},\boldsymbol {\lambda }) $ of the orthogonal polynomials $ P_n(x;\boldsymbol {b},\boldsymbol {\lambda }) $ is defined by $\mu _{n}(\boldsymbol {b},\boldsymbol {\lambda }) = \mathcal {L}(x^n) $ .

Viennot [Reference Viennot18] found the following combinatorial interpretation for the moment:

$$\begin{align*}\mathcal{L}(x^n) = \mu_n(\boldsymbol{b},\boldsymbol{\lambda})= \sum_{p\in \operatorname{Mot}_{n}} \operatorname{wt}(p;\boldsymbol{b},\boldsymbol{\lambda}), \end{align*}$$

where $ \operatorname {Mot}_{n} $ is the set of Motzkin paths from $ (0,0) $ to $ (n,0) $ and $ \operatorname {wt}(p;\boldsymbol {b},\boldsymbol {\lambda }) $ is a weight of a Motzkin path $ p $ depending on the sequences $ \boldsymbol {b} $ and $ \boldsymbol {\lambda } $ . See Section 2 for the precise definitions.

We define the bounded moments $ \mu _n^{\le k}(\boldsymbol {b},\boldsymbol {\lambda }) $ by

$$\begin{align*}\mu_{n}^{\le k}(\boldsymbol{b},\boldsymbol{\lambda}) := \sum_{p\in \operatorname{Mot}^{\le k}_{n}} \operatorname{wt}(p;\boldsymbol{b},\boldsymbol{\lambda}), \end{align*}$$

where $ \operatorname {Mot}_{n}^{\le k}(\boldsymbol {b},\boldsymbol {\lambda }) $ is the set of Motzkin paths from $ (0,0) $ to $ (n,0) $ that stay weakly below the line $ y=k $ . Then the moments are the limits of the bounded moments:

$$\begin{align*}\mathcal{L}(x^n) = \mu_n(\boldsymbol{b},\boldsymbol{\lambda}) = \lim_{k\to\infty} \mu_{n}^{\le k}(\boldsymbol{b},\boldsymbol{\lambda}). \end{align*}$$

For certain choices of $ \boldsymbol {b},\boldsymbol {\lambda }$ , and $ k $ , the sequence $ (\mu _{n}^{\le k}(\boldsymbol {b},\boldsymbol {\lambda }))_{n\ge 0}$ satisfies a homogeneous linear recurrence relation so that its negative version $ (\mu _{-n}^{\le k}(\boldsymbol {b},\boldsymbol {\lambda }))_{n\ge 1}$ is defined. In this case, we call $ \mu _{-n}^{\le k}(\boldsymbol {b},\boldsymbol {\lambda }) $ the negative (bounded) moments of the orthogonal polynomials $ P_n(x;\boldsymbol {b},\boldsymbol {\lambda }) $ .

Cigler and Krattenthaler [Reference Cigler and Krattenthaler3] showed the following combinatorial reciprocity theorem for the number $ \mu _{2n}^{\le 2k-1}(\boldsymbol {0},\boldsymbol {1}) $ of bounded Dyck paths, where $ \boldsymbol {0}=(0,0,\dots ) $ and $ \boldsymbol {1}=(1,1,\dots ) $ .

Theorem 1.1 [Reference Cigler and Krattenthaler3, Corollary 13].

For positive integers $ n $ and $ k $ ,

$$\begin{align*}\mu_{-2n}^{\le 2k-1}(\boldsymbol{0},\boldsymbol{1}) = |\operatorname{Alt}_{2n-1}^{\le k}|, \end{align*}$$

where $ \operatorname {Alt}_{n}^{\le k} $ is the set of alternating sequences $ (a_1,\dots ,a_n) $ of integers such that $ a_1\le a_2\ge a_3 \le \cdots $ and $ 1\le a_i\le k $ for all $ i $ .

Cigler and Krattenthaler [Reference Cigler and Krattenthaler3] proved Theorem 1.1 using generating functions. We give a new proof of this theorem using continued fractions. To do this, we introduce a notion of $ \ell $ -peak-valley sequences in Definition 3.1 and give a simple bijection between alternating sequences and $ 2 $ -peak-valley sequences.

Using continued fractions, we show in Theorem 3.5 that $ \mu _{-2n}^{\le 2k-1} (\boldsymbol {0},\boldsymbol {\lambda }) $ is a weight-generating function for $ 2 $ -peak-valley sequences with some conditions, which is equivalent to [Reference Cigler and Krattenthaler3, Corollary 32]. Our method also applies to Motzkin paths. In Theorems 4.2 and 4.5, we show that if $ \boldsymbol {b} $ and $ \boldsymbol {\lambda } $ satisfy $ \lambda _i=b_{i-1}b_i $ for all $ i\ge 1 $ , then $ \mu _{-n}^{\le 3k-1}(\boldsymbol {b},\boldsymbol {\lambda }) $ and $ \mu _{-n}^{\le 3k}(\boldsymbol {b},\boldsymbol {\lambda }) $ are weight-generating functions for $ 3 $ -peak-valley sequences with some conditions.

Viennot (see [Reference Viennot18, Proposition 17, p. I.15] or [Reference Viennot19, (5)]) also showed that the generalized moment $ \mu _{n,r,s}(\boldsymbol {b},\boldsymbol {\lambda }) := \mathcal {L}(x^n P_r(x;\boldsymbol {b},\boldsymbol {\lambda }) P_s(x;\boldsymbol {b},\boldsymbol {\lambda })) $ has a similar combinatorial expression

$$\begin{align*}\mu_{n,r,s}(\boldsymbol{b},\boldsymbol{\lambda})= \sum_{p\in \operatorname{Mot}_{n,r,s}} \operatorname{wt}(p;\boldsymbol{b},\boldsymbol{\lambda}), \end{align*}$$

where $ \operatorname {Mot}_{n,r,s}(\boldsymbol {b},\boldsymbol {\lambda }) $ is the set of Motzkin paths from $ (0,r) $ to $ (n,s) $ . We define the generalized bounded moments $ \mu _{n,r,s}^{\le k}(\boldsymbol {b},\boldsymbol {\lambda }) $ by

$$\begin{align*}\mu_{n,r,s}^{\le k}(\boldsymbol{b},\boldsymbol{\lambda}) := \sum_{p\in \operatorname{Mot}^{\le k}_{n,r,s}} \operatorname{wt}(p;\boldsymbol{b},\boldsymbol{\lambda}), \end{align*}$$

where $ \operatorname {Mot}_{n,r,s}^{\le k}(\boldsymbol {b},\boldsymbol {\lambda }) $ is the set of Motzkin paths from $ (0,r) $ to $ (n,s) $ that stay weakly below the line $ y=k $ .

Cigler and Krattenthaler [Reference Cigler and Krattenthaler3] showed that Theorem 1.1 extends nicely to generalized bounded moments as follows.

Theorem 1.2 [Reference Cigler and Krattenthaler3, Corollary 12].

For positive integers $ n,k,r,s $ with $ 1\le r,s\le k $ , we have

$$ \begin{align*} (-1)^{r+s}\mu_{-2n,2r-2,2s-2}^{\le 2k-1}(\boldsymbol{0},\boldsymbol{1}) &= |\operatorname{Alt}_{2n+1,r,s}^{\le k}|,\\ (-1)^{r+s}\mu_{-2n+1,2r-2,2s-1}^{\le 2k-1}(\boldsymbol{0},\boldsymbol{1}) &= |\operatorname{Alt}_{2n,r,s}^{\le k}|, \end{align*} $$

where $ \operatorname {Alt}_{n,r,s}^{\le k} $ is the set of sequences $ (a_1,\dots ,a_n) $ of integers such that $ a_1\le a_2\ge a_3 \le \cdots $ and $ 1\le a_i\le k $ for all $ i $ and such that $ a_1=r $ and $ a_n=s $ .

In Theorems 5.5 and 5.8, we show that if $ \boldsymbol {b} $ and $ \boldsymbol {\lambda } $ satisfy $ \lambda _i=b_{i-1}b_i $ for all $ i\ge 1 $ , then $ \mu _{-n,r,s}^{\le 3k-1}(\boldsymbol {b},\boldsymbol {\lambda }) $ and $ \mu _{-n,r,s}^{\le 3k}(\boldsymbol {b},\boldsymbol {\lambda }) $ are weight-generating functions for $ 3 $ -peak-valley sequences with some conditions.

Cigler and Krattenthaler [Reference Cigler and Krattenthaler3] showed the following reciprocity theorem relating determinants whose entries are $ \mu _{n}^{\le 2k-1}(\boldsymbol {0},\boldsymbol {1}) $ and their negative versions.

Theorem 1.3 [Reference Cigler and Krattenthaler3, Theorem 15].

For all nonnegative integers $n, k, m$ , we have

$$\begin{align*}\det\left(\mu_{2 n+2 i+2 j+4 m-2}^{\le 2 k+2 m-1}(\boldsymbol{0},\boldsymbol{1})\right)_{i, j =0 }^{ k-1} =\det\left(\mu_{-2 n-2 i-2 j}^{\le 2 k+2 m-1}(\boldsymbol{0},\boldsymbol{1})\right)_{i, j =0 }^{ m-1}. \end{align*}$$

Cigler and Krattenthaler [Reference Cigler and Krattenthaler3] proposed the following two conjectures.

Theorem 1.4 [Reference Cigler and Krattenthaler3, Conjecture 50].

For all nonnegative integers $n, k, m$ , we have

$$\begin{align*}\det\left(\sum_{s=0}^{2 k+2 m-1} \mu_{n+i+j+2 m-1,0,s}^{\le 2 k+2 m-1}(\boldsymbol{0},\boldsymbol{1})\right)_{i, j =0 }^{ k-1} =(-1)^{\left(\binom{k}{2}+\binom{m}{2}\right)(n+1)} \det\left(\left|\operatorname{Alt}_{n+i+j}^{\le k+m}\right|\right)_{i, j =0 }^{ m-1}. \end{align*}$$

Theorem 1.5 [Reference Cigler and Krattenthaler3, Conjecture 53].

For all positive integers $ n, k, m $ with $ k+m \not \equiv 2\ \ \pmod 3 $ , we have

$$\begin{align*}\det\left(\mu_{n+i+j+2 m-2}^{\le k+m-1}(\boldsymbol{1},\boldsymbol{1})\right)_{i, j =0 }^{ k-1} \\ =(-1)^{n\left\lfloor (k+m) / 3\right\rfloor} \det\left(\mu_{-n-i-j}^{\le k+m-1}(\boldsymbol{1},\boldsymbol{1})\right)_{i, j =0 }^{ m-1}. \end{align*}$$

In Section 6, we prove a general reciprocity theorem (Theorem 6.1). In Section 7, we prove the above two conjectures using Theorem 6.1. In Section 8, we show that Theorem 6.1 also implies the weighted version of Theorem 1.3 due to Cigler and Krattenthaler [Reference Cigler and Krattenthaler3, Theorem 34]. We then show in Theorem 8.5 that this weighted version gives a bounded and multivariate generalization of the Morales–Pak–Panova ex-conjecture [Reference Morales, Pak and Panova14] on reverse plane partitions, which has been proved by Hwang et al. [Reference Hwang, Kim and Yoo9] and Guo et al. [Reference Guo, Zhao and Zhong7], independently.

In the final section, Section 9, we consider the negative version of the number of bounded Schröder paths and the negative moments of Laurent biorthogonal polynomials.

2 Preliminaries

In this section, we give some definitions related to negative moments of orthogonal polynomials and prove their basic properties.

We say that a sequence $ (f_n)_{n\ge 0} $ satisfies a homogeneous linear recurrence relation if there exist a positive integer $ k $ and constants $ r_1,\dots ,r_k $ with $ r_k\ne 0 $ such that for all $ n\ge k $ ,

(3) $$ \begin{align} f_n = r_1f_{n-1}+\cdots+r_k f_{n-k}. \end{align} $$

In this case, we can uniquely extend the sequence $ f_n $ to all integers $ n $ by requiring that (3) holds for all $ n\in \mathbb {Z} $ . Therefore, whenever a sequence $ (f_n)_{n\ge 0} $ satisfies a homogeneous linear recurrence relation, we can also consider the negatively indexed sequence $ (f_{-n})_{n\ge 1} $ .

It is not hard to check that the ‘negative of negative’ of a sequence is itself in the sense that if we write $ f=(f_n)_{n\ge 0} $ and $ \overline {f}=(f_{-n})_{n\ge 0} $ , then $ \overline {\overline {f}}=f $ .

The following well-known lemma is useful when we study negatively indexed sequences.

Lemma 2.1 [Reference Stanley16, Theorem 4.1.1].

A sequence $ (f_n)_{n\ge 0} $ satisfies a homogeneous linear recurrence relation if and only if

$$\begin{align*}\sum_{n\ge0} f_n x^n = \frac{P(x)}{Q(x)} \end{align*}$$

for some polynomials $ P(x) $ and $ Q(x) $ with $ \deg (P(x))<\deg (Q(x)) $ and $ Q(0)\ne 0 $ . Moreover, in this case, we have

$$\begin{align*}\sum_{n\ge1} f_{-n} x^n = -\frac{P(1/x)}{Q(1/x)}, \end{align*}$$

as rational functions.

In this paper, a lattice path is a finite sequence $ p=(p_0,p_1,\dots ,p_n) $ of points in $ \mathbb {Z}\times \mathbb {Z}_{\ge 0}$ . Each $ S_i=(x_{i}-x_{i-1}, y_{i}-y_{i-1}) $ , $ 1\le i\le n $ , is called a step of $ p $ . If the starting point $ p_0 $ is fixed, we will often identify the lattice path $ p $ with the sequence $ (S_1,S_2,\dots ,S_n) $ of its steps.

A Motzkin path is a lattice path in which every step is an up step $U=(1,1)$ , a horizontal step $H=(1,0)$ or a down step $ D=(1,-1) $ . We denote by $ \operatorname {Mot}_{n,r,s} $ the set of Motzkin paths from $ (0,r) $ to $ (n,s) $ . Let $ \operatorname {Mot}^{\le k}_{n,r,s} $ be the set of Motzkin paths in $ \operatorname {Mot}_{n,r,s} $ that lie weakly below the line $ y=k $ . We also define $ \operatorname {Mot}_{n} = \operatorname {Mot}_{n,0,0} $ and $ \operatorname {Mot}^{\le k}_{n} = \operatorname {Mot}^{\le k}_{n,0,0} $ .

Throughout this paper, we use the following notation:

$$ \begin{align*} \boldsymbol{b}&= (b_n)_{n\ge0}=(b_0,b_1,\dots), \\ \boldsymbol{\lambda}&= (\lambda_n)_{n\ge1}=(\lambda_1,\lambda_2,\dots), \\ \boldsymbol{b}^2&= (b_{n-1}b_n)_{n\ge1} = (b_0b_1,b_1b_2,\dots), \\ \boldsymbol{0}&= (0,0,\dots), \\ \boldsymbol{1}&= (1,1,\dots). \end{align*} $$

Definition 2.2. The weight $ \operatorname {wt}(\pi ;\boldsymbol {b},\boldsymbol {\lambda }) $ of a Motzkin path $ \pi $ (with respect to $ \boldsymbol {b} $ and $ \boldsymbol {\lambda } $ ) is defined to be the product of $ b_i $ for each horizontal step starting at a point with $ y $ -coordinate $ i $ and $ \lambda _i $ for each down step starting at a point with $ y $ -coordinate $ i $ . We define

$$ \begin{align*} \mu_{n,r,s}(\boldsymbol{b},\boldsymbol{\lambda}) &= \sum_{\pi\in \operatorname{Mot}_{n,r,s}} \operatorname{wt}(\pi;\boldsymbol{b},\boldsymbol{\lambda}),\\ \mu_{n,r,s}^{\le k}(\boldsymbol{b},\boldsymbol{\lambda}) &= \sum_{\pi\in \operatorname{Mot}^{\le k}_{n,r,s}} \operatorname{wt}(\pi;\boldsymbol{b},\boldsymbol{\lambda}),\\ \mu_{n}(\boldsymbol{b},\boldsymbol{\lambda}) &= \mu_{n,0,0}(\boldsymbol{b},\boldsymbol{\lambda}),\\ \mu_{n}^{\le k}(\boldsymbol{b},\boldsymbol{\lambda}) &= \mu_{n,0,0}^{\le k}(\boldsymbol{b},\boldsymbol{\lambda}). \end{align*} $$

Recall that $ P_n(x;\boldsymbol {b},\boldsymbol {\lambda }) $ , $ n\ge 0 $ , are the orthogonal polynomials defined by the three-term recurrence in (2).

Definition 2.3. The inverted polynomial of $ P_n(x;\boldsymbol {b},\boldsymbol {\lambda }) $ is defined by $ P^*_n(x;\boldsymbol {b},\boldsymbol {\lambda }) = x^n P_n(1/x;\boldsymbol {b},\boldsymbol {\lambda }) $ . We also define

$$\begin{align*}\delta P_n(x;\boldsymbol{b},\boldsymbol{\lambda}) &= P_n(x;\delta \boldsymbol{b},\delta \boldsymbol{\lambda}),\\\delta P^*_n(x;\boldsymbol{b},\boldsymbol{\lambda}) &= P^*_n(x;\delta \boldsymbol{b},\delta \boldsymbol{\lambda}), \end{align*}$$

where, for a sequence $\boldsymbol {s}=(s_n)_{n\ge 0}$ , we denote $\delta \boldsymbol {s} = (s_{n+1})_{n\ge 0}$ .

The main focus of this paper is to study the negative versions of $ \mu _{n,r,s}^{\le k}(\boldsymbol {b},\boldsymbol {\lambda }) $ .

Definition 2.4. Let $ k,r,s $ be fixed integers. If the sequence $ \mu _{n,r,s}^{\le k}(\boldsymbol {b},\boldsymbol {\lambda }) $ for $ n=0,1,\dots $ satisfies a homogeneous linear recurrence relation, then we define $ \mu _{-n,r,s}^{\le k}(\boldsymbol {b},\boldsymbol {\lambda }) $ for $ n=1,2,\dots $ in the unique way so that the sequence $ \mu _{n,r,s}^{\le k}(\boldsymbol {b},\boldsymbol {\lambda }) $ for all $ n\in \mathbb {Z} $ satisfies the recurrence. We call $ \mu _{-n}^{\le k}(\boldsymbol {b},\boldsymbol {\lambda }) := \mu _{-n,0,0}^{\le k}(\boldsymbol {b},\boldsymbol {\lambda }) $ the negative moments of the orthogonal polynomials $ P_n(x;\boldsymbol {b},\boldsymbol {\lambda }) $ .

Now we prove some basic properties of the (generalized) negative moments $ \mu _{-n,r,s}^{\le k}(\boldsymbol {b},\boldsymbol {\lambda }) $ .

Viennot [Reference Viennot18, Ch. V, (27)] found the following generating function for $ \mu _{n,r,s}^{\le k}(\boldsymbol {b},\boldsymbol {\lambda }) $ .

Lemma 2.5. Let $ r,s $ and $ k $ be integers with $ 0\le r,s\le k $ . If $r\le s$ , then

(4) $$ \begin{align} \sum_{n\ge0} \mu_{n,r,s}^{\le k}(\boldsymbol{b},\boldsymbol{\lambda}) x^n = \frac{x^{s-r}P^*_r(x;\boldsymbol{b},\boldsymbol{\lambda}) \delta^{s+1} P^*_{k-s}(x;\boldsymbol{b},\boldsymbol{\lambda})}{P^*_{k+1}(x;\boldsymbol{b},\boldsymbol{\lambda})}. \end{align} $$

If $r> s$ , then

(5) $$ \begin{align} \sum_{n\ge0} \mu_{n,r,s}^{\le k}(\boldsymbol{b},\boldsymbol{\lambda}) x^n = \frac{ P^*_s(x;\boldsymbol{b},\boldsymbol{\lambda}) \delta^{r+1} P^*_{k-r}(x;\boldsymbol{b},\boldsymbol{\lambda})}{P^*_{k+1}(x;\boldsymbol{b},\boldsymbol{\lambda})} \prod_{i=s+1}^{r} \lambda_i. \end{align} $$

By Lemmas 2.1 and 2.5, we can also find the generating function for $ \mu _{-n,r,s}^{\le k}(\boldsymbol {b},\boldsymbol {\lambda }) $ .

