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A new family of generalized Stirling and Bell numbers is introduced by considering powers $(VU)^n$ of the noncommuting variables $U,V$ satisfying $UV=VU+hV^s$. The case $s=0$ (and $h=1$) corresponds to the conventional Stirling numbers of second kind and Bell numbers. For these generalized Stirling numbers, the recursion relation is given and explicit expressions are derived. Furthermore, they are shown to be connection coefficients and a combinatorial interpretation in terms of statistics is given. It is also shown that these Stirling numbers can be interpreted as $s$-rook numbers introduced by Goldman and Haglund. For the associated generalized Bell numbers, the recursion relation as well as a closed form for the exponential generating function is derived. Furthermore, an analogue