Proposition 2.6. Let $ r,s $ and $ k $ be integers with $ 0\le r,s\le k $ . Suppose that $ \mu _{-n,r,s}^{\le k}(\boldsymbol {b},\boldsymbol {\lambda }) $ is well-defined for $ n\ge 1 $ . If $r\le s$ , then

(6) $$ \begin{align} \sum_{n\ge1} \mu_{-n,r,s}^{\le k}(\boldsymbol{b},\boldsymbol{\lambda}) x^n = -\frac{xP_r(x;\boldsymbol{b},\boldsymbol{\lambda}) \delta^{s+1} P_{k-s}(x;\boldsymbol{b},\boldsymbol{\lambda})}{P_{k+1}(x;\boldsymbol{b},\boldsymbol{\lambda})}. \end{align} $$

If $r> s$ , then

(7) $$ \begin{align} \sum_{n\ge1} \mu_{-n,r,s}^{\le k}(\boldsymbol{b},\boldsymbol{\lambda}) x^n =- \frac{ x^{r-s+1}P_s(x;\boldsymbol{b},\boldsymbol{\lambda}) \delta^{r+1} P_{k-r}(x;\boldsymbol{b},\boldsymbol{\lambda})}{P_{k+1}(x;\boldsymbol{b},\boldsymbol{\lambda})} \prod_{i=s+1}^{r} \lambda_i. \end{align} $$

Using Flajolet’s combinatorial theory of continued fractions [Reference Flajolet5], Viennot [Reference Viennot18] showed that

(8) $$ \begin{align} \sum_{n\ge0} \mu_n^{\le k}(\boldsymbol{b},\boldsymbol{\lambda})x^n = \cfrac{1}{ 1-b_0x- \cfrac{\lambda_1x^2}{ 1-b_1x- \cfrac{\lambda_2x^2}{ 1-b_2x- \genfrac{}{}{0pt}{1}{}{\displaystyle\ddots - \cfrac{\lambda_kx^2}{1-b_kx}}} }}. \end{align} $$

There is a similar continued fraction expression for the generating function for $ \mu _{-n}^{\le k}(\boldsymbol {b},\boldsymbol {\lambda }) $ .

Proposition 2.7. If $ (\mu _{-n}^{\le k}(\boldsymbol {b},\boldsymbol {\lambda }))_{n\ge 1} $ is defined, we have

$$\begin{align*}\sum_{n\ge1} \mu_{-n}^{\le k}(\boldsymbol{b},\boldsymbol{\lambda})x^n =\cfrac{-x}{ x-b_0- \cfrac{\lambda_1}{ x-b_1- \cfrac{\lambda_2}{ x-b_2- \genfrac{}{}{0pt}{1}{}{\displaystyle\ddots - \cfrac{\lambda_k}{x-b_k}}} }}. \end{align*}$$

Proof. By Lemma 2.1 and (8),

$$\begin{align*}\sum_{n\ge1} \mu_{-n}^{\le k}(\boldsymbol{b},\boldsymbol{\lambda})x^n =\cfrac{-1}{ 1-b_0x^{-1}- \cfrac{\lambda_1x^{-2}}{ 1-b_1x^{-1}- \cfrac{\lambda_2x^{-2}}{ 1-b_2x^{-1}- \genfrac{}{}{0pt}{1}{}{\displaystyle\ddots - \cfrac{\lambda_kx^{-2}}{1-b_kx^{-1}}}} }}. \end{align*}$$

Multiplying $ x $ to the numerator and the denominator for each fraction, we obtain the desired formula.

For the rest of this paper, we mainly consider the bounded moments $ \mu _{n,r,s}^{\le k}(\boldsymbol {b},\boldsymbol {\lambda }) $ and their negatives $ \mu _{-n,r,s}^{\le k}(\boldsymbol {b},\boldsymbol {\lambda }) $ when $ \boldsymbol {b}=\boldsymbol {0} $ or $ \boldsymbol {\lambda }=\boldsymbol {b}^2 $ . The choice of $ \boldsymbol {\lambda } $ satisfying $ \boldsymbol {\lambda }=\boldsymbol {b}^2 $ becomes more natural if we define the weight of a Motzkin path using ‘points’ instead of ‘steps’ as follows: the point-weight $ \operatorname {pwt}(\pi ;\boldsymbol {b}) $ of a Motzkin path $ \pi \in \operatorname {Mot}_{n,r,s} $ is defined by

$$\begin{align*}\operatorname{pwt}(\pi;\boldsymbol{b}) = \prod_{(i,j)\in \pi} b_j. \end{align*}$$

If $ \boldsymbol {\lambda }=\boldsymbol {b}^2 $ , there is a simple relation between the usual weight $ \operatorname {wt}(\pi ;\boldsymbol {b},\boldsymbol {b}^2) $ and the point-weight $ \operatorname {pwt}(\pi ;\boldsymbol {b}) $ .

Lemma 2.8. For $ \pi \in \operatorname {Mot}_{n,r,s} $ , we have

$$\begin{align*}\operatorname{wt}(\pi;\boldsymbol{b},\boldsymbol{b}^2) = \frac{b_0\cdots b_{r-1}}{b_0\cdots b_{s}}\operatorname{pwt}(\pi;\boldsymbol{b}). \end{align*}$$

Proof. We first show this for $ r=s=0 $ . Suppose $ \tau \in \operatorname {Mot}_{n,0,0} $ . Since each down step of $ \tau $ corresponds to a unique up step, we can redistribute the weight $ b_{i-1}b_i $ attached to a down step ending at height $ i-1 $ in such a way that the weight of the down step is $ b_{i-1} $ and the weight of its corresponding up step ending at height $ i $ is $ b_{i} $ . Therefore $ \operatorname {wt}(\tau ;\boldsymbol {b},\boldsymbol {b}^2) $ is equal to the product of the new weights of the steps, where the weight of each step ending at height $ i $ is given by $ b_i $ . This is equivalent to assigning the weight $ b_j $ for each lattice point $ (i,j) $ in $ \tau $ except the starting point $ (0,0) $ . Thus, $ \operatorname {wt}(\tau ;\boldsymbol {b},\boldsymbol {b}^2) = b_0^{-1}\operatorname {pwt}(\tau ;\boldsymbol {b}) $ , which shows the lemma for $ r=s=0 $ .

Now consider the general case $ \pi \in \operatorname {Mot}_{n,r,s} $ . Let $ \tau $ be the Motzkin path obtained from $ \pi $ by adding $ r $ up steps at the beginning and $ s $ down steps at the end. Then

$$\begin{align*}\operatorname{wt}(\pi;\boldsymbol{b},\boldsymbol{b}^2) =\frac{\operatorname{wt}(\tau;\boldsymbol{b})}{b_0b_1^2\cdots b_{s-1}^2 b_s},\qquad \operatorname{pwt}(\pi;\boldsymbol{b}) =\frac{\operatorname{pwt}(\tau;\boldsymbol{b})}{b_0\cdots b_{r-1} b_0 \cdots b_{s-1}}. \end{align*}$$

Since $ \tau \in \operatorname {Mot}_{n+r+s,0,0} $ , we have $ \operatorname {wt}(\tau ;\boldsymbol {b},\boldsymbol {b}^2) = b_0^{-1}\operatorname {pwt}(\tau ;\boldsymbol {b}) $ , which together with the equations above implies the desired identity.

Lemma 2.8 immediately implies the following proposition, which shows that $ \mu _{n,r,s}^{\le k}(\boldsymbol {b},\boldsymbol {b}^2) $ is a natural point-weight generating function for Motzkin paths.

Proposition 2.9. We have

$$\begin{align*}\mu_{n,r,s}^{\le k}(\boldsymbol{b},\boldsymbol{b}^2) = \frac{b_0\cdots b_{r-1}}{b_0\cdots b_{s}} \sum_{\pi\in \operatorname{Mot}^{\le k}_{n,r,s}} \operatorname{pwt}(\pi;\boldsymbol{b}). \end{align*}$$

We finish this section by giving sufficient conditions for $ \mu _{-n,r,s}^{\le k}(\boldsymbol {b},\boldsymbol {\lambda }) $ to be well-defined.

Proposition 2.10. If $ P_{k+1}(0;\boldsymbol {b},\boldsymbol {\lambda })\ne 0 $ , then $ \mu _{-n,r,s}^{\le k}(\boldsymbol {b},\boldsymbol {\lambda }) $ is well-defined for $ n\ge 1 $ .

Proof. Since $ P_{k+1}(x;\boldsymbol {b},\boldsymbol {\lambda }) $ has the nonzero constant term $ P_{k+1}(0;\boldsymbol {b},\boldsymbol {\lambda }) $ , its inverted polynomial $ P^*_{k+1}(x;\boldsymbol {b},\boldsymbol {\lambda }) $ has degree $ k+1 $ . Moreover, $ P^*_{k+1}(0;\boldsymbol {b},\boldsymbol {\lambda })=1 $ because it is the leading coefficient of the monic polynomial $ P_{k+1}(x;\boldsymbol {b},\boldsymbol {\lambda }) $ .

Now we consider the generating function for $ \mu _{n,r,s}^{\le k}(\boldsymbol {b},\boldsymbol {\lambda }) $ in Lemma 2.5. If $ r\le s $ ,

$$\begin{align*}\deg(x^{s-r}P^*_r(x;\boldsymbol{b},\boldsymbol{\lambda}) \delta^{s+1} P^*_{k-s}(x;\boldsymbol{b},\boldsymbol{\lambda})) \le k < \deg(P^*_{k+1}(x;\boldsymbol{b},\boldsymbol{\lambda})). \end{align*}$$

If $ r>s $ ,

$$\begin{align*}\deg(P^*_s(x;\boldsymbol{b},\boldsymbol{\lambda}) \delta^{r+1} P^*_{k-r}(x;\boldsymbol{b},\boldsymbol{\lambda})) \le s+k-r< k < \deg(P^*_{k+1}(x;\boldsymbol{b},\boldsymbol{\lambda})). \end{align*}$$

Therefore, by Lemma 2.1, $ \mu _{-n,r,s}^{\le k}(\boldsymbol {b},\boldsymbol {\lambda }) $ is well-defined in either case.

Proposition 2.11. The sequence $ (\mu _{-n,r,s}^{\le k}(\boldsymbol {0},\boldsymbol {\lambda }))_{n\ge 1} $ is well-defined if and only if $ k $ is odd. The sequence $ (\mu _{-n,r,s}^{\le k}(\boldsymbol {b},\boldsymbol {b}^2))_{n\ge 1} $ is well-defined if and only if $ k\not \equiv 1 \ \ \pmod 3 $ .

Proof. Substituting $ x=0 $ in (2) gives a recurrence for $ P_{n}(0;\boldsymbol {b},\boldsymbol {\lambda }) $ . Therefore, by induction, one can easily show that

$$ \begin{align*} P_{2k}(0;\boldsymbol{0},\boldsymbol{\lambda}) &= (-1)^{k} \prod_{i=1}^{k} \lambda_{2i-1},\\ P_{2k+1}(0;\boldsymbol{0},\boldsymbol{\lambda}) &= 0,\\ P_{3k}(0;\boldsymbol{b},\boldsymbol{b}^2) &= b_0\cdots b_{3k-1},\\ P_{3k+1}(0;\boldsymbol{b},\boldsymbol{b}^2) &= -b_0\cdots b_{3k},\\ P_{3k+2}(0;\boldsymbol{b},\boldsymbol{b}^2) &= 0. \end{align*} $$

Then the proof follows from Proposition 2.10.

3 Reciprocity for bounded Dyck paths

In this section, we introduce a method to compute negative moments using continued fractions. Using this method, we give a combinatorial model for $ \mu _{-n}^{\le k} (\boldsymbol {0},\boldsymbol {\lambda }) $ , which is equivalent to Cigler and Krattenthaler’s result stated in Theorem 1.1.

We begin with the following definitions.

Definition 3.1. An $ \ell $ -peak-valley sequence ( $ \ell $ -PV sequence for short) is a sequence $ (a_1,\dots ,a_n) $ of nonnegative integers such that for $ i = 1,\dots ,n $ ,

  • if $ a_i\equiv 0 \ \ \pmod \ell $ , then $ a_i $ is a valley; that is, $ a_{i-1}>a_i<a_{i+1} $ ,

  • if $ a_i\equiv -1 \ \ \pmod \ell $ , then $ a_i $ is a peak; that is, $ a_{i-1} < a_i> a_{i+1} $ ,

where we set $ a_0 = a_{n+1} = 0 $ . Let $ \operatorname {PV}^{\ell ,k}_{n} $ denote the set of all $ \ell $ -PV sequences $ (a_1,\dots ,a_n) $ with bound $ k $ (i.e., $ 0\le a_i\le k $ for all $ i=1,\dots ,n $ ).

Definition 3.2. We define the weight $ \operatorname {wt}(\pi ) $ of a sequence $ \pi = (a_1,\dots ,a_n) $ of nonnegative integers by $ \operatorname {wt}(\pi ) = V_{a_1}\cdots V_{a_n} $ , where $ V_i $ ’s are indeterminates.

For convenience, we define $ \operatorname {PV}^{\ell ,k}_{0}=\{\emptyset \} $ , where $ \emptyset $ is the empty sequence with $ \operatorname {wt}(\emptyset )=1 $ .

In this paper, we only need to consider $ \ell $ -PV sequences for $ \ell =2,3 $ . In this section, (resp. Section 4) we will show that if $ \boldsymbol {b}=\boldsymbol {0} $ (resp. $ \boldsymbol {\lambda } = \boldsymbol {b}^2 $ ), the negative moment $ \mu _{-n}^{\le k} (\boldsymbol {b},\boldsymbol {\lambda }) $ is a generating function for certain $ 2 $ -PV sequences (resp. $ 3 $ -PV sequences).

Note that a sequence is a $ 2 $ -PV sequence if and only if every even integer is a valley and every odd integer is a peak assuming a zero is padded at both ends. For example, $ (3,2,7,0,1) $ is a $ 2 $ -PV sequence because the odd integers $ 3,7,1 $ are peaks and the even integers $ 2,0 $ are valleys. Equivalently, a sequence $ (a_1,\dots ,a_n) $ is a $ 2 $ -PV sequence if and only if $ n $ is odd, $ a_1>a_2<a_3>\cdots $ , each $ a_{2i-1} $ is odd and $ a_{2i} $ is even.

Recall that $ \operatorname {Alt}_{n}^{\le k} $ is the set of all sequences $ (b_1,\dots ,b_n) $ such that $ b_1\le b_2 \ge b_3 \le \cdots $ and $ 1 \le b_i \le k $ . There is a close connection between alternating sequences and $ 2 $ -PV sequences as follows.

Proposition 3.3. The map from $ \operatorname {PV}_{2n+1}^{2,2k-1}$ to $ \operatorname {Alt}_{2n+1}^{\le k} $ defined by

$$\begin{align*}(a_1,\dots,a_{2n+1})\mapsto \left(k-\left\lfloor a_1/2 \right\rfloor,\dots,k-\left\lfloor a_{2n+1}/2 \right\rfloor \right) \end{align*}$$

is a bijection.

Proof. One can easily see that the map from $ \operatorname {Alt}_{2n+1}^{\le k} $ to $ \operatorname {PV}_{2n+1}^{2,2k-1}$ defined by $ (b_1,\dots ,b_{2n+1})\mapsto (c_1,\dots ,c_{2n+1}) $ , where $ c_{2i+1}=2(k-b_{2i+1})+1 $ and $ c_{2i}=2(k-b_{2i}) $ , is the inverse of the given map.

There is a simple continued fraction expression for the generating function for $ 2 $ -PV sequences.

Proposition 3.4. For an integer $ k\ge 1 $ , we have

$$\begin{align*}\sum_{n\ge 0}\sum_{\pi\in \operatorname{PV}^{2, 2k-1}_{2n+1}} \operatorname{wt}(\pi) x^{2n+1} = \cfrac{1}{ -V_0x- \cfrac{1}{ -V_1x- \genfrac{}{}{0pt}{1}{}{\displaystyle\ddots - \cfrac{1}{-V_{2k-1}x}} }} . \end{align*}$$

Proof. The proof is by induction on $ k $ . If $ k=1 $ , since there is only one $ 2 $ -PV sequence $ (1,0,1,\dots ,0,1) $ of length $ 2n+1 $ with bound $ 1 $ , we have

$$ \begin{align*} \sum_{n\ge 0}\sum_{\pi\in \operatorname{PV}^{2, 1}_{2n+1}} \operatorname{wt}(\pi) x^{2n+1} = \sum_{n\ge 0}V_1 x (V_1 V_0 x^2)^n = \frac{V_1 x}{1- V_1 V_0 x^2}. \end{align*} $$

Hence, it is true for $ k=1 $ .

Suppose $ k>1 $ , and let $ \overline {\operatorname {PV}}^{2, 2k-1}_{2n+1} $ be the set of sequences $ (a_1,\dots ,a_{2n+1}) $ in $ \operatorname {PV}^{2, 2k-1}_{2n+1} $ such that $ a_i \ge 2 $ for all $ i=1,\dots ,2n+1 $ . For convenience, let

$$ \begin{align*} \mathcal{A} = \bigcup_{n\ge 0} \operatorname{PV}^{2, 2k-1}_{2n+1} \quad\mbox{and}\quad \overline{\mathcal{A}} = \bigcup_{n\ge 0} \overline{\operatorname{PV}}^{2, 2k-1}_{2n+1}. \end{align*} $$

Then, by induction with indices shifted properly, it is enough to show that

(9) $$ \begin{align} \sum_{\pi \in \mathcal{A}} \operatorname{wt}(\pi) x^{|\pi|} = \frac{1}{-V_0x-\cfrac{1}{-V_1x-\sum_{\pi \in \overline{\mathcal{A}}} \operatorname{wt}(\pi) x^{|\pi|}}}, \end{align} $$

where if $ \pi =(a_1,\dots ,a_n) $ , we denote $ |\pi |=n $ .

Let $ A=(a_1,\dots ,a_{2n+1})\in \mathcal {A} $ . We divide $ A $ into subsequences using the locations of $ 0 $ ’s as follows. Let $ i_1,\dots ,i_m $ be the indices $ j $ such that $ a_j = 0 $ , where $ i_1<\dots <i_m $ . Let $ A_0=(a_1,\dots ,a_{i_1-1}) $ and $ A_j=(a_{i_j},\dots ,a_{i_{j+1}-1}) $ for $ j=1,\dots ,m $ , where $ i_{m+1}-1=2n+1 $ , so that $ A $ is the concatenation of $ A_0,A_1,\dots ,A_m $ . For example, if $ A=(3,2,7,0,1,0,5,2,3,0,7,6,7) $ , then $ A_0=(3,2,7) $ , $ A_1=(0,1) $ , $ A_2=(0,5,2,3) $ and $ A_3=(0,7,6,7) $ .

Since every even integer is a valley and every odd integer is a peak in $ A $ , one can easily check the following:

  • $ A_0 $ is either $ (1) $ or an element in $ \overline {\mathcal {A}} $ ,

  • for each $ 1\le j\le m $ , $ A_j $ is either $ (0,1) $ or $ (0,y) $ for some $ y\in \overline {\mathcal {A}} $ .

Conversely, any choice of $ A_0,A_1,\dots ,A_m $ satisfying the above conditions gives an element in $ \mathcal {A} $ . Therefore, if we set $ S = \sum _{\pi \in \overline {\mathcal {A}}} \operatorname {wt}(\pi ) x^{|\pi |} $ , then

$$ \begin{align*} \sum_{\pi \in \mathcal{A}} \operatorname{wt}(\pi) x^{|\pi|} = \sum_{m \ge 0} (V_1 x + S ) (V_0V_1 x^2 + V_0 x S)^m = \frac{V_1x+S}{1-V_0V_1x^2-V_0xS}. \end{align*} $$

Dividing the numerator and the denominator by $ V_1 x + S $ , we obtain (9), and the proof follows by induction.

We now give a combinatorial interpretation for $ \mu _{-2n}^{\le 2k-1} (\boldsymbol {0},\boldsymbol {\lambda }) $ using $ 2 $ -PV sequences.

Theorem 3.5. Suppose that the sequence $ \boldsymbol {\lambda }=(\lambda _i)_{i\ge 1} $ is given by $ \lambda _i = V_{i-1}^{-1} V_{i}^{-1} $ for $ i \ge 1 $ . Then we have

$$ \begin{align*} \mu_{-2n}^{\le 2k-1} (\boldsymbol{0},\boldsymbol{\lambda}) = V_0 \sum_{\pi\in \operatorname{PV}^{2,2k-1}_{2n-1} } \operatorname{wt}(\pi). \end{align*} $$

Proof. Let $ \lambda _0 = V_0^{-1} $ . Observe that for each integer $ m\ge 0 $ , $ \lambda _m^{-1}\lambda _{m-1}\cdots \lambda _0^{(-1)^{m+1}} = V_{m} $ . By Proposition 2.7,

$$ \begin{align*} \sum_{n\ge1} \mu_{-n}^{\le 2k-1} (\boldsymbol{0},\boldsymbol{\lambda})x^n &=\cfrac{-x}{ x- \cfrac{\lambda_1}{ x- \cfrac{\lambda_2}{ x- \genfrac{}{}{0pt}{1}{}{\displaystyle\ddots - \cfrac{\lambda_{2k-1}}{x}}} }}\\ &=\cfrac{\lambda_0^{-1} x}{ -\lambda_0^{-1} x- \cfrac{1}{ -\lambda_1^{-1}\lambda_0 x- \cfrac{1}{ -\lambda_2^{-1}\lambda_1 \lambda_0^{-1} x- \genfrac{}{}{0pt}{1}{}{\displaystyle\ddots - \cfrac{1}{-\lambda_{2k-1}^{-1}\lambda_{2k-2}\cdots \lambda_0^{(-1)^{2k}} x}}} }}\\ &=\cfrac{V_0 x}{ -V_0 x- \cfrac{1}{ -V_1 x- \genfrac{}{}{0pt}{1}{}{\displaystyle\ddots - \cfrac{1}{-V_{2k-1} x}} }}. \end{align*} $$

Then the proof follows from Proposition 3.4.

By the above theorem with $ \boldsymbol {\lambda } = \boldsymbol {1} $ , we get the following corollary.

Corollary 3.6. We have

$$ \begin{align*} \mu_{-2n}^{\le 2k-1} (\boldsymbol{0},\boldsymbol{1}) = \left|\operatorname{PV}^{2,2k-1}_{2n-1}\right|. \end{align*} $$

By Proposition 3.3, Corollary 3.6 is equivalent to Theorem 1.1 due to Cigler and Krattenthaler. Moreover, using Proposition 3.3, one can easily check that Theorem 3.5 is equivalent to the following proposition, which is a weighted version of Theorem 1.1.

Proposition 3.7 [Reference Cigler and Krattenthaler3, Corollary 32].

Suppose that $ \lambda _{2i-1} = V_i^{-1} A_i^{-1} $ and $ \lambda _{2i} = A_i^{-1} V_{i+1}^{-1} $ for all $ i \ge 1 $ , and let $ \lambda _0 = V_1^{-1} $ . Then we have

$$ \begin{align*} \mu_{-2n}^{\le 2k-1} (\boldsymbol{0},\boldsymbol{\lambda}) = V_1 R_{AV}^{(k)} \left( \sum_{\pi \in \operatorname{Alt}_{2n-1}^{\le k}} \operatorname{wt}_{AV}(\pi) \right) , \end{align*} $$

where the operator $ R_{AV}^{(k)} $ replaces $ A_i $ by $ V_{k+1-i} $ and $ V_i $ by $ A_{k+1-i} $ , and

(10) $$ \begin{align} \operatorname{wt}_{AV}(\pi) = V_{a_1}V_{a_3}\cdots V_{a_{2n-1}} A_{a_2}A_{a_4}\cdots A_{a_{2n-2}}. \end{align} $$

4 Reciprocity for bounded Motzkin paths

In this section, we find a combinatorial interpretation for $ \mu _{-n}^{\le k}(\boldsymbol {b},\boldsymbol {b}^2) $ . We only need to consider the case $ k\not \equiv 1 \ \ \pmod 3 $ because, otherwise, $ \mu _{-n}^{\le k}(\boldsymbol {b},\boldsymbol {b}^2) $ is not defined by Proposition 2.11. We show that $ \mu _{-n}^{\le 3k-1}(\boldsymbol {b},\boldsymbol {b}^2) $ is a generating function for $ 3 $ -PV sequences (Theorem 4.2) and $ \mu _{-n}^{\le 3k}(\boldsymbol {b},\boldsymbol {b}^2) $ is a generating function for modified $3$ -PV sequences (Theorem 4.5).

Recall that a sequence $ (a_1,\dots ,a_n) $ is a $ 3 $ -PV sequence if each $ a_i $ is a valley when $ a_i \equiv 0 \ \ \pmod 3 $ , and $ a_i $ is a peak when $ a_i \equiv 2 \ \ \pmod 3 $ .

Using arguments similar to those in the previous section, we find a continued fraction expression for the generating function for $ 3 $ -PV sequences.

Proposition 4.1. For an integer $ k\ge 1 $ , we have

$$\begin{align*}\sum_{n\ge 1}\sum_{\pi\in \operatorname{PV}^{3, 3k-1}_{n}} \operatorname{wt}(\pi) x^{n}= \cfrac{1}{ -V_0x-1- \cfrac{1}{ -V_1x-1- \genfrac{}{}{0pt}{1}{}{\displaystyle\ddots - \cfrac{1}{-V_{3k-1}x-1}} }}. \end{align*}$$

Proof. The proof is similar to (but slightly more complicated than) that of Proposition 3.4. Let $ \overline {\operatorname {PV}}^{3, 3k-1}_{n} $ be the set of sequences $ (a_1,\dots ,a_{n}) $ in $ \operatorname {PV}^{3, 3k-1}_{n} $ such that $ a_i \ge 3 $ for all $ i=1,\dots ,n $ , and let

$$ \begin{align*} \mathcal{A} = \bigcup_{n\ge 0} \operatorname{PV}^{3, 3k-1}_{n} \quad\mbox{and}\quad \overline{\mathcal{A}} = \bigcup_{n\ge 0} \overline{\operatorname{PV}}^{3, 3k-1}_{n}. \end{align*} $$

We first claim that

(11) $$ \begin{align} \sum_{\pi\in \mathcal{A}}\operatorname{wt}(\pi)x^{|\pi|} =\cfrac{1}{-V_0x-1-\cfrac{1}{-V_1x-1-\cfrac{1}{-V_2x-1-\sum_{\pi\in \overline{\mathcal{A}}}\operatorname{wt}(\pi)x^{|\pi|}}}}. \end{align} $$

It is easy to see that the proposition follows from the claim by induction on $ k $ . Therefore, it suffices to prove the claim (11).

For a sequence $ \pi =(a_1,\dots ,a_n)\in \mathcal {A} $ , let $ i_1,\dots ,i_m $ be the indices $ j $ such that $ a_j = 0 $ or $ a_{j-1}\ge a_j=1 $ , where $ i_1<\dots <i_m $ . Let $ A_0=(a_1,\dots ,a_{i_1-1}) $ and $ A_j=(a_{i_j},\dots ,a_{i_{j+1}-1}) $ for $ j=1,\dots ,m $ , where $ i_{m+1}-1=n $ , so that $ \pi $ is the concatenation of $ A_0,A_1,\dots ,A_m $ .

Observe that the possible sequences for $ A_0 $ are $ (1),(1,2),(2),(1,y) $ and $ (y) $ where $ y \in \overline {\mathcal {A}} $ . For $ 1\le j\le m $ , the first entry of $ A_j $ is $ 0 $ or $ 1 $ . If the first entry is $ 0 $ , the possible sequences for $ A_j $ are $ (0,1),(0,1,2),(0,2),(0,1,y), (0,y) $ , where $ y \in \overline {\mathcal {A}} $ , and if the first entry is $ 1 $ , the possible sequences for $ A_j $ are $ (1),(1,2), (1,y) $ where $ y \in \overline {\mathcal {A}} $ . Hence, if we set $ S =\sum _{\pi \in \overline {\mathcal {A}}}\operatorname {wt}(\pi )x^{|\pi |} $ , then we have

$$ \begin{align*} \sum_{\pi \in \mathcal{A}} \operatorname{wt}(\pi) x^{|\pi|} &= \sum_{m \ge 0} (V_1x+V_1V_2x^2+V_2x+V_1x S+S ) \\ &\qquad\qquad\qquad \times(V_0x(V_1x+V_1V_2x^2+V_2x+V_1x S+S)+V_1x(1+V_2x+S))^m\\ &= \frac{V_1x+V_1V_2x^2+V_2x+V_1x S+S} {1-V_0x(V_1x+V_1V_2x^2+V_2x+V_1x S+S)-V_1x(1+V_2x+S)}, \end{align*} $$

which is easily seen to be equal to the right-hand side of (11). This completes the proof.

Using Proposition 4.1, we can find a combinatorial interpretation for $ \mu _{-n}^{\le 3k-1}(\boldsymbol {b},\boldsymbol {b}^2) $ .

Theorem 4.2. Let $ \boldsymbol {b}=(b_i)_{i\ge 0} $ and $ \boldsymbol {\lambda }=(\lambda _i)_{i\ge 1} $ be the sequences given by $ b_i=-V_i^{-1} $ and $ \lambda _{i}=V_{i}^{-1}V_{i-1}^{-1} $ for all $ i $ . Then we have

$$ \begin{align*} \mu_{-n}^{\le 3k-1}(\boldsymbol{b},\boldsymbol{\lambda}) = V_0 \sum_{\pi\in \operatorname{PV}^{3, 3k-1}_{n-1}} \operatorname{wt}(\pi). \end{align*} $$

Proof. By Proposition 2.7, we have

$$ \begin{align*} \sum_{n\ge1} \mu_{-n}^{\le k} (\boldsymbol{b},\boldsymbol{\lambda})x^n &=\cfrac{-x}{ x-b_0- \cfrac{\lambda_1}{ x-b_1- \cfrac{\lambda_2}{ x-b_2- \genfrac{}{}{0pt}{1}{}{\displaystyle\ddots - \cfrac{\lambda_k}{x-b_k}}} }}\\ &=\cfrac{b_0^{-1} x}{ 1-b_0^{-1}x- \cfrac{b_0^{-1}b_1^{-1}\lambda_1}{ 1-b_1^{-1}x- \cfrac{b_1^{-1}b_2^{-1}\lambda_2}{ 1-b_2^{-1}x- \genfrac{}{}{0pt}{1}{}{\displaystyle\ddots - \cfrac{b_{k-1}^{-1}b_k^{-1}\lambda_k}{1-b_k^{-1}x}}} }}\\ &=\cfrac{V_0 x}{ -V_0 x - 1- \cfrac{1}{ -V_1x - 1 - \cfrac{1}{ -V_2x - 1 - \genfrac{}{}{0pt}{1}{}{\displaystyle\ddots - \cfrac{1}{-V_k x - 1}}} }}. \end{align*} $$

The proof follows from Proposition 4.1.

Now we find a combinatorial interpretation for $ \mu _{-n}^{\le 3k}(\boldsymbol {b},\boldsymbol {b}^2) $ . To this end, we need the following definition.

Definition 4.3. A modified $3$ -PV sequence is a sequence $ (a_1,\dots ,a_n) $ of nonnegative integers such that for $ i =1,\dots ,n $ ,

  • if $ a_i\equiv 1 \ \ \pmod 3$ , then $ a_i $ is a valley; that is, $ a_{i-1}>a_i<a_{i+1} $ ,

  • if $ a_i\equiv 2 \ \ \pmod 3$ , then $ a_i $ is a peak; that is, $ a_{i-1} < a_i> a_{i+1} $ ,

where we set $ a_0 = a_{n+1} = 0 $ . Let $ \widetilde {\operatorname {PV}}^{3,k}_{n} $ denote the set of all modified $ 3 $ -PV sequences of length $ n $ with bound $ k $ (i.e., $ 0\le a_i\le k $ for all $ i $ ).

Similar to Proposition 4.1, there is a continued fraction expression for the generating function for $ \widetilde {\operatorname {PV}}_n^{3,3k} $ (see the proposition below). We note, however, that the proof of Proposition 4.4 is different from that of Proposition 4.1 due to the fact that in Proposition 4.4, the sum is over $ n\ge 0 $ whereas in Proposition 4.1 the sum is over $ n\ge 1 $ .

Proposition 4.4. For an integer $ k\ge 1 $ , we have

$$\begin{align*}\sum_{n\ge 0} (-1)^{n+1}\sum_{\pi \in \widetilde{\operatorname{PV}}_n^{3,3k}} \operatorname{wt}(\pi) x^{n} = \cfrac{1}{ -V_0x-1- \cfrac{1}{ -V_1x-1- \genfrac{}{}{0pt}{1}{}{\displaystyle\ddots - \cfrac{1}{-V_{3k}x-1}} }}. \end{align*}$$

Proof. Let $ \mathcal {A}=\cup _{n\ge 0}\widetilde {\operatorname {PV}}_n^{3,3k} $ , and let $ \mathcal {B} $ be the set of sequences $ \beta =(b_1,\dots ,b_m) $ for $ m\ge 0 $ such that $ b_i $ is a valley if $ b_i \equiv 1 \ \ \pmod 3 $ , $ b_i $ is a peak if $ b_i \equiv 0 \ \ \pmod 3 $ and $ 1\le b_i \le 3k $ for all $ i $ , where we set $ b_0 = b_{m+1} = 0 $ . Here $ (b_1,\dots ,b_m)$ means the empty sequence $\emptyset $ if $ m=0 $ . By Proposition 4.1, we have

$$ \begin{align*}\sum_{\beta\in \mathcal{B}} \operatorname{wt}(\beta) x^{|\beta|} = 1 + \cfrac{1}{ -V_1x-1- \cfrac{1}{ -V_2x-1- \genfrac{}{}{0pt}{1}{}{\displaystyle\ddots - \cfrac{1}{-V_{3k}x-1}}} }. \end{align*} $$

We claim that

(12) $$ \begin{align} \sum_{\alpha\in \mathcal{A}}\operatorname{wt}(\alpha)(-x)^{|\alpha|} \left( V_0 x + \sum_{\beta\in \mathcal{B}}\operatorname{wt}(\beta)x^{|\beta|} \right) = 1. \end{align} $$

For $ \alpha \in \mathcal {A} $ and $ \beta \in \mathcal {B}\cup \{(0)\} $ , define the weight $ \overline {\operatorname {wt}}(\alpha ,\beta ) $ of the pair $ (\alpha ,\beta ) $ to be $ (-1)^{|\alpha |}\operatorname {wt}(\alpha )\operatorname {wt}(\beta ) $ . To prove the claim, it suffices to find a sign-reversing involution $ \varphi $ from $ \mathcal {A}\times (\mathcal {B}\cup \{(0)\}) $ to itself with unique fixed point $ (\emptyset ,\emptyset ) $ , where $ \emptyset $ is the empty sequence.

For a nonempty sequence $ \alpha = (a_1,\dots ,a_m)\in \mathcal {A} $ , define $ I(\alpha )$ to be the largest integer $ i $ such that $ 1\le i\le m-1 $ and $ a_i, a_{i+1} \not \equiv 1 \ \ \pmod 3$ . If there is no such $ i $ , we define $ I(\alpha )=0 $ . Similarly, for a nonempty sequence $ \beta = (b_1,\dots ,b_n)\in \mathcal {B}\cup \{(0)\} $ , define $ J(\beta ) $ to be the smallest integer $ j $ such that $ 1\le j\le n-1 $ and $ b_j,b_{j+1}\not \equiv 1 \ \ \pmod 3 $ . If there is no such $ j $ , we define $ J(\beta )=n $ . One can check that $ m-I(\alpha ) $ and $ J(\beta ) $ are odd. Moreover, $ a_{I(\alpha )+1}>a_{I(\alpha )+2}<\dots <a_m $ and $ b_1>b_2<\dots <b_{J(\beta )} $ .

We define the map $ \varphi $ as follows. For $ \alpha = (a_1,\dots ,a_m) \in \mathcal {A} $ and $ \beta = (b_1,\dots ,b_n)\in \mathcal {B}\cup \{(0)\} $ ,

  1. 1. define $ \varphi (\alpha ,\beta ) = ((a_1,\dots ,a_m,b_1,\dots ,b_{J(\beta )}),(b_{J(\beta )+1},\dots ,b_n)) $ if one of the following conditions is satisfied:

    $$\begin{align*}\begin{cases} m=0, \\ a_m \equiv 0 \quad \pmod 3 \quad\mbox{and}\quad b_1 \equiv 0 \quad \pmod 3, \\ a_m\equiv 2\quad \pmod 3 \quad\mbox{and}\quad b_1 \equiv 0\quad \pmod 3 \mbox{ with } a_m>b_1,\\ a_m\equiv 0\quad \pmod 3 \quad\mbox{and}\quad b_1 \equiv 2\quad \pmod 3 \mbox{ with } a_m<b_1, \end{cases}\end{align*}$$
  2. 2. define $ \varphi (\alpha ,\beta ) = ((a_1,\dots ,a_{I(\alpha )}),(a_{I(\alpha )+1},\dots ,a_m ,b_1,\dots ,b_n)) $ if one of the following conditions is satisfied:

    $$\begin{align*}\begin{cases} n=0,\\ a_m \equiv 2 \quad \pmod 3 \quad\mbox{and}\quad b_1 \equiv 2 \quad \pmod 3, \\ a_m\equiv 2\quad \pmod 3 \quad\mbox{and}\quad b_1 \equiv 0\quad \pmod 3 \mbox{ with } a_m<b_1, \\ a_m\equiv 0\quad \pmod 3 \quad\mbox{and}\quad b_1 \equiv 2\quad \pmod 3 \mbox{ with } a_m>b_1. \end{cases}\end{align*}$$

Then it is not hard to see that the map $ \varphi $ is a sign-reversing involution with unique fixed point $ (\emptyset ,\emptyset ) $ , which proves the claim. For example, let $ \alpha = (a_1,a_2,a_3,a_4,a_5)= (2,0,3,1,5)\in \mathcal {A} $ and $ \beta = (b_1,b_2,b_3,b_4) = (2,3,1,2)\in \mathcal {B} $ . Then $ I(\alpha ) = 2 $ since $ a_2,a_3\not \equiv 1 \ \ \pmod 3 $ , and $ J(\beta )=1 $ since $ b_1,b_2\not \equiv 1 \ \ \pmod 3 $ . Since $ a_5\equiv 2\ \ \pmod 3 $ and $ b_1 \equiv 2 \ \ \pmod 3 $ , it satisfies the second condition of the case (2), so $ \varphi (\alpha ,\beta ) = ((2,0),(3,1,5,2,3,1,2)) $ . Moreover, one can easily check that $ \varphi ((2,0),(3,1,5,2,3,1,2)) = ((2,0,3,1,5),(2,3,1,2)) = (\alpha ,\beta ) $ .

By the claim (12), we have

$$ \begin{align*} -\sum_{\alpha\in \mathcal{A}}\operatorname{wt}(\alpha)(-x)^{|\alpha|} &= \frac{1}{-V_0 x - \sum_{\beta\in \mathcal{B}}\operatorname{wt}(\beta)x^{|\beta|}} \\ &= \cfrac{1}{ -V_0x-1- \cfrac{1}{ -V_1x-1- \genfrac{}{}{0pt}{1}{}{\displaystyle\ddots - \cfrac{1}{-V_{3k}x-1}}} }, \end{align*} $$

which completes the proof.

Similar to Theorem 4.2, using Proposition 4.4, we can find a combinatorial interpretation for $ \mu _{-n}^{\le 3k}(\boldsymbol {b},\boldsymbol {b}^2) $ . We omit the proof.

Theorem 4.5. Let $ \boldsymbol {b}=(b_i)_{i\ge 0} $ and $ \boldsymbol {\lambda }=(\lambda _i)_{i\ge 1} $ be the sequences given by $ b_i=-V_i^{-1} $ and $ \lambda _{i}=V_{i}^{-1}V_{i-1}^{-1} $ for all $ i $ . Then we have

$$ \begin{align*} \mu_{-n}^{\le 3k}(\boldsymbol{b},\boldsymbol{\lambda}) = V_0 \sum_{\pi \in \widetilde{\operatorname{PV}}_{n-1}^{3,3k}} \operatorname{wt}(\pi). \end{align*} $$

5 Negative moments using inverse matrices

In this section, we generalize Theorems 4.2 and 4.5 using inverse matrices.

For integers $ k $ and $ i $ with $ 0\le i\le k $ , let $ \epsilon ^{\le k}_i $ be the standard basis vector in $ \mathbb {R}^{k+1} $ such that the $ i $ th entry is equal to $ 1 $ and the other entries are all $ 0 $ . If the size of $ \epsilon _i^{\le k} $ is clear from the context, we will simply write it as $ \epsilon _i $ . We also define the tridiagonal matrix $ A^{\le k}(\boldsymbol {b},\boldsymbol {\lambda }) $ by

(13) $$ \begin{align} A^{\le k}(\boldsymbol{b},\boldsymbol{\lambda}) = \begin{pmatrix} b_0 & 1 & & & \\ \lambda_1 & b_1 & 1& & \\ & &\ddots& & \\ & & \lambda_{k-1}& b_{k-1}& 1 \\ && & \lambda_k& b_k \\ \end{pmatrix}. \end{align} $$

By the definition of $ \mu _{n,r,s}^{\le k}(\boldsymbol {b},\boldsymbol {\lambda }) $ , it is easy to see that

(14) $$ \begin{align} \mu_{n,r,s}^{\le k}(\boldsymbol{b},\boldsymbol{\lambda}) = \epsilon_r^T \left( A^{\le k}(\boldsymbol{b},\boldsymbol{\lambda}) \right)^n \epsilon_s. \end{align} $$

The next proposition shows that $ \mu _{-n,r,s}^{\le k}(\boldsymbol {b},\boldsymbol {\lambda }) $ can be computed similarly using the inverse of $ A^{\le k}(\boldsymbol {b},\boldsymbol {\lambda }) $ . This is essentially the same as [Reference Hopkins and Zaimi8, Lemma 2.7] due to Hopkins and Zaimi, which was first presented in [Reference Zaimi20].

Proposition 5.1 [Reference Hopkins and Zaimi8, Lemma 2.7].

For nonnegative integers $ r,s,k,n $ with $ r,s\le k $ and $ n\ge 1 $ , if $ A^{\le k}(\boldsymbol {b},\boldsymbol {\lambda }) $ is invertible, then

(15) $$ \begin{align} \mu_{-n,r,s}^{\le k}(\boldsymbol{b},\boldsymbol{\lambda}) = \epsilon_r^T \left( A^{\le k}(\boldsymbol{b},\boldsymbol{\lambda}) \right)^{-n} \epsilon_s. \end{align} $$

Proof. Let $ x^m + c_{m-1}x^{m-1}+\dots +c_0 $ be the minimal polynomial of $ A^{\le k}(\boldsymbol {b},\boldsymbol {\lambda }) $ so that

$$\begin{align*}(A^{\le k}(\boldsymbol{b},\boldsymbol{\lambda}))^m + c_{m-1}(A^{\le k}(\boldsymbol{b},\boldsymbol{\lambda}))^{m-1}+\dots+c_0I =O, \end{align*}$$

where $ I $ (resp. $ O $ ) is the identity matrix (resp. zero matrix). For each $ N\in \mathbb {Z} $ , multiplying $ (A^{\le k}(\boldsymbol {b},\boldsymbol {\lambda }))^{N-m} $ and then multiplying $ \epsilon _r^T $ and $ \epsilon _s $ on the left and right, respectively, in the above equation, we obtain

$$\begin{align*}\epsilon_r^T(A^{\le k}(\boldsymbol{b},\boldsymbol{\lambda}))^N\epsilon_s + c_{m-1}\epsilon_r^T(A^{\le k}(\boldsymbol{b},\boldsymbol{\lambda}))^{N-1}\epsilon_s+\dots+c_0\epsilon_r^T(A^{\le k}(\boldsymbol{b},\boldsymbol{\lambda}))^{N-m} \epsilon_s=0. \end{align*}$$

Therefore, $ (\epsilon _r^T(A^{\le k}(\boldsymbol {b},\boldsymbol {\lambda }))^N\epsilon _s)_{N\in \mathbb {Z}} $ is the sequence that is extended from $ (\mu _{N,r,s}^{\le k}(\boldsymbol {b},\boldsymbol {\lambda }))_{N\ge 0} = (\epsilon _r^T(A^{\le k}(\boldsymbol {b},\boldsymbol {\lambda }))^N\epsilon _s)_{N\ge 0} $ by the above linear recurrence relation, which implies (15).

Usmani [Reference Usmani17] found a formula for the inverse of a general tridiagonal matrix. Specializing Usmani’s result to the tridiagonal matrix $ A^{\le k}(\boldsymbol {b},\boldsymbol {\lambda }) $ , we obtain the following lemma.

Lemma 5.2. Suppose that $ A^{\le k}(\boldsymbol {b},\boldsymbol {\lambda }) $ is invertible and let $ \left ( A^{\le k}(\boldsymbol {b},\boldsymbol {\lambda }) \right )^{-1} = (\alpha _{i,j})_{0\le i,j\le k} $ . Then

(16) $$ \begin{align} \alpha_{i,j}=\begin{cases} (-1)^{i+j}\theta_{i}\phi_{j+2}/\theta_{k+1} & \mbox{if } i\le j,\\ (-1)^{i+j}\lambda_j\cdots\lambda_{i-1}\theta_{j}\phi_{i+2}/\theta_{k+1} & \mbox{if } i>j , \end{cases} \end{align} $$

where $ \theta _i $ and $ \phi _i $ are defined by

$$ \begin{align*} \theta_i&=b_{i-1}\theta_{i-1}-\lambda_{i-1}\theta_{i-2},&i&=1,2,\dots,k+1,\\ \phi_i&=b_{i-1}\phi_{i+1}-\lambda_i\phi_{i+2},&i&=k+1,k,\dots,1, \end{align*} $$

with initial conditions $ \phi _{k+2}=\theta _0=1$ and $\phi _{k+3}=\theta _{-1}=0 $ .

The next lemma shows that if $ \boldsymbol {\lambda }=\boldsymbol {b}^2 $ , then there is a simple explicit formula for $ \alpha _{i,j} $ in Lemma 5.2.

Lemma 5.3. Let $ \boldsymbol {b}=(b_i)_{i\ge 0} $ and $ \boldsymbol {\lambda }=(\lambda _i)_{i\ge 1} $ be the sequences given by $ b_i=-V_i^{-1} $ and $ \lambda _{i}=V_{i}^{-1}V_{i-1}^{-1} $ for all $ i $ . Suppose that $ A^{\le k}(\boldsymbol {b},\boldsymbol {\lambda }) $ is invertible and let $ \left ( A^{\le k}(\boldsymbol {b},\boldsymbol {\lambda }) \right )^{-1} = (\alpha _{i,j})_{0\le i,j\le k} $ . Then

$$ \begin{align*} \alpha_{i,j}=(-1)^{\left\lfloor \frac{i}{3}\right\rfloor+\left\lfloor \frac{j}{3}\right\rfloor}\frac{V_0\cdots V_j}{V_0\cdots V_{i-1}}\chi_{i,j}, \end{align*} $$

where for $ k\equiv -1\ \ \pmod 3 $ ,

$$\begin{align*}\chi_{i,j}=\begin{cases} 0 & \text{ if } \quad i\equiv-1\quad \pmod3 \text{ and } i\le j,\\ 0 & \text{ if } \quad j\equiv0\quad \pmod3 \text{ and } i\le j,\\ 0 & \text{ if } \quad i\equiv0\quad \pmod3 \text{ and } i>j,\\ 0 & \text{ if } \quad j\equiv-1\quad \pmod3 \text{ and } i>j,\\ 1 & \text{ otherwise,} \end{cases} \end{align*}$$

and for $ k\equiv 0\ \ \pmod 3 $ ,

$$\begin{align*}\chi_{i,j}=\begin{cases} 0 & \text{ if } \quad i\equiv-1\quad \pmod3 \text{ and } i\le j,\\ 0 & \text{ if } \quad j\equiv1\quad \pmod3 \text{ and } i\le j,\\ 0 & \text{ if } \quad i\equiv1\quad \pmod3 \text{ and } i>j,\\ 0 & \text{ if } \quad j\equiv-1\quad \pmod3 \text{ and } i>j,\\ 1 & \text{ otherwise.} \end{cases} \end{align*}$$

Proof. By induction on $ i $ , one can easily verify that the $ \theta _i $ ’s and $ \phi _i $ ’s in Lemma 5.2 are given by

$$ \begin{align*} \theta_{3i}&=V_0^{-1}\cdots V_{3i-1}^{-1},& \phi_{k+1-3i}&=-V_{k}^{-1}\cdots V_{k-3i}^{-1},\\ \theta_{3i+1}&=-V_0^{-1}\cdots V_{3i}^{-1},&\phi_{k+2-3i}&=V_{k}^{-1}\cdots V_{k+1-3i}^{-1},\\ \theta_{3i+2}&=0,&\phi_{k+3-3i}&=0. \end{align*} $$

If $ k\equiv -1\ \ \pmod 3 $ , then these can be written as

$$ \begin{align*} \theta_i&=\begin{cases} 0 & \mbox{ if } i\equiv-1\quad \pmod 3 ,\\ (-1)^{i-3\left\lfloor \frac{i}{3}\right\rfloor} V_{0}^{-1}\cdots V_{i-1}^{-1} & \mbox{ otherwise,} \end{cases}\\ \phi_i&=\begin{cases} 0 & \mbox{ if } i\equiv-1\quad \pmod 3 ,\\ (-1)^{i-3\left\lfloor \frac{i}{3}\right\rfloor+1} V_{i-1}^{-1}\cdots V_{k}^{-1} & \mbox{ otherwise.} \end{cases} \end{align*} $$

Substituting the formulas for $ \phi _i $ and $ \theta _i $ to (16) completes the proof for $ k\equiv -1\ \ \pmod 3 $ . One can obtain the result for $ k\equiv 0\ \ \pmod 3 $ in the same way.

Note that if $ k\equiv 1\ \ \pmod 3 $ , then $ \alpha _{i,j} $ in (16) is not defined (i.e., $ A^{\le k}(\boldsymbol {b},\boldsymbol {\lambda }) $ is not invertible). Using Proposition 5.1 and Lemma 5.2, we can give a combinatorial interpretation for $ \mu _{-n,r,s}^{\le k}(\boldsymbol {b},\boldsymbol {b}^2) $ . To do this, we first need to define $ (\ell ,r,s) $ -peak-valley sequences, which are a generalization of $ \ell $ -peak-valley sequences in Definition 3.1.

Definition 5.4. An $ (\ell ,r,s)$ -peak-valley sequence is a sequence $ ( a_1,\dots ,a_{n}) $ of nonnegative integers such that for $ i=0,\dots ,n+1 $ ,

  • if $ a_i\equiv 0\ \ \pmod \ell $ , then $ a_i $ is a valley; that is, $ a_{i-1}>a_i<a_{i+1} $ ,

  • if $ a_i\equiv -1\ \ \pmod \ell $ , then $ a_i $ is a peak; that is, $ a_{i-1}<a_i>a_{i+1} $ ,

where we set $ a_0=r $ and $ a_{n+1} = s $ . Here, we ignore the inequalities involving $ a_t $ for $ t=-1 $ or $ t=n+2 $ . Denote by $ \operatorname {PV}_{n,r,s}^{\ell ,k} $ the set of $ (\ell ,r,s) $ -peak-valley sequences $ ( a_1,\dots ,a_{n}) $ with bound $ k $ , i.e., $ 0\le a_i\le k $ for all $ i=1,\dots ,n $ .

Note that Definition 5.4 reduces to Definition 3.1 when $ r=s=0 $ . Cigler and Krattenthaler [Reference Cigler and Krattenthaler3, Theorem 28] found a combinatorial description of $ \mu _{-n,r,s}^{\le 2k-1}(\boldsymbol {0},\boldsymbol {\lambda }) $ . The next theorem gives a combinatorial interpretation for $ \mu _{-n,r,s}^{\le 3k-1}(\boldsymbol {b},\boldsymbol {\lambda }) $ when $ b_i=-V_i^{-1} $ and $ \lambda _{i}=V_{i}^{-1}V_{i-1}^{-1} $ for all $ i $ . Note that this theorem reduces to Theorem 4.2 if $ r=s=0 $ .

Theorem 5.5. Suppose that $ \boldsymbol {b}=(b_i)_{i\ge 0} $ and $ \boldsymbol {\lambda }=(\lambda _i)_{i\ge 1} $ are the sequences given by $ b_i=-V_i^{-1} $ and $ \lambda _{i}=V_{i}^{-1}V_{i-1}^{-1} $ for all $ i $ . Then

$$\begin{align*}\mu_{-n,r,s}^{\le 3k-1}(\boldsymbol{b},\boldsymbol{\lambda}) = (-1)^{\left\lfloor {r}/{3}\right\rfloor+\left\lfloor {s}/{3}\right\rfloor} \frac{V_0\cdots V_s}{V_0\cdots V_{r-1}}\sum_{\pi\in\operatorname{PV}_{n-1,r,s}^{3,3k-1}}\operatorname{wt}(\pi). \end{align*}$$

Here, we set $ V_0\cdots V_{r-1}=1 $ if $ r=0 $ .

Proof. Let $ a_0=r $ , $ a_n=s $ and $ (\alpha _{i,j})_{0\le i,j\le 3k-1}=\left (A^{\le 3k-1}(\boldsymbol {b},\boldsymbol {\lambda })\right )^{-1} $ . By Proposition 5.1,

(17) $$ \begin{align} \mu_{-n,r,s}^{\le 3k-1}(\boldsymbol{b},\boldsymbol{\lambda})=\epsilon_r^T\left(A^{\le 3k-1}(\boldsymbol{b},\boldsymbol{\lambda})\right)^{-n}\epsilon_s=\sum_{(a_1,\dots,a_{n-1})\in X}\prod_{i=0}^{n-1} \alpha_{a_i,a_{i+1}}, \end{align} $$

where $ X $ is the set of sequences $ (a_1,\dots ,a_{n-1}) $ of integers with $0\le a_i \le 3k-1 $ for all $ i $ .

For $ (a_1,\dots ,a_{n-1})\in X $ , we claim that $ \prod _{i=0}^{n-1}\alpha _{a_i,a_{i+1}}=0 $ unless $ (a_1,\dots ,a_{n-1})\in \operatorname {PV}_{n-1,r,s}^{3,3k-1} $ . To see this, suppose $ (a_1,\dots ,a_{n-1})\not \in \operatorname {PV}_{n-1,r,s}^{3,3k-1} $ . Then there is an integer $ 0\le j\le n $ satisfying one of the following two conditions:

  • $ a_{j}\equiv 0\ \ \pmod 3 $ and $ a_{j} $ is not a valley,

  • $ a_{j}\equiv -1\ \ \pmod 3 $ and $ a_{j} $ is a not peak.

First, suppose $ a_{j}\equiv 0\ \ \pmod 3 $ and $ a_{j} $ is not a valley. Then $ a_{j-1}\le a_{j} $ or $ a_{j}\ge a_{j+1} $ . By Lemma 5.3, $ a_{j-1}\le a_{j} $ implies $\alpha _{a_{j-1},a_{j}}=0 $ and each of $ a_{j}= a_{j+1} $ and $ a_{j}>a_{j+1} $ implies $\alpha _{a_{j},a_{j+1}}=0 $ . Hence, we always have $ \prod _{i=0}^{n-1} \alpha _{a_i,a_{i+1}}=0 $ . Similarly, one can prove $ \prod _{i=0}^{n-1} \alpha _{a_i,a_{i+1}}=0 $ in the second case that $ a_{j}\equiv -1\ \ \pmod 3 $ and $ a_{j} $ is not a peak for some integer $ j $ .

By (17) and the claim, we have

(18) $$ \begin{align} \mu_{-n,r,s}^{\le 3k-1}(\boldsymbol{b},\boldsymbol{\lambda})=\sum_{(a_1,\dots,a_{n-1})\in\operatorname{PV}_{n-1,r,s}^{3,3k-1}} \prod_{i=0}^{n-1} \alpha_{a_i,a_{i+1}}. \end{align} $$

By Lemma 5.3, for $ \pi =(a_1,\dots ,a_{n-1})\in \operatorname {PV}_{n-1,r,s}^{3,3k-1} $ , we have

$$ \begin{align*} \prod_{i=0}^{n-1} \alpha_{a_i,a_{i+1}}&=(-1)^{\left\lfloor \frac{a_0}{3}\right\rfloor+2\left\lfloor \frac{a_1}{3}\right\rfloor+\cdots+2\left\lfloor \frac{a_{n-1}}{3}\right\rfloor+\left\lfloor \frac{a_n}{3}\right\rfloor}\prod_{i=0}^{n-1}\frac{V_0\cdots V_{a_{i+1}}}{V_0\cdots V_{a_i}}V_{a_i}\\ &=(-1)^{\left\lfloor \frac{r}{3}\right\rfloor+\left\lfloor \frac{s}{3}\right\rfloor}\frac{V_0\cdots V_s}{V_0\cdots V_{r-1}}V_{a_1}\cdots V_{a_{n-1}}, \end{align*} $$

which together with (18) gives the theorem.

Putting $ V_i=-1 $ in Theorem 5.5 gives the following corollary.

Corollary 5.6. We have

$$\begin{align*}\mu_{-n,r,s}^{\le 3k-1}(\boldsymbol{1},\boldsymbol{1})=(-1)^{\left\lfloor {r}/{3}\right\rfloor+\left\lfloor {s}/{3}\right\rfloor+r+s+n}\left|\operatorname{PV}_{n-1,r,s}^{3,3k-1}\right|. \end{align*}$$

Similarly, we can find a combinatorial interpretation for $ \mu _{-n,r,s}^{\le 3k}(\boldsymbol {b},\boldsymbol {\lambda }) $ . To do this, we introduce modified peak-valley sequences.

Definition 5.7. A modified $(\ell ,r,s)$ -peak-valley sequence is a sequence $ ( a_1,\dots ,a_{n}) $ of nonnegative integers such that for $ i=0,\dots ,n+1 $ ,

  • if $ a_i\equiv 1\ \ \pmod \ell $ , then $ a_i $ is a valley; that is, $ a_{i-1}>a_i<a_{i+1} $ ,

  • if $ a_i\equiv -1\ \ \pmod \ell $ , then $ a_i $ is a peak; that is, $ a_{i-1}<a_i>a_{i+1} $ ,

where we set $ a_0=r $ and $ a_{n+1} = s $ . Here, we ignore the inequalities involving $ a_t $ for $ t=-1 $ or $ t=n+2 $ . Denote by $ \widetilde {\operatorname {PV}}_{n,r,s}^{\ell ,k} $ the set of modified $ (\ell ,r,s) $ -peak-valley sequences $ ( a_1,\dots ,a_{n}) $ with bound $ k $ (i.e., $ 0\le a_i\le k $ for all $ i=0,\dots ,n+1 $ ).

Theorem 5.8. Suppose that $ \boldsymbol {b}=(b_i)_{i\ge 0} $ and $ \boldsymbol {\lambda }=(\lambda _i)_{i\ge 1} $ are the sequences given by $ b_i=-V_i^{-1} $ and $ \lambda _{i}=V_{i}^{-1}V_{i-1}^{-1} $ for all $ i $ . Then

$$\begin{align*}\mu_{-n,r,s}^{\le 3k}(\boldsymbol{b},\boldsymbol{\lambda}) =(-1)^{\left\lfloor {(r+1)}/{3}\right\rfloor+\left\lfloor {(s+1)}/{3}\right\rfloor+n}\frac{V_0\cdots V_s}{V_0\cdots V_{r-1}}\sum_{\pi\in\widetilde{\operatorname{PV}}_{n-1,r,s}^{3,3k}}\operatorname{wt}(\pi). \end{align*}$$

Proof. This can be proved by the same arguments as in the proof of Theorem 5.5. We omit the details.

Putting $ V_i=-1 $ in Theorem 5.8, we obtain the following corollary.

Corollary 5.9. We have

$$\begin{align*}\mu_{-n,r,s}^{\le 3k}(\boldsymbol{1},\boldsymbol{1})=(-1)^{\left\lfloor {(r+1)}/{3}\right\rfloor+\left\lfloor {(s+1)}/{3}\right\rfloor+r+s}\left|\widetilde{\operatorname{PV}}_{n-1,r,s}^{3,3k}\right|. \end{align*}$$

6 A general reciprocity theorem

In this section, we prove a general reciprocity theorem, Theorem 6.1. Using this theorem, we will prove the Cigler–Krattenthaler conjectures, Theorems 1.4 and 1.5, in the next section.

Following the notation in [Reference Cigler and Krattenthaler3], let $R^{(n)}$ be the operator defined on polynomials in $b_i$ ’s and $\lambda _i$ ’s that replaces each $b_i$ by $b_{n-i}$ and each $\lambda _i$ by $\lambda _{n+1-i}$ . For example, $R^{(5)}(b_1+\lambda _2+b^2_3\lambda _1)=b_4+\lambda _4+b^2_2\lambda _5$ .

Recall the matrix $A^{\leq k} (\boldsymbol {b},\boldsymbol {\lambda })$ given in (13). We now state the general reciprocity theorem.

Theorem 6.1. For positive integers k and m, we have

$$ \begin{align*} &\det\left( \mu^{\leq k+m-1}_{n+i+j+2m-2}(\boldsymbol{b},\boldsymbol{\lambda}) \right)_{i,j=0}^{k-1}\\ &\qquad\qquad\qquad \ = \left(\prod_{i=1}^{k+m-1}\lambda_i^{k-i}\right)\det\left( A^{\leq k+m-1} (\boldsymbol{b},\boldsymbol{\lambda}) \right)^{n+2m-2} R^{(k+m-1)}\left( \det \left(\mu^{\leq k+m-1}_{-n-i-j}(\boldsymbol{b},\boldsymbol{\lambda})\right)_{i,j=0}^{m-1}\right). \end{align*} $$

Before proving Theorem 6.1, we define several terminologies and prove some auxiliary results.

Definition 6.2. For a matrix $ A=(A_{i,j})_{i,j=0}^k$ and two subsets $ I,J\subseteq \{0,\dots ,k\} $ of the same cardinality, we define

$$\begin{align*}[A]_{I,J} = \det(A_{i,j})_{i\in I, j\in J}. \end{align*}$$

The following well-known lemma is an important tool in our proofs.

Lemma 6.3. Suppose that $ A=(A_{i,j})_{i,j=0}^{k}$ is an invertible matrix. For subsets $ I,J\subseteq \{0,\dots ,k\} $ of the same cardinality, we have

$$\begin{align*}\left[A^{-1}\right]_{I, J}=(-1)^{\Vert I\Vert + \Vert J\Vert} \frac{[A]_{J^{\prime}, I^{\prime}}}{\det (A)}, \end{align*}$$

where $ \Vert I\Vert =\sum _{i\in I}i $ and $ I'=\{0,\dots ,k\}\setminus I $ .

Definition 6.4. Let $ A=(A_{i,j})_{i,j=0}^{k} $ . We define the weighted directed graph $G(A)$ whose vertex set is $V(A)=\{(i,j): i\in \mathbb {Z}, j\in \{0,\dots ,k\}\}$ and edge set is $E(A)=\{(i,j)\rightarrow (i+1,j'): i\in \mathbb {Z}, j,j'\in \{0,\dots ,k\}\}$ . We assign the weight $A_{j,j'}$ to each edge $(i,j)\rightarrow (i+1,j')$ and ignore the edges with zero weights.

For $ u,v\in V(A) $ , let $P(G(A);u\to v)$ be the set of paths in $G(A)$ from u to v. The weight $\operatorname {wt}_A(\pi )$ of a path $\pi $ is defined to be the product of weights on its edges. For $ u_0,\dots ,u_n,v_0,\dots ,v_n\in V(A) $ , we define $\operatorname {NI}\left (G(A);(u_0,\dots ,u_n) \rightarrow (v_0,\dots ,v_n)\right )$ to be the set of tuples $\boldsymbol {\pi }=(\pi _0,\dots ,\pi _n)$ of nonintersecting paths (i.e., no two paths meet at a vertex in $ V(A) $ ), such that each $\pi _i$ is a path in $ G(A) $ from $u_i$ to $v_j$ for some j. For such a path tuple $\boldsymbol {\pi }$ , there exists a permutation $\sigma $ of $ \{0,\dots ,n\} $ such that each $\pi _i$ is a path from $ u_i $ to $v_{\sigma (i)}$ . The weight $\operatorname {wt}_A(\boldsymbol {\pi })$ of the path tuple is defined to be $\operatorname {sgn}(\sigma )\prod _{i=0}^{n} \operatorname {wt}_A(\pi _i)$ .

Note that if $ A $ is the tridiagoanl matrix $A^{\leq k}(\boldsymbol {b},\boldsymbol {\lambda })$ , then, for any $ i\in \mathbb {Z} $ , a path $ \pi $ in $ P(G(A);(i,0)\to (i+n,0)) $ can be identified with a Motzkin path in $ \operatorname {Mot}^{\le k}_n $ , and we have

(19) $$ \begin{align} \mu_{n}^{\le k}(\boldsymbol{b},\boldsymbol{\lambda})= \sum_{\pi\in \operatorname{Mot}_{n}^{\le k}} \operatorname{wt}(\pi)=\sum_{\pi \in P(G(A);(i,0)\rightarrow (i+n,0))}\operatorname{wt}_A(\pi). \end{align} $$

Moreover, by Proposition 5.1,

(20) $$ \begin{align} \mu_{-n}^{\le k}(\boldsymbol{b},\boldsymbol{\lambda})= \epsilon_0^T \left( A^{-1} \right)^{n} \epsilon_0 =\sum_{\pi \in P(G(A^{-1});(i,0)\rightarrow (i+n,0))}\operatorname{wt}_{A^{-1}}(\pi). \end{align} $$

Lemma 6.5. For the tridiagoanl matrix $A=A^{\leq k}(\boldsymbol {b},\boldsymbol {\lambda })$ , the following statements hold.

  1. 1. Given $I ,J \subseteq \{0,\dots ,k\}$ of the same cardinality and $\{0,\dots ,i\}\subseteq I$ for some i, if J misses two or more elements in $\{0,\dots ,i+1\}$ , then $[A]_{I,J}=0$ .

  2. 2. Given $I\subseteq \{0,\dots ,i-1\}$ , $J\subseteq \{0,\dots ,i\}$ of the same cardinality, we have

    $$ \begin{align*} [A]_{I\cup \{i,\dots,k-1\},J\cup \{i+1,\dots,k\}}&=[A]_{I,J} ,\\ [A]_{I\cup \{i+1,\dots,k\},J\cup \{i,\dots,k-1\}}&=[A]_{I,J} \prod_{j=i+1}^{k}\lambda_j. \end{align*} $$

Proof. (1) Let B be the submatrix of $ A $ consisting of the rows indexed by $0,\dots ,i$ . Since A is a tridiagonal matrix, the jth column of B is zero if $j>i+1$ . So if J misses two or more elements in $0,\dots ,i+1$ , the submatrix of B consisting of the columns indexed by J has rank at most i. We conclude $[A]_{I,J}=0$ .

(2) The submatrix of A with rows indexed by $i,\dots ,k-1$ and columns indexed by $i+1,\dots ,k$ is a lower triangular matrix with diagonal entries all 1. So the first identity follows. Likewise, the submatrix of A with rows indexed by $i+1,\dots ,k$ and columns indexed by $i,\dots ,k-1$ is an upper triangular matrix with diagonal entries $\lambda _{i+1},\dots ,\lambda _{k}$ . This gives the second identity.

Lemma 6.6. Letting $A=A^{\leq k+m-1} (\boldsymbol {b},\boldsymbol {\lambda })$ , we have

$$ \begin{align*} \det\left( \mu^{\leq k+m-1}_{n+i+j+2m-2}(\boldsymbol{b},\boldsymbol{\lambda}) \right)_{i,j=0}^{k-1}= \left(\prod_{i=1}^{k-1}\lambda_i^{k-i}\right) \sum_{(I_0,\dots,I_{n+2m-2})\in X} \prod_{j=0}^{n+2m-3}[A]_{I_j,I_{j+1}}, \end{align*} $$

where X is the set of all tuples $(I_0,\dots ,I_{n+2m-2})$ of k-element subsets of $\{0,\dots ,k+m -1\}$ such that $I_j, I_{n+2m-2-j} \subseteq \{0,\dots ,k-1+j\}$ for all $0\le j\leq m-1$ .

Proof. By (19), we have

$$ \begin{align*} \mu_{n+i+j+2m-2}^{\leq k+m-1}(\boldsymbol{b},\boldsymbol{\lambda})= \sum_{\pi \in P(G(A);(-i,0)\rightarrow (n+2m-2+j,0))}\operatorname{wt}_A(\pi). \end{align*} $$

Thus, the Lindström–Gessel–Viennot lemma [Reference Gessel and Viennot6, Reference Lindström13] gives

$$ \begin{align*} \det\left( \mu^{\leq k+m-1}_{n+i+j+2m-2}(\boldsymbol{b},\boldsymbol{\lambda}) \right)_{i,j=0}^{k-1} =\sum_{\boldsymbol{\pi} \in \operatorname{NI}(G(A);R \rightarrow S)}\operatorname{wt}_A(\boldsymbol{\pi}), \end{align*} $$

where $R=((0,0),(-1,0),\dots ,(-k+1,0))$ and $S=((n+2m-2,0),(n+2m-1,0),\dots ,(n+2m+k-3,0))$ .

Suppose $ \boldsymbol {\pi }=(\pi _0,\dots ,\pi _{k-1}) \in \operatorname {NI}(G(A);R \rightarrow S) $ . Since $ \pi _0,\dots ,\pi _{k-1} $ are nonintersecting Motzkin paths and each $ \pi _i $ is from $ (-i,0) $ to $ (n+2m-2+\sigma (i),0) $ , for some permutation $ \sigma $ , the first $ i $ steps (resp. last $ \sigma (i) $ steps) of $ \pi _i $ are up steps (resp. down steps) whose weights are $ 1 $ ’s (resp. $ \lambda _1,\dots ,\lambda _{\sigma (i)} $ ). Considering the subpath obtained from $ \pi _i $ by deleting the first $ i $ steps and last $ \sigma (i) $ steps, we obtain

(21) $$ \begin{align} \det\left( \mu^{\leq k+m-1}_{n+i+j+2m-2}(\boldsymbol{b},\boldsymbol{\lambda}) \right)_{i,j=0}^{k-1} =\left(\prod_{i=1}^{k-1}\lambda_i^{k-i}\right)\sum_{ \boldsymbol{\pi}\in \operatorname{NI}(G(A);R_1 \rightarrow S_1)}\operatorname{wt}_A(\boldsymbol{\pi}), \end{align} $$

where $R_1=((0,0),(0,1),\dots ,(0,k-1))$ and $S_1=((n+2m-2,0),(n+2m-2,1),\dots ,(n+2m-2,k-1))$ .

For each $\boldsymbol {\pi }=(\pi _0,\dots ,\pi _{k-1}) \in \operatorname {NI}(G(A);R_1 \rightarrow S_1)$ , we define $I(\boldsymbol {\pi })=(I_0,\dots ,I_{n+2m-2})$ , where each $I_j$ is the k-element subset of $\{0,\dots ,k+m -1\}$ consisting of the y-coordinates of the points of $\pi _0,\dots ,\pi _{k-1}$ on the line $x=j$ . For brevity we write $ \boldsymbol {I}=(I_0,\dots ,I_{n+2m-2}) $ . Observe that, since $\boldsymbol {\pi } \in \operatorname {NI}(G(A);R_1 \rightarrow S_1)$ , we have $I_0=I_{n+2m-2}=\{0,\dots ,k-1\}$ . Moreover, since $\pi _0,\dots ,\pi _{k-1}$ are Motzkin paths, we also have $I_j, I_{n+2m-2-j} \subseteq \{0,\dots ,k-1+j\}$ for all $0\le j\leq m-1$ ; that is, $ \boldsymbol {I}\in X $ . Therefore, we can rewrite (21) as

(22) $$ \begin{align} \det\left( \mu^{\leq k+m-1}_{n+i+j+2m-2}(\boldsymbol{b},\boldsymbol{\lambda}) \right)_{i,j=0}^{k-1} = \left(\prod_{i=1}^{k-1}\lambda_i^{k-i}\right) \sum_{\boldsymbol{I}\in X} \sum_{\substack{\boldsymbol{\pi} \in \operatorname{NI}(G(A);R_1 \rightarrow S_1)\\ I(\boldsymbol{\pi})=\boldsymbol{I}}} \operatorname{wt}_{A}(\boldsymbol{\pi}). \end{align} $$

For a fixed tuple $ \boldsymbol {I}=(I_0,\dots ,I_{n+2m-2})\in X $ , applying the Lindström–Gessel–Viennot lemma repeatedly to the paths (of length $ 1 $ ) starting from the points $ (j,r) $ for $ r\in I_j $ to the points $ (j+1,s) $ for $ s\in I_{j+1} $ , we obtain

(23) $$ \begin{align} \sum_{\substack{\boldsymbol{\pi} \in \operatorname{NI}(G(A);R_1 \rightarrow S_1)\\ I(\boldsymbol{\pi})=\boldsymbol{I}}} \operatorname{wt}_{A}(\boldsymbol{\pi})= \prod_{j=0}^{n+2m-3}[A]_{I_j,I_{j+1}}. \end{align} $$

Combining (22) and (23) completes the proof.

Lemma 6.7. Letting $A=A^{\leq k+m-1} (\boldsymbol {b},\boldsymbol {\lambda })$ , we have

$$ \begin{align*} &\det \left(\mu^{\leq k+m-1}_{-n-i-j}(\boldsymbol{b},\boldsymbol{\lambda})\right)_{i,j=0}^{m-1}\\ &\qquad\qquad\qquad\quad = \sum_{(J_0,\dots,J_{n+2m-2})\in Y} \prod_{j=0}^{m-2}[A^{-1}]_{J_j,J_{j+1}\setminus\{0\}} \prod_{j=m-1}^{n+m-2}[A^{-1}]_{J_j,J_{j+1}} \prod_{j=n+m-1}^{n+2m-3}[A^{-1}]_{J_j\setminus\{0\},J_{j+1}}, \end{align*} $$

where Y is the set of all tuples $(J_0,\dots ,J_{n+2m-2})$ of subsets of $\{0,\dots ,k+m -1\}$ satisfying the following conditions:

  1. 1. Both $J_j$ and $J_{n+2m-2-j}$ have cardinality $ j+1 $ and contain $ 0 $ for all $0\leq j\leq m-1$ .

  2. 2. $ |J_j|=m $ for all $m-1\leq j\leq n+m-1$ .

  3. 3. $J_j\cap \{1,\dots ,m-1-j\}= J_{n+2m-2-j}\cap \{1,\dots ,m-1-j\}= \emptyset $ for all $0\le j\leq m-2$ .

Proof. By (20) and the Lindström–Gessel–Viennot lemma, we have

(24) $$ \begin{align} \det\left( \mu^{\leq k+m-1}_{-n-i-j}(\boldsymbol{b},\boldsymbol{\lambda}) \right)_{i,j=0}^{m-1} =\sum_{\boldsymbol{\pi} \in \operatorname{NI}(G(A^{-1});R \rightarrow S)}\operatorname{wt}_{A^{-1}}(\boldsymbol{\pi}), \end{align} $$

where $R=((m-1,0),(m-2,0),\dots ,(0,0))$ and $S=((n+m-1,0),(n+m,0),\dots ,(n+2m-2,0))$ .

For each $ \boldsymbol {\pi }=(\pi _0,\dots ,\pi _{m-1}) \in \operatorname {NI}(G(A^{-1});R \rightarrow S) $ , we define $J(\boldsymbol {\pi })=(J_0,\dots ,J_{n+2m-2})$ , where $J_j$ is the subset of $\{0,\dots ,k+m -1\}$ consisting of the y-coordinates of the points of $\pi _0,\dots ,\pi _{m-1}$ on the line $x=j$ . For brevity, we write $ \boldsymbol {J}=(J_0,\dots ,J_{n+2m-2}) $ . It is easy to check that the tuple $ \boldsymbol {J} $ satisfies the first two conditions for the elements in $ Y $ . Let $ Z $ be the set of such tuples $ \boldsymbol {J} $ . Then we can rewrite (24) as

(25) $$ \begin{align} \det\left( \mu^{\leq k+m-1}_{-n-i-j}(\boldsymbol{b},\boldsymbol{\lambda}) \right)_{i,j=0}^{m-1} =\sum_{\boldsymbol{J}\in Z} \sum_{\substack{\boldsymbol{\pi} \in \operatorname{NI}(G(A^{-1});R \rightarrow S)\\ J(\boldsymbol{\pi})=\boldsymbol{J}}}\operatorname{wt}_{A^{-1}}(\boldsymbol{\pi}). \end{align} $$

For a fixed tuple $ \boldsymbol {J}=(J_0,\dots ,J_{n+2m-2})\in Z $ , applying the Lindström–Gessel–Viennot lemma repeatedly to the paths (of length $ 1 $ ) starting from the points $ (j,r) $ for $ r\in J_j $ to the points $ (j+1,s) $ for $ s\in J_{j+1} $ , where we ignore the point $ (j+1,0) $ (resp. $ (j,0) $ ) if $ 0\le j\le m-2 $ (resp. $ n+m-1\le j\le n+2m-3 $ ), we obtain

(26) $$ \begin{align} \sum_{\substack{\boldsymbol{\pi} \in \operatorname{NI}(G(A^{-1});R \rightarrow S)\\ J(\boldsymbol{\pi})=\boldsymbol{J}}}\operatorname{wt}_{A^{-1}}(\boldsymbol{\pi}) = w(\boldsymbol{J}), \end{align} $$

where

$$\begin{align*}w(\boldsymbol{J}) = \prod_{j=0}^{m-2}[A^{-1}]_{J_j,J_{j+1}\setminus\{0\}} \prod_{j=m-1}^{n+m-2}[A^{-1}]_{J_j,J_{j+1}} \prod_{j=n+m-1}^{n+2m-3}[A^{-1}]_{J_j\setminus\{0\},J_{j+1}}. \end{align*}$$

Combining (25) and (26) gives

$$\begin{align*}\det\left( \mu^{\leq k+m-1}_{-n-i-j}(\boldsymbol{b},\boldsymbol{\lambda}) \right)_{i,j=0}^{m-1} =\sum_{\boldsymbol{J}\in Z} w(\boldsymbol{J}). \end{align*}$$

Since $ Z $ is the set of tuples $ (J_0,\dots ,J_{n+2m-2}) $ satisfying the conditions (1) and (2) (but not necessarily (3)) for the elements in $ Y $ , it remains to show the following claim.

Claim. Let $ \boldsymbol {J}=(J_0,\dots ,J_{n+2m-2})\in Z $ . If $J_j\cap \{1,\dots ,m-1-j\}\ne \emptyset $ or $J_{n+2m-2-j}\cap \{1,\dots ,m-1-j\}\ne \emptyset $ for some $0\le j\leq m-2$ , then $ w(\boldsymbol {J})=0 $ .

To prove the claim, suppose that $J_j\cap \{1,\dots ,m-1-j\}\neq \emptyset $ for some $0\le j\leq m-2$ . Take the largest $ j $ so that $J_{j+1}\cap \{1,\dots ,m-2-j\}= \emptyset $ , which is clearly true if $ j=m-2 $ . By Lemma 6.3, we have

$$ \begin{align*} [A^{-1}]_{J_j,J_{j+1}\setminus\{0\}}= (-1)^{\Vert {J_j}\Vert + \Vert {J_{j+1}\setminus\{0\}}\Vert} \frac{[A]_{(J_{j+1}\setminus\{0\})',(J_j)'}}{\det(A)}. \end{align*} $$

By the assumption on $ j $ , we have $\{0,\dots ,m-2-j\}\subseteq (J_{j+1}\setminus \{0\})'$ and $0,t\not \in (J_j)'$ for some $t\in \{1,\dots ,m-1-j\}$ . Thus, by Lemma 6.5 (1), we have $[A]_{(J_{j+1}\setminus \{0\})',(J_j)'}=0$ , which implies $ w(\boldsymbol {J})=0 $ . Similarly, one can prove that if $J_{n+2m-2-j}\cap \{1,\dots ,m-j-1\}\ne \emptyset $ for some $0\le j\leq m-2$ , then $ w(\boldsymbol {J})=0 $ . This settles the claim and the proof is completed.

We are now ready to prove Theorem 6.1.

Proof of Theorem 6.1.

Abusing the notation, let $R^{(k+m-1)}$ also denote the operator acting on the subsets K of $\{0,\dots ,k+m-1\}$ by

$$ \begin{align*} R^{(k+m-1)}(K)=\{k+m-1-i: i \in K\}. \end{align*} $$

Recall the sets $ X $ and $ Y $ given in Lemmas 6.6 and 6.7, respectively. We define the map $f:X \rightarrow Y$ by $ f(I_0,\dots ,I_{n+2m-2})=(J_0,\dots ,J_{n+2m-2}) $ , where

(27) $$ \begin{align} J_j = \begin{cases} \{0\}\cup R^{(k+m-1)}(\{0,\dots,k-1+j\}\setminus I_j) &\mbox{if } 0 \leq j \leq m-1 ,\\ R^{(k+m-1)}(\{0,\dots,k+m-1\}\setminus I_j) &\mbox{if } m-1 \leq j \leq n+m-1 ,\\ \{0\}\cup R^{(k+m-1)}(\{0,\dots,k+n+2m-3-j\}\setminus I_j) &\mbox{if } n+m-1 \leq j \leq n+2m-2. \end{cases} \end{align} $$

Note that $ J_j $ is well-defined when $ j=m-1 $ or $ j=n-m-1 $ . It is not hard to see that the map f is a bijection.

We claim that, for $0 \leq j \leq m-2$ ,

(28) $$ \begin{align} [A^{-1}]_{J_j,J_{j+1}\setminus\{0\}} = (-1)^{\Vert {J_j}\Vert + \Vert {J_{j+1}\setminus\{0\}}\Vert} \frac{R^{(k+m-1)}([A]_{I_{j+1},I_j})}{\det(A)}. \end{align} $$

To prove the claim, we first use Lemma 6.3 to obtain

(29) $$ \begin{align} [A^{-1}]_{J_j,J_{j+1}\setminus\{0\}} =(-1)^{\Vert {J_j}\Vert +\Vert {J_{j+1}\setminus\{0\}}\Vert} \frac{[A]_{(J_{j+1}\setminus\{0\})',(J_j)'}}{\det(A)}. \end{align} $$

Note that, for $0 \leq j \leq m-2$ , (27) implies

$$ \begin{align*} (J_j)'&=\{0,\dots,k+m-1\}\setminus J_j=R^{(k+m-1)}(I_j\cup \{k+j,\dots,k+m-2\}),\\ (J_{j+1}\setminus\{0\})' &=\{0,\dots,k+m-1\}\setminus (J_{j+1}\setminus\{0\})\\ &= R^{(k+m-1)}(I_{j+1}\cup \{k+j+1,\dots,k+m-1\}). \end{align*} $$

Thus, the right-hand side of (29) is equal to

$$ \begin{align*} (-1)^{\Vert {J_j}\Vert + \Vert {J_{j+1}\setminus\{0\}}\Vert} & \frac{[A]_{R^{(k+m-1)}(I_j\cup \{k+j,\dots,k+m-2\}),R^{(k+m-1)}(I_{j+1}\cup \{k+j+1,\dots,k+m-1\})}}{\det(A)}\\ &\quad = (-1)^{\Vert {J_j}\Vert +\Vert {J_{j+1}\setminus\{0\}}\Vert} \frac{R^{(k+m-1)}([A]_{I_j\cup \{k+j,\dots,k+m-2\}),I_{j+1}\cup \{k+j+1,\dots,k+m-1\}})}{\det(A)}, \end{align*} $$

which, by Lemma 6.5 (2), is equal to the right-hand side of (28), and the claim is proved.

A similar argument shows that, for $m-1\leq j\leq n+m-2$ ,

(30) $$ \begin{align} [A^{-1}]_{J_j,J_{j+1}} = (-1)^{\Vert {J_j}\Vert +\Vert {J_{j+1}}\Vert} \frac{R^{(k+m-1)}([A]_{I_{j+1},I_j})}{\det(A)}, \end{align} $$

and, for $n+m-1\leq j\leq n+2m-3$ ,

(31) $$ \begin{align} [A^{-1}]_{J_j\setminus\{0\},J_{j+1}}=(-1)^{\Vert {J_j\setminus\{0\}}\Vert + \Vert {J_{j+1}}\Vert} \frac{\left(\prod_{i=1}^{j-n-m+1}\lambda_{k+m-i}\right) R^{(k+m-1)} ([A]_{I_{j+1},I_j})} {\det(A)}. \end{align} $$

By (28), (30), and (31) and using the fact that $ \Vert {J_0}\Vert = \Vert {J_{n+2m-2}} \Vert =0 $ and $ \Vert {J\setminus \{0\}}\Vert = \Vert {J}\Vert $ for any set $ J $ , we obtain

(32) $$ \begin{align} \prod_{j=0}^{m-2}[A^{-1}]_{J_j,J_{j+1}\setminus\{0\}} \prod_{j=m-1}^{n+m-2} [A^{-1}]_{J_j,J_{j+1}} \prod_{j=n+m-1}^{n+2m-3}&[A^{-1}]_{J_j\setminus\{0\},J_{j+1}} \notag \\ & \ =\frac{\prod_{i=k}^{k+m-1}\lambda_i^{k-i}}{\det(A)^{n+2m-2}} R^{(k+m-1)} \left( \prod_{j=1}^{n+2m-2}[A]_{I_{j+1},I_{j}} \right). \end{align} $$

Since $ (I_0,\dots ,I_{n+2m-2})\in X $ if and only if $ (I_{n+2m-2},\dots ,I_{0})\in X $ , combining Lemma 6.6, Lemma 6.7 and (32) completes the proof.

7 Proof of Cigler–Krattenthaler conjectures

In this section, we show that Theorem 6.1 implies the Cigler–Krattenthaler conjectures, Theorems 1.4 and 1.5. To obtain Theorem 1.5, we can simply put $\boldsymbol {b}=\boldsymbol {1}$ and $\boldsymbol {\lambda }=\boldsymbol {1}$ in Theorem 6.1. However, it is more difficult to derive Theorem 1.4 from Theorem 6.1 because the left-hand side of the equation in Theorem 1.4 is not of the form as written in Theorem 6.1. To remedy this, we find suitable sequences $\boldsymbol {b}$ and $\boldsymbol {\lambda }$ such that

(33) $$ \begin{align} &\mu^{\leq k+m-1}_{n+i+j+2m-2}(\boldsymbol{b},\boldsymbol{\lambda})= \sum_{s=0}^{2k+2m-1}\mu_{n+i+j+2m-1,0,s}^{\leq 2k+2m-1}(\boldsymbol{0},\boldsymbol{1}). \end{align} $$

Indeed, we will show in Lemma 7.3 that (33) holds if $ \boldsymbol {b}=\boldsymbol {b}^{(k+m-1)} $ and $ \boldsymbol {\lambda }=-\boldsymbol {1} $ , where the sequences $ \boldsymbol {b}^{(\ell )} $ and $ -\boldsymbol {1} $ are defined by

(34) $$ \begin{align} \boldsymbol{b}^{(\ell)}&=\left( b^{(\ell)}_i \right)_{i\ge0}, \qquad b^{(\ell)}_i = \begin{cases} (-1)^{i}2 & \mbox{if } 0 \leq i<\ell ,\\ (-1)^{i} & \mbox{if } i\ge \ell , \end{cases} \end{align} $$
(35) $$ \begin{align} -\boldsymbol{1}&=(-1,-1,\dots). \end{align} $$

We will mostly consider $\mu ^{\le \ell }_n(\boldsymbol {b}^{(\ell )},\boldsymbol {\lambda })$ , which does not depend on the values $b^{(\ell )}_i$ for $i>\ell $ .

Remark 7.1. One may wonder how to guess that $\boldsymbol {b}=\boldsymbol {b}^{(k+m-1)}$ and $\boldsymbol {\lambda }=-\boldsymbol {1}$ is a solution to (33). Such a solution can be found by computer once we fix the value of $ k+m $ . For example, if $ k+m=3 $ , then the sequences $ \boldsymbol {b} $ and $ \boldsymbol {\lambda } $ must satisfy

(36) $$ \begin{align} \mu^{\leq 2}_{n}(\boldsymbol{b},\boldsymbol{\lambda})= \sum_{s=0}^{5}\mu_{n+1,0,s}^{\leq 5}(\boldsymbol{0},\boldsymbol{1}). \end{align} $$

Substituting $ n=1,\dots ,5 $ in (36) gives five equations with variables $ b_0,b_1,b_2, \lambda _1,\lambda _2$ . One can check by computer that there is a unique solution to these equations, which is $ b_0=2, b_1=-2, b_2=1, \lambda _1=-1, \lambda _2=-1 $ . After computing more solutions for different choices of $ k+m $ , one can guess that $\boldsymbol {b}=\boldsymbol {b}^{(k+m-1)}$ and $\boldsymbol {\lambda }=-\boldsymbol {1}$ is a solution to (33).

Now we begin with a simple lemma.

Lemma 7.2. We have

(37) $$ \begin{align} \det\left(A^{\leq k-1}(\boldsymbol{1},\boldsymbol{1})\right) &=\begin{cases} 0 & \mbox{if } k\equiv 2 \quad \pmod 3 ,\\ (-1)^{\left\lfloor {k}/{3}\right\rfloor} &\mbox{otherwise}, \end{cases} \end{align} $$
(38) $$ \begin{align} \det\left(A^{\leq k-1}(\boldsymbol{b}^{(k-1)},-\boldsymbol{1})\right) &=(-1)^{\left\lfloor {k}/{2}\right\rfloor}. \end{align} $$

Proof. To prove (37), we expand the determinant with respect to the first row to get

$$ \begin{align*} \det\left(A^{\leq k-1}(\boldsymbol{1},\boldsymbol{1})\right)=\det\left(A^{\leq k-2}(\boldsymbol{1},\boldsymbol{1})\right)- \det\left(A^{\leq k-3}(\boldsymbol{1},\boldsymbol{1})\right). \end{align*} $$

Then (37) follows easily by induction on k.

For the second identity, let $U=(U_{i,j})_{i,j=0}^{k-1}$ and $L=(L_{i,j})_{i,j=0}^{k-1}$ be the matrices defined by

$$ \begin{align*} U_{i,j} =\begin{cases} 1 &\text{ if }\qquad i=j,\\ (-1)^{i-1} &\text{ if }\qquad i=j-1,\\ 0 &\text{otherwise}, \end{cases} \qquad L_{i,j} =\begin{cases} (-1)^{i} &\text{ if }\qquad i=j,\\ -1 &\text{ if }\qquad i=j+1,\\ 0 &\text{otherwise}. \end{cases} \end{align*} $$

It is easy to check that $A^{\leq k-1}(\boldsymbol {b}^{(k-1)},-\boldsymbol {1})=UL$ . Since U is an upper-triangular matrix with diagonal entries all $ 1 $ and L is a lower-triangular matrix with diagonal entries $1,-1,1,-1,\dots $ , we obtain (38).

Since the proof of Theorem 1.5 is simpler than that of Theorem 1.4, we present it first.

Proof of Theorem 1.5.

We put $\boldsymbol {b}=\boldsymbol {1}$ and $\boldsymbol {\lambda }=\boldsymbol {1}$ in Theorem 6.1. Then Theorem 1.5 immediately follows from (37) and

$$ \begin{align*} \left. R^{(k+m-1)}\left(\mu_{-n-i-j}^{\le k+m-1}(\boldsymbol{b},\boldsymbol{\lambda})\right) \right|{}_{\boldsymbol{b}=\boldsymbol{1},\boldsymbol{\lambda}=\boldsymbol{1}} =\mu_{-n-i-j}^{\le k+m-1}(\boldsymbol{1},\boldsymbol{1}).\\[-38pt] \end{align*} $$

In order to prove Theorem 1.4, we need the following two technical lemmas whose proofs will be given later.

Lemma 7.3. For $n\geq 0$ and $k\ge 1$ , we have

$$ \begin{align*} \mu^{\leq k}_{n}(\boldsymbol{b}^{(k)},-\boldsymbol{1}) =\sum_{s=0}^{2k+1}\mu_{n+1,0,s}^{\leq 2k+1}(\boldsymbol{0},\boldsymbol{1}). \end{align*} $$

Lemma 7.4. For $n\geq 0$ and $k\ge 1$ , we have

$$ \begin{align*} \left. (-1)^{kn}\left(R^{(k)} \left( \mu^{\leq k}_{-n}(\boldsymbol{b},\boldsymbol{\lambda}) \right)\right)\right|{}_{\boldsymbol{b}=\boldsymbol{b}^{(k)}, \boldsymbol{\lambda}=-\boldsymbol{1}} =\left| \operatorname{Alt}_{n}^{\leq k+1} \right|. \end{align*} $$

Proof of Theorem 1.4.

We put $\boldsymbol {b}=\boldsymbol {b}^{(k+m-1)}$ and $\boldsymbol {\lambda }=-\boldsymbol {1}$ in Theorem 6.1 and apply Lemma 7.3, (38) and Lemma 7.4, which gives

(39) $$ \begin{align} &\det\left( \sum_{s=0}^{2k+2m-1}\mu_{n+i+j+2m-1,0,s}^{\leq 2k+2m-1}(\boldsymbol{0},\boldsymbol{1}) \right)_{i,j=0}^{k-1}\notag \\ &\qquad\qquad\quad = \left(\prod_{i=1}^{k+m-1}(-1)^{k-i}\right) (-1)^{\left\lfloor \frac{k+m}{2}\right\rfloor(n+2m-2)} \det \left((-1)^{(k+m-1)(n+i+j)}|\operatorname{Alt}_{n+i+j}^{\leq k+m}|\right)_{i,j=0}^{m-1}. \end{align} $$

Observe that $\left \lfloor \frac {k+m}{2}\right \rfloor \equiv \binom {k+m}{2} \ \ \pmod 2$ and

$$ \begin{align*} \det \left((-1)^{(k+m-1)(n+i+j)}|\operatorname{Alt}_{n+i+j}^{\leq k+m}|\right)_{i,j=0}^{m-1}=(-1)^{(k+m-1)nm}\det \left(|\operatorname{Alt}_{n+i+j}^{\leq k+m}|\right)_{i,j=0}^{m-1}, \end{align*} $$

and $ (-1)^{(k+m-1)nm} = (-1)^{kmn}$ . Therefore, we can rewrite (39) as

$$\begin{align*}\det\left( \sum_{s=0}^{2k+2m-1}\mu_{n+i+j+2m-1,0,s}^{\leq 2k+2m-1}(\boldsymbol{0},\boldsymbol{1}) \right)_{i,j=0}^{k-1}\\ = s \cdot \det \left(|\operatorname{Alt}_{n+i+j}^{\leq k+m}|\right)_{i,j=0}^{m-1}, \end{align*}$$

where $ s = (-1)^{k(k+m-1)-\binom {k+m}{2}}(-1)^{n\binom {k+m}{2}}(-1)^{knm} $ , which is equal to

$$\begin{align*}(-1)^{km+(n+1)\binom{k+m}{2}+knm} = (-1)^{\left(km +\binom{k+m}{2} \right)(n+1)} = (-1)^{\left(\binom{k}{2} + \binom{m}{2} \right)(n+1)}. \end{align*}$$

This completes the proof.

Now it remains to prove Lemmas 7.3 and 7.4.

Proof of Lemma 7.3.

Using (14), we can restate the lemma as

(40) $$ \begin{align} \epsilon_0^{T} (A^{\leq k}(\boldsymbol{b}^{(k)},-\boldsymbol{1}))^{n} \epsilon_0=\epsilon_0^{T} (A^{\leq 2k+1}(\boldsymbol{0},\boldsymbol{1}))^{n+1} v , \end{align} $$

where $v=\sum _{s=0}^{2k+1}\epsilon _s$ .

Fix the integer $ k\ge 1 $ and, for $ n\ge 0 $ , let

$$ \begin{align*} (A^{\leq k}(\boldsymbol{b}^{(k)},-\boldsymbol{1}))^{n} \epsilon_0&=(a_{n,0},\dots,a_{n,k})^{T},\\ (A^{\leq 2k+1}(\boldsymbol{0},\boldsymbol{1}))^{n} v&=(d_{n,0},\dots,d_{n,2k+1})^{T}. \end{align*} $$

We also define $a_{n,j}=0$ for $ j\not \in \{0,\dots ,k\} $ and $d_{n,i}=0$ for $ i\not \in \{0,\dots ,2k+1\} $ . Then, by definition, we have

(41) $$ \begin{align} a_{n+1,i} &= -a_{n,i-1} +(-1)^i2 a_{n,i}+a_{n,i+1}, \qquad 0\le i\le k-1, \end{align} $$
(42) $$ \begin{align} a_{n+1,k} &= -a_{n,k-1} +(-1)^k a_{n,k}, \end{align} $$
(43) $$ \begin{align} d_{n+1,i} &= d_{n,i-1} + d_{n,i+1}, \qquad 0\le i\le 2k+1, \end{align} $$
(44) $$ \begin{align} d_{n+1,i}&=d_{n+1,2k+1-i}, \qquad 0\le i\le 2k+1, \end{align} $$

where (44) follows from the symmetry of the matrix $A^{\leq 2k+1}(\boldsymbol {0},\boldsymbol {1})$ .

We claim that, for all $ n\ge 0 $ and $0\leq i \leq k$ , (with $ k\ge 1 $ fixed)

(45) $$ \begin{align} d_{n+1,i}-d_{n+1,i-1}=a_{n,i}+(-1)^{i-1}a_{n,i-1}. \end{align} $$

Note that if $ i=0 $ , we have $ d_{n+1,0}=a_{n,0} $ , which is equivalent to (40). Thus, it suffices to prove the claim.

To prove the claim (45), we proceed by induction on n. The base case $n=0$ is easily checked by

$$ \begin{align*} (d_{1,0},\dots,d_{1,2k+1})^{T} &= (A^{\leq 2k+1}(\boldsymbol{0},\boldsymbol{1}))^{1} v=(1,2,\dots,2,1)^T,\\ (a_{0,0},\dots,a_{0,k})^{T} &= \epsilon_0 = (1,0,\dots,0)^T. \end{align*} $$

Now assume (45) is true for n and consider the case $n+1$ . Suppose $ 0\leq i \leq k-1$ . By (43) and the induction hypothesis,

$$ \begin{align*} d_{n+2,i}-d_{n+2,i-1} &= (d_{n+1,i-1}+d_{n+1,i+1})-(d_{n+1,i-2}+d_{n+1,i})\\ & =a_{n,i-1}+(-1)^{i-2}a_{n,i-2}+a_{n,i+1}+(-1)^{i}a_{n,i}. \end{align*} $$

However, by (41),

$$ \begin{align*} & a_{n+1,i}+(-1)^{i-1}a_{n+1,i-1} \\ &=(-a_{n,i-1}+(-1)^{i}2a_{n,i}+a_{n,i+1})+(-1)^{i-1}(-a_{n,i-2}+(-1)^{i-1}2a_{n,i-1}+a_{n,i})\\ & =a_{n,i-1}+(-1)^{i-2}a_{n,i-2}+a_{n,i+1}+(-1)^{i}a_{n,i}. \end{align*} $$

Thus, $d_{n+2,i}-d_{n+2,i-1}=a_{n+1,i}+(-1)^{i-1}a_{n+1,i-1} $ . Suppose $i=k$ . By (43), (44) and the induction hypothesis,

$$ \begin{align*} d_{n+2,k}-d_{n+2,k-1}&=(d_{n+1,k-1}+d_{n+1,k+1})-(d_{n+1,k-2}+d_{n+1,k})\\ &=d_{n+1,k-1}-d_{n+1,k-2}\\ &=a_{n,k-1}+(-1)^{k-2}a_{n,k-2}. \end{align*} $$

However, by (42),

$$ \begin{align*} &a_{n+1,k}+(-1)^{k-1}a_{n+1,k-1}\\ &=(-a_{n,k-1}+(-1)^{k}a_{n,k})+ (-1)^{k-1}(-a_{n,k-2}+(-1)^{k-1}2a_{n,k-1}+a_{n,k})\\ &=a_{n,k-1}+(-1)^{k-2}a_{n,k-2}. \end{align*} $$

Thus, we also have $d_{n+2,i}-d_{n+2,i-1}=a_{n+1,i}+(-1)^{i-1}a_{n+1,i-1} $ . This settles (45) by induction and the proof is completed.

In order to prove Lemma 7.4, we need the following two lemmas.

Lemma 7.5. We have

$$ \begin{align*} |\operatorname{Alt}_{n}^{\leq k+1}| = \epsilon_0^{T}(A')^n v, \end{align*} $$

where $v=\sum _{s=0}^{2k+1}\epsilon _s$ and $A'=(A^{\prime }_{i,j})_{i,j=0}^{2k+1}$ is the matrix defined by

$$\begin{align*}A^{\prime}_{i,j} =\begin{cases} 1 &\mbox{if } i \equiv 0 \quad \pmod 2, j \equiv 1 \quad \pmod 2 , \text{ and } i<j , \\ 1 &\mbox{if } i \equiv 1 \quad \pmod 2, j \equiv 0 \quad \pmod 2, \text{ and } i>j ,\\ 0 &\text{otherwise}. \end{cases} \end{align*}$$

Proof. From the definition of $A'$ , the value $\epsilon _0^{T}(A')^n \epsilon _s$ equals the number of sequences $(a_1,\dots ,a_n)$ satisfying the following three conditions:

  1. 1. $0 \leq a_i \leq 2k+1$ and $a_i \equiv i \ \ \pmod 2$ ,

  2. 2. $a_1>a_2<a_3>a_4<\cdots $ ,

  3. 3. $a_n=s$ .

So $\epsilon _0^{T}(A')^n v$ counts the number of sequences $(a_1,\dots ,a_n)$ satisfying the conditions (1) and (2). Using the bijection in Proposition 3.3, such sequences are in bijection with the elements of $\operatorname {Alt}_{n}^{\leq k+1}$ .

Lemma 7.6. We have

$$\begin{align*}\left. R^{(k)}\left(A^{\leq k}(\boldsymbol{b},\boldsymbol{\lambda})\right)\right|{}_{\boldsymbol{b}=\boldsymbol{b}^{(k)}, \boldsymbol{\lambda}=-\boldsymbol{1}}=B^{-1}, \end{align*}$$

where $B=(B_{i,j})_{i,j=0}^{k}$ is the matrix defined by

$$\begin{align*}B_{i,j}= (-1)^{\left\lfloor \frac{k-i}{2}\right\rfloor+\left\lfloor \frac{k+1-j}{2}\right\rfloor}\left(k+1-\max(i,j)\right). \end{align*}$$

Proof. Denote $\bar {A}= \left (\bar {A}_{i,j}\right )_{i,j=0}^{k} = \left (R^{(k)}(A^{\leq k}(\boldsymbol {b},\boldsymbol {\lambda }))\right )\vert _{\boldsymbol {b}=\boldsymbol {b}^{(k)}, \boldsymbol {\lambda }=-\boldsymbol {1}}$ . In other words,

$$ \begin{align*} \bar{A}_{i,j} =\begin{cases} (-1)^{k} &\mbox{if } i=j=0 ,\\ (-1)^{k-i}2 &\mbox{if } i=j\ge 1 ,\\ -1 &\mbox{if } i=j+1 ,\\ 1 &\mbox{if } i=j-1 ,\\ 0 &\mbox{otherwise}. \end{cases} \end{align*} $$

We must show $\left (B\bar {A}\right )_{i,j}=\delta _{i,j}$ for $ 0\le i,j\le k $ , where $ \delta _{i,j}=1 $ if $ i=j $ and $ \delta _{i,j}=0 $ otherwise. To this end, we consider the following three cases.

First, suppose $j=0$ . Then $\left (B\bar {A}\right )_{i,0}= (-1)^{k}B_{i,0}-B_{i,1}$ . Since $k=\left \lfloor \frac {k}{2}\right \rfloor +\left \lfloor \frac {k+1}{2}\right \rfloor $ ,

$$ \begin{align*} \left(B\bar{A}\right)_{i,0} &=(-1)^{k}(-1)^{\left\lfloor \frac{k-i}{2}\right\rfloor+\left\lfloor \frac{k+1}{2}\right\rfloor}(k+1-i)-(-1)^{\left\lfloor \frac{k-i}{2}\right\rfloor+\left\lfloor \frac{k}{2}\right\rfloor}(k+1-\max(i,1))\\ &=(-1)^{\left\lfloor \frac{k-i}{2}\right\rfloor+\left\lfloor \frac{k}{2}\right\rfloor}\left( -i+\max(i,1) \right)=\delta_{i,0}. \end{align*} $$

Second, suppose $1\le j\le k-1$ . Then

$$ \begin{align*} \left(B\bar{A}\right)_{i,j}= B_{i,j-1}+(-1)^{k-j}2B_{i,j}-B_{i,j+1}. \end{align*} $$

Letting $ s=(-1)^{\left \lfloor \frac {k-i}{2}\right \rfloor +\left \lfloor \frac {k-j}{2}\right \rfloor } $ , we have

$$ \begin{align*} B_{i,j-1} &= -s(k+1-\max(i,j-1)),\\ (-1)^{k-j}2B_{i,j} &= (-1)^{\left\lfloor \frac{k-j}{2}\right\rfloor+\left\lfloor \frac{k+1-j}{2}\right\rfloor}2B_{i,j} = 2s(k+1-\max(i,j)),\\ -B_{i,j+1} &= -s(k+1-\max(i,j+1)). \end{align*} $$

Thus,

$$\begin{align*}\left(B\bar{A}\right)_{i,j} = s(\max(i,j-1)-2\max(i,j)+\max(i,j+1)) = \delta_{i,j}. \end{align*}$$

Finally, suppose $j=k$ . In this case, we have

$$ \begin{align*} \left(B\bar{A}\right)_{i,k} &=B_{i,k-1}+2B_{i,k}\\ &=(-1)^{\left\lfloor \frac{k-i}{2}\right\rfloor+1}(k+1-\max(i,k-1)) +2(-1)^{\left\lfloor \frac{k-i}{2}\right\rfloor}(k+1-k)\\ &=(-1)^{\left\lfloor \frac{k-i}{2}\right\rfloor}(\max(i,k-1)-k+1) = \delta_{i,k}. \end{align*} $$

Therefore, $\left (B\bar {A}\right )_{i,j}=\delta _{i,j}$ for all $ 0\le i,j\le k $ and the lemma follows.

Now we are ready to prove Lemma 7.4.

Proof of Lemma 7.4.

Recall the matrices $A'$ and B in Lemmas 7.5 and 7.6, respectively. By these lemmas and Proposition 5.1, it is enough to show

(46) $$ \begin{align} \epsilon_0^{T} (A')^{n} v=(-1)^{kn}\epsilon_0^{T}B^{n}\epsilon_0, \end{align} $$

where $v=\sum _{s=0}^{2k+1}\epsilon _s$ .

Denote $(A')^{n} v=(a_{n,0},\dots ,a_{n,2k+1})^{T}$ and $B^{n}\epsilon _0=(b_{n,0},\dots ,b_{n,k})^{T}$ . We have $a_{n,i}=a_{n,2k+1-i}$ for $0\leq i\leq k$ due to the symmetry of the matrix $A'$ .

We claim that for $0\leq i \leq k$ ,

(47) $$ \begin{align} a_{n,i}-a_{n,i-1}= \begin{cases} (-1)^{n-1+\left\lfloor \frac{i-1}{2}\right\rfloor}b_{n,i} & \mbox{if } k \equiv 1 \quad \pmod 2 , \\ (-1)^{\left\lfloor \frac{i}{2}\right\rfloor}b_{n,i} & \mbox{if } k \equiv 0 \quad \pmod 2 , \end{cases} \end{align} $$

where $a_{n,i}=b_{n,i}=0$ if $i<0$ . Observe that if $ i=0 $ in (47), we have $ a_{n,0}=(-1)^{n} b_{n,0} $ if $ k\equiv 1 \ \ \pmod 2 $ and $ a_{n,0}=b_{n,0} $ if $ k \equiv 0 \ \ \pmod 2 $ , which is equivalent to (46). Hence, it suffices to prove (47).

To prove the claim (47), we proceed by induction on n. The base case $n=0$ is trivial. Now assume (47) is true for n and consider the case $n+1$ . We will only prove the case when k is even because the other case can be proved similarly.

For $ 0\le i\le k $ , using the symmetry $a_{n,i}=a_{n,2k+1-i}$ , we get

$$ \begin{align*} a_{n+1,i}=\sum_{j=0}^{2k+1}A^{\prime}_{i,j}a_{n,j}=\sum_{j=0}^{k}\left(A^{\prime}_{i,j}+A^{\prime}_{i,2k+1-j}\right)a_{n,j}, \end{align*} $$

which implies

$$\begin{align*}a_{n+1,i}= \begin{cases} \sum_{j=0}^{k}a_{n,j}-\sum_{j=0}^{{i}/{2}}a_{n,2j-1} & \mbox{if } i \equiv 0 \quad \pmod 2 , \\ \sum_{j=0}^{(i-1)/{2}}a_{n,2j} & \mbox{if } i \equiv 1 \quad \pmod 2. \end{cases} \end{align*}$$

Therefore, we have

(48) $$ \begin{align} a_{n+1,i}-a_{n+1,i-1}=(-1)^{i}\sum_{j=i}^{k}a_{n,j}. \end{align} $$

Using the induction hypothesis, we sum the identities (47), where the index $ i $ takes the values $ i,i-1,\dots ,1 $ , to obtain

(49) $$ \begin{align} a_{n,i}=\sum_{j=0}^{i}(-1)^{\left\lfloor \frac{j}{2}\right\rfloor}b_{n,j}. \end{align} $$

Now we compare both sides of (47) for the case $ n+1 $ . By (48) and (49), we have

(50) $$ \begin{align} a_{n+1,i}-a_{n+1,i-1}=\sum_{j=0}^{i}(-1)^{i+\left\lfloor \frac{j}{2}\right\rfloor}(k+1-i)b_{n,j} +\sum_{j=i+1}^{k}(-1)^{i+\left\lfloor \frac{j}{2}\right\rfloor}(k+1-j)b_{n,j}. \end{align} $$

However,

$$\begin{align*}(-1)^{\left\lfloor \frac{i}{2}\right\rfloor} b_{n+1,i} = (-1)^{\left\lfloor \frac{i}{2}\right\rfloor} \sum_{j=0}^{k} B_{i,j}b_{n,j} = \sum_{j=0}^{k}(-1)^{\left\lfloor \frac{i}{2}\right\rfloor+\left\lfloor \frac{k-i}{2}\right\rfloor+\left\lfloor \frac{k+1-j}{2}\right\rfloor} (k+1-\max(i,j))b_{n,j}, \end{align*}$$

which is equal to the right-hand side of (50) because the assumption that $ k $ is even implies

$$\begin{align*}(-1)^{\left\lfloor \frac{i}{2}\right\rfloor+\left\lfloor \frac{k-i}{2}\right\rfloor+\left\lfloor \frac{k+1-j}{2}\right\rfloor} =(-1)^{\left\lfloor \frac{i}{2}\right\rfloor+\left\lfloor \frac{-i}{2}\right\rfloor+\left\lfloor \frac{1-j}{2}\right\rfloor} =(-1)^{i+\left\lfloor \frac{j}{2}\right\rfloor}. \end{align*}$$

Therefore, (47) is also true for $ n+1 $ . By induction, the claim is settled, which completes the proof.

We finish this section by presenting an interesting consequence of Lemma 7.4.

Corollary 7.7. We have

$$\begin{align*}\sum_{n\ge1} |\operatorname{Alt}_{n}^{\leq k+1}|x^n =\cfrac{-y}{ y-b_0- \cfrac{-1}{ y-b_1- \cfrac{-1}{ y-b_2- \genfrac{}{}{0pt}{1}{}{\displaystyle\ddots - \cfrac{-1}{y-b_k}}} }}, \end{align*}$$

where $y=(-1)^k x$ and

$$ \begin{align*} b_i=\begin{cases} (-1)^k &\mbox{if } i=0 , \\ (-1)^{k-i}2 &\mbox{if } 1 \leq i \leq k. \end{cases} \end{align*} $$

Proof. This is immediate from Proposition 2.7 and Lemma 7.4.

It would be interesting to find a direct combinatorial proof of Corollary 7.7.

8 Application of the general reciprocity theorem

In this section, we show that the general reciprocity theorem (Theorem 6.1) implies the following result of Cigler and Krattenthaler [Reference Cigler and Krattenthaler3, Theorem 34]. Using this theorem, we give a generalization of a result on reverse plane partitions, which was conjectured by Morales, Pak and Panova [Reference Morales, Pak and Panova14] and proved independently by Hwang et al. [Reference Hwang, Kim and Yoo9] and Guo et al. [Reference Guo, Zhao and Zhong7].

Theorem 8.1 [Reference Cigler and Krattenthaler3, Theorem 34].

We have

$$ \begin{align*} &\det\left(\mu^{\leq 2k+2m-1}_{2n+2i+2j+4m-2}(\boldsymbol{0},\boldsymbol{\lambda})\right)_{i,j=0}^{k-1}\\ &\qquad\qquad\qquad\qquad\quad = \left( \prod_{i=1}^{k+m-1} \lambda_{2i}^{k-i} \prod_{i=1}^{k+m}\lambda_{2i-1}^{k-i+n+2m-1} \right) R^{(2k+2m-1)}\left(\det\left(\mu^{\leq 2k+2m-1}_{-2n-2i-2j}(\boldsymbol{0},\boldsymbol{\lambda})\right)_{i,j=0}^{m-1}\right). \end{align*} $$

We note that the statement in [Reference Cigler and Krattenthaler3, Theorem 34] uses the change of variables $ \lambda _{2i-1}=A_i^{-1}V_i^{-1} $ and $\lambda _{2i}=A_i^{-1}V_{i+1}^{-1} $ .

As before, let $ \boldsymbol {b}=(b_i)_{i\ge 0} $ and $ \boldsymbol {\lambda }=(\lambda _i)_{i\ge 1} $ be sequences of indeterminates. We define $ \lambda _0=0 $ and the following sequences:

$$ \begin{align*} \boldsymbol{b'}&=\left( b^{\prime}_i \right)_{i\ge0}, \qquad b^{\prime}_i=\lambda_{2i}+\lambda_{2i+1},\\ \boldsymbol{\lambda'}&=\left( \lambda^{\prime}_i \right)_{i\ge1}, \qquad \lambda^{\prime}_i=\lambda_{2i-1}\lambda_{2i},\\ \boldsymbol{b''}&=\left( b^{\prime\prime}_i \right)_{i\ge0}, \qquad b^{\prime\prime}_i=\lambda_{2i+1}+\lambda_{2i+2},\\ \boldsymbol{\lambda''}&=\left( \lambda^{\prime\prime}_i \right)_{i\ge1},\qquad \lambda^{\prime\prime}_i=\lambda_{2i}\lambda_{2i+1}. \end{align*} $$

Lemma 8.2. We have

$$ \begin{align*} \mu_{2n}^{\leq 2k-1}(\boldsymbol{0},\boldsymbol{\lambda})=\mu_{n}^{\leq k-1}(\boldsymbol{b'},\boldsymbol{\lambda'}) =\left.\lambda_1\mu_{n-1}^{\leq k-1}(\boldsymbol{b''},\boldsymbol{\lambda''})\right|{}_{\lambda_{2k}=0}. \end{align*} $$

Proof. This can be proved by the same method in the proof of [Reference Corteel, Kim and Stanton4, Proposition 4.2].

Lemma 8.3. We have

$$ \begin{align*} \det\left(A^{\leq k-1}(\boldsymbol{b'},\boldsymbol{\lambda'})\right)=\prod_{i=1}^{k}\lambda_{2i-1}. \end{align*} $$

Proof. Expanding the determinant along the last row gives a simple recurrence for the left-hand side. Then the lemma follows easily by induction.

Lemma 8.4. We have

$$ \begin{align*} \left.\left(R^{(k-1)}\left( \mu_{-n}^{\leq k-1}(\boldsymbol{b},\boldsymbol{\lambda}) \right)\right)\right\vert{}_{\boldsymbol{b}=\boldsymbol{b'},\boldsymbol{\lambda}=\boldsymbol{\lambda'}} =R^{(2k-1)}\left(\lambda_1^{-1}\mu^{\leq 2k-1}_{-2n+2}(\boldsymbol{0},\boldsymbol{\lambda})\right). \end{align*} $$

Proof. It is easy to see that

$$ \begin{align*} \left.\left(R^{(k-1)}\left( \mu_{n}^{\leq k-1}(\boldsymbol{b},\boldsymbol{\lambda}) \right)\right)\right\vert{}_{\boldsymbol{b}=\boldsymbol{b'},\boldsymbol{\lambda}=\boldsymbol{\lambda'}} =\left.R^{(2k-1)}\left(\mu^{\leq k-1}_{n}(\boldsymbol{b''},\boldsymbol{\lambda''})\right)\right|{}_{\lambda_{2k}=0}, \end{align*} $$

where in the right-hand side $ \mu ^{\leq k-1}_{n}(\boldsymbol {b''},\boldsymbol {\lambda ''}) $ is a polynomial in $ \lambda _i $ ’s and the operator $ R^{(2k-1)} $ replaces $ \lambda _i $ to $ \lambda _{2k-i} $ . Thus, by Lemma 8.2, we obtain

$$ \begin{align*} \left.\left(R^{(k-1)}\left( \mu_{n}^{\leq k-1}(\boldsymbol{b},\boldsymbol{\lambda}) \right)\right)\right\vert{}_{\boldsymbol{b}=\boldsymbol{b'},\boldsymbol{\lambda}=\boldsymbol{\lambda'}} =R^{(2k-1)}\left(\lambda_1^{-1}\mu^{\leq 2k-1}_{2n+2}(\boldsymbol{0},\boldsymbol{\lambda})\right). \end{align*} $$

Extending both sides to the negative indices completes the proof.

Proof of Theorem 8.1.

We put $\boldsymbol {b}=\boldsymbol {b'}$ and $\boldsymbol {\lambda }=\boldsymbol {\lambda '}$ in Theorem 6.1. By Lemmas 8.2, 8.3 and 8.4, we get

$$ \begin{align*} &\det\left(\mu^{\leq 2k+2m-1}_{2n+2i+2j+4m-4}(\boldsymbol{0},\boldsymbol{\lambda})\right)_{i,j=0}^{k-1}\\ &\qquad\qquad\qquad \ =\left(\prod_{i=1}^{k+m-1} \lambda_{2i-1}^{k-i}\lambda_{2i}^{k-i} \prod_{i=1}^{k+m}\lambda_{2i-1}^{n+2m-2}\right) R^{(2k+2m-1)}\left(\det\left(\lambda_1^{-1}\mu^{\leq 2k+2m-1}_{-2n-2i-2j+2}(\boldsymbol{0},\boldsymbol{\lambda})\right)_{i,j=0}^{m-1}\right). \end{align*} $$

Pulling out the factor $ \lambda _1^{-1} $ in the determinant and replacing $ n $ by $ n+1 $ gives the desired equation.

Now we will give an application of Theorem 8.1 to reverse plane partitions. We will use the definitions of partitions and reverse plane partitions in Hwang et al. [Reference Hwang, Kim and Yoo9].

We denote by $ {\operatorname {RPP}}(\lambda /\mu ) $ the set of reverse plane partitions of shape $ \lambda /\mu $ . We also denote by $ {\operatorname {RPP}}^{\le k}(\lambda /\mu ) $ the set of reverse plane partitions in $ {\operatorname {RPP}}(\lambda /\mu ) $ whose entries are contained in $ \{0,\dots ,k\} $ . For a reverse plane partition $ T $ , we define $ |T| $ to be the sum of all entries in $ T $ .

Recall that $ \operatorname {Alt}_{2n+1} $ is the set of sequences $ a_1\le a_2 \ge a_3\le \cdots \ge a_{2n+1} $ of positive integers and $ \operatorname {Alt}_{2n+1}^{\le k} $ is the set of sequences in $ \operatorname {Alt}_{2n+1} $ whose entries are contained in $ \{1,\dots ,k\} $ . We define $ \overline {\operatorname {Alt}}_{2n+1} $ to be the set of sequences $ a_1\ge a_2 \le a_3\ge \cdots \le a_{2n+1} $ of positive integers and define $ \overline {\operatorname {Alt}}_{2n+1}^{\le k} $ to be the set of sequences in $ \overline {\operatorname {Alt}}_{2n+1} $ whose entries are contained in $ \{1,\dots ,k\} $ . For a sequence $ s=(a_1,\dots ,a_{2n+1}) $ in $ \operatorname {Alt}_{2n+1} $ or $ \overline {\operatorname {Alt}}_{2n+1} $ , let $ |s|=a_1+\dots +a_{2n+1} $ .

Morales, Pak and Panova [Reference Morales, Pak and Panova14] conjectured the following identity, which was proved independently by Hwang et al. [Reference Hwang, Kim and Yoo9] and Guo et al. [Reference Guo, Zhao and Zhong7]:

(51) $$ \begin{align} \sum_{\pi \in \operatorname{RPP}\left(\delta_{n+2 m} / \delta_{n}\right)} q^{|\pi|}=q^{-\frac{m(m+1)(6 n+8 m-5)}{6}} \det\left(\sum_{s\in\overline{\operatorname{Alt}}_{2n+2i+2j+1}}q^{|s|}\right)_{i, j=0}^{m-1}, \end{align} $$

where $ \delta _n=(n-1,\dots ,0) $ . In [Reference Hwang, Kim and Yoo9, Theorem 1.2] the matrix entries are generating functions for alternating sequences of nonnegative integers (see [Reference Hwang, Kim and Yoo9, (20)]), whereas (51) uses alternating sequences of positive integers. It is easy to check that the two statements are equivalent.

In [Reference Cigler and Krattenthaler3, Theorem 36] Cigler and Krattenthaler gave an equivalent statement of Theorem 8.1 using trapezoidal arrays. They also found a bijection between trapezoidal arrays and bounded plane partitions. Using their bijection, a simple connection between bounded plane partitions and bounded reverse plane partitions, a simple connection between $ \operatorname {Alt}^{\le k+m}_{2n+1} $ and $ \overline {\operatorname {Alt}}^{\le k+m}_{2n+1} $ , and the change of variables $ V_i\mapsto V_{k+m+1-i} $ and $ A_i\mapsto A_{k+m+1-i} $ , we can restate [Reference Cigler and Krattenthaler3, Theorem 36] as follows.

Theorem 8.5 [Reference Cigler and Krattenthaler3, Theorem 36 (restated)].

We have

(52) $$ \begin{align} \sum_{T\in{\operatorname{RPP}}^{\le k}(\delta_{n+2m}/\delta_{n})} \operatorname{wt}(T) =\det\left( \sum_{t\in\overline{\operatorname{Alt}}_{2n+2i+2j+1}^{\le k+m}} \operatorname{wt}(t) \right)_{i,j=0}^{m-1}, \end{align} $$

where for $ T\in {\operatorname {RPP}}^{\le k}(\delta _{n+2m}/\delta _{n}) $ and $ t=(t_1,\dots ,t_{2p+1})\in \overline {\operatorname {Alt}}^{\le k+m}_{2p+1} $ ,

$$ \begin{align*} \operatorname{wt}(t)&=V_{t_1}V_{t_3}\cdots V_{t_{2n+1}} A_{t_2}A_{t_4}\cdots A_{t_{2n}},\\ \operatorname{wt}(T)&=\prod_{(i,j)\in\delta_{n+2m}/\delta_{n}} \operatorname{wt}(T(i,j)) ,\\ \operatorname{wt}(T(i,j))&= \begin{cases} A_{T(i,j)+\left\lfloor (i+j-n+1)/2\right\rfloor} &\text{if } i+j-n \text{ is odd},\\ V_{T(i,j)+\left\lfloor (i+j-n+1)/2\right\rfloor} &\text{if } i+j-n \text{ is even}. \end{cases} \end{align*} $$

Substituting $ V_i =A_i= q^{i} $ in the equation (52) gives the following corollary.

Corollary 8.6. We have

$$ \begin{align*} \sum_{S\in{\operatorname{RPP}}^{\le k}(\delta_{n+2m}/\delta_{n})} q^{|S|} = q^{-\frac{m(m+1)(6 n+8 m-5)}{6}} \det\left(\sum_{s\in\overline{\operatorname{Alt}}_{2n+2i+2j+1}^{\le k+m}} q^{|s|} \right) _{i,j=0}^{m-1}. \end{align*} $$

If $ k\rightarrow \infty $ in Corollary 8.6, we get (51).

9 Negative moments of Laurent biorthogonal polynomials

Recall that we have combinatorial reciprocity theorems for the number of Dyck paths of bounded height and for the number of Motzkin paths of bounded height. Therefore, it is natural to ask whether there is a reciprocity theorem for the number of Schröder paths of bounded height. In this section we study the negative version of the number of Schröder paths with bounded height and its connection with the negative moment of Laurent biorthogonal polynomials.

The Laurent biorthogonal polynomials $ (L_n(x))_{n\ge 0} $ can be defined by a three-term recurrence

(53) $$ \begin{align} L_{n+1}(x) = (x-b_n)L_n(x) -a_nx L_{n-1}(x),\quad n\ge0, \qquad L_{-1}(x)=0,L_0(x)=1, \end{align} $$

for some sequences $ \boldsymbol {b}=(b_n)_{n\ge 0} $ and $ \boldsymbol {a}=(a_n)_{n\ge 1} $ . To emphasize sequences $ \boldsymbol {b} $ and $ \boldsymbol {a} $ we will write the polynomials $ L_n(x) $ as $ L_n(x;\boldsymbol {b},\boldsymbol {a}) $ . There is a unique linear functional $ \mathcal {L} $ on the space of Laurent polynomials such that $ \mathcal {L}(1)=1 $ and

$$\begin{align*}\mathcal{L}\left(L_m(x;\boldsymbol{b},\boldsymbol{a})\cdot \frac{L_n(x;\boldsymbol{b},\boldsymbol{a})}{x^n}\right) = 0, \qquad 0\le m< n. \end{align*}$$

Since the linear functional $ \mathcal {L} $ is defined on the space of Laurent polynomials, we have positive moments $ \mathcal {L}(x^n) $ and negative moments $ \mathcal {L}(x^{-n}) $ . Kamioka [Reference Kamioka10, Reference Kamioka11] showed that both positive and negative moments are generating functions for Schröder paths. To state Kamioka’s results, we need the following definitions.

Recall that a lattice path is a finite sequence of points in $ \mathbb {Z}\times \mathbb {Z}_{\ge 0}$ .

Definition 9.1. A Schröder path is a lattice path in which every step is an up step $(1,1)$ , a double-horizontal step $(2,0)$ or a down step $ (1,-1) $ . The set of Schröder paths from $ (0,0) $ to $ (n,0) $ is denoted by $ \operatorname {Sch}_n $ .

For given sequences $ \boldsymbol {b}=(b_0,b_1,\dots ) $ and $ \boldsymbol {a}=(a_1,a_2,\dots ) $ , the weight $ \operatorname {wt}(\pi ;\boldsymbol {b},\boldsymbol {a}) $ of a Schröder path $ \pi $ is defined to be the product of $ b_i $ for each double-horizontal step starting at a point with $ y $ -coordinate $ i $ and $ a_i $ for each down step starting at a point with $ y $ -coordinate $ i $ .

Kamioka [Reference Kamioka10, Reference Kamioka11] showed that the moments $ \mathcal {L}(x^n) $ , $ n\in \mathbb {Z} $ , of Laurent biorthogonal polynomials $ L_n(x;\boldsymbol {b},\boldsymbol {a}) $ are generating functions for Schröder paths. For $ n\ge 0 $ ,

(54) $$ \begin{align} \mathcal{L}(x^{n}) &= \sum_{\pi\in\operatorname{Sch}_{2n}} \operatorname{wt}(\pi;\boldsymbol{b},\boldsymbol{a}), \end{align} $$
(55) $$ \begin{align} \mathcal{L}(x^{-n-1}) &= b_0^{-1} \sum_{\pi\in\operatorname{Sch}_{2n}} \operatorname{wt}(\pi;\boldsymbol{b}',\boldsymbol{a}'), \end{align} $$

where $ \boldsymbol {b}' $ and $ \boldsymbol {a}' $ are the sequences defined by

(56) $$ \begin{align} \boldsymbol{b}' & =(b^{\prime}_i)_{i\ge0}, \qquad b^{\prime}_i=b_i^{-1}, \end{align} $$
(57) $$ \begin{align} \boldsymbol{a}'&=(a^{\prime}_i)_{i\ge1} , \qquad a^{\prime}_i = a_ib_{i-1}^{-1}b_{i}^{-1}. \end{align} $$

Definition 9.2. We define the bounded moment $ \sigma _n^{\le k }(\boldsymbol {b},\boldsymbol {a}) $ of the Laurent biorthogonal polynomials $ L_n(x;\boldsymbol {b},\boldsymbol {a}) $ by

$$\begin{align*}\sigma_n^{\le k }(\boldsymbol{b},\boldsymbol{a})= \sum_{\pi\in\operatorname{Sch}_{2n}^{\le k}} \operatorname{wt}(\pi;\boldsymbol{b},\boldsymbol{a}), \end{align*}$$

where $ \operatorname {Sch}_{2n}^{\le k} $ is the set of Schröder paths from $ (0,0) $ to $ (2n,0) $ that stay weakly below the line $ y=k $ .

Note that if the sequence $ (\sigma _n^{\le k }(\boldsymbol {b},\boldsymbol {a}))_{n\ge 0} $ satisfies a homogeneous linear recurrence relation, then its negative version $ (\sigma _{-n}^{\le k }(\boldsymbol {b},\boldsymbol {a}))_{n\ge 1} $ is defined. By definition, we have

$$\begin{align*}\mathcal{L}(x^n) = \lim_{k\to\infty} \sigma_n^{\le k }(\boldsymbol{b},\boldsymbol{a}), \qquad n\ge0. \end{align*}$$

The goal of this section is to prove that the negative moment $ \mathcal {L}(x^{-n}) $ is also the limit of the negative version of $ (\sigma _n^{\le k }(\boldsymbol {b},\boldsymbol {a}))_{n\ge 0} $ .

By specializing the results of Kim and Stanton [Reference Kim and Stanton12, Corollary 5.4 and Propositions 5.5] on orthogonal polynomials of type $ R_I $ , we obtain the following.

Proposition 9.3. We have

$$ \begin{align*} \sum_{n\ge0} \sigma_{n}^{\le k}(\boldsymbol{b},\boldsymbol{a}) x^n =\frac{\delta P^*_{k}(x;\boldsymbol{b},\boldsymbol{a})}{P^*_{k+1}(x;\boldsymbol{b},\boldsymbol{a})} =\cfrac{1}{ 1-b_0x- \cfrac{a_1x}{ 1-b_1x- \cfrac{a_2x}{ 1-b_2x- \genfrac{}{}{0pt}{1}{}{\displaystyle\ddots - \cfrac{a_kx}{1-b_k x}}} }}, \end{align*} $$

where $ \delta P^*_{k}(x;\boldsymbol {b},\boldsymbol {a}) $ and $ P^*_{k+1}(x;\boldsymbol {b},\boldsymbol {a})$ are defined similarly as in Definition 2.3.

The following proposition can be proved similarly as Propositions 2.10 and 2.11.

Proposition 9.4. If $ P_{k+1}(0;\boldsymbol {b},\boldsymbol {a})\ne 0 $ , then $ \sigma _{-n}^{\le k}(\boldsymbol {b},\boldsymbol {a}) $ is well-defined for $ n\ge 1 $ . In particular, if $ b_i\ne 0 $ for all $ i\ge 0 $ , then $ \sigma _{-n}^{\le k}(\boldsymbol {b},\boldsymbol {a}) $ is well-defined for $ n\ge 1 $ .

By the same argument as the one in the proof of Proposition 2.7, we obtain the generating function for $ \sigma ^{\le k}_{-n}(\boldsymbol {b},\boldsymbol {a})$ as follows.

Proposition 9.5. If $ (\sigma _{-n}^{\le k}(\boldsymbol {b},\boldsymbol {a}))_{n\ge 1} $ is defined, we have

$$ \begin{align*} \sum_{n\ge1} \sigma_{-n}^{\le k}(\boldsymbol{b},\boldsymbol{a}) x^n =-\frac{x \delta P_{k}(x;\boldsymbol{b},\boldsymbol{a})}{P_{k+1}(x;\boldsymbol{b},\boldsymbol{a})} =\cfrac{x}{ b_0-x- \cfrac{a_1x}{ b_1-x- \cfrac{a_2x}{ b_2-x- \genfrac{}{}{0pt}{1}{}{\displaystyle\ddots - \cfrac{a_kx}{b_k-x}}} }}. \end{align*} $$

Using Proposition 9.5, we can find a combinatorial interpretation for $ \sigma ^{\le k}_{-n}(\boldsymbol {b},\boldsymbol {a}) $ .

Theorem 9.6. Let $ n, k $ be positive integers. We have

$$\begin{align*}\sigma^{\le k}_{-n}(\boldsymbol{b},\boldsymbol{a}) = b^{-1}_0 \sum_{\pi\in \operatorname{Sch}^{\le k}_{n-1}} \operatorname{wt}(\pi;\boldsymbol{b}',\boldsymbol{a}'), \end{align*}$$

where $ \boldsymbol {b}' $ and $ \boldsymbol {a}' $ are defined in (56) and (57).

Proof. Let

$$\begin{align*}f^{\le k}_n=\sum_{\pi\in \operatorname{Sch}^{\le k}_{n}} \operatorname{wt}(\pi;\boldsymbol{b}',\boldsymbol{a}'). \end{align*}$$

By Proposition 9.3, we have

$$ \begin{align*} \sum_{n\ge0} f_{n}^{\le k} x^n &=\cfrac{1}{ 1-b^{-1}_0x- \cfrac{a_1 b^{-1}_0 b^{-1}_1 x}{ 1-b^{-1}_1x- \cfrac{a_2 b^{-1}_1 b^{-1}_2 x}{ 1-b^{-1}_2x- \genfrac{}{}{0pt}{1}{}{\displaystyle\ddots - \cfrac{a_k b^{-1}_{k-1} b^{-1}_k x}{1-b^{-1}_k x}}} }} \\ &=\cfrac{b_0}{ b_0-x- \cfrac{a_1x}{ b_1-x- \cfrac{a_2x}{ b_2-x- \genfrac{}{}{0pt}{1}{}{\displaystyle\ddots - \cfrac{a_kx}{b_k-x}}} }}. \end{align*} $$

Comparing this with Proposition 9.5, we obtain

$$\begin{align*}\sum_{n\ge1} \sigma_{-n}^{\le k}(\boldsymbol{b},\boldsymbol{a}) x^n =b^{-1}_0 x \sum_{n\ge0} f_{n}^{\le k} x^n =\sum_{n\ge 1} b^{-1}_0 f^{\le k}_{n-1} x^n. \end{align*}$$

Therefore, $ \sigma _{-n}^{\le k}(\boldsymbol {b},\boldsymbol {a}) = b^{-1}_0 f^{\le k}_{n-1} $ , which is the desired result.

Substituting $ \boldsymbol {b}=\boldsymbol {a}=\boldsymbol {1} $ in Theorem 9.6, we see that the negative version of the number of bounded Schröder paths is also the number of bounded Schröder paths.

Corollary 9.7. Let $ s_n=|\operatorname {Sch}_n^{\le k}| $ for $ n\ge 0 $ . Then for $ n\ge 1 $ , we have $ s_{-n}=s_{n-1} $ .

By Theorem 9.6 and (55), we obtain that the negative moments $ \mathcal {L}(x^{-n}) $ are the limits of the negative versions $ \sigma _{-n}^{\le k }(\boldsymbol {b},\boldsymbol {a}) $ of the bounded moments $ \sigma _{n}^{\le k }(\boldsymbol {b},\boldsymbol {a})$ .

Corollary 9.8. For $n \ge 1$ ,

$$\begin{align*}\mathcal{L}(x^{-n}) = \lim_{k\to\infty} \sigma_{-n+1}^{\le k }(\boldsymbol{b},\boldsymbol{a}). \end{align*}$$

Acknowledgements

The authors would like to thank the anonymous referees for helpful comments.

Competing interest

The authors have no competing interests to declare.

Financial support

All authors were supported by NRF grant #2016R1A5A1008055. JihyeugJang, Jang Soo Kim and U-Keun Song were supported by NRF grant#2022R1A2C101100911. Donghyun Kim was supported by NRF grant #2022R1I1A1A01070260. Minho Song was supported by NRF grant #2022R1C1C2009025.

Footnotes

1 In this paper, we only consider the ‘formal’ orthogonality in the sense that we do not require the positive-definiteness of the linear functional $ \mathcal {L} $ , which is often assumed in the literature on orthogonal polynomials.

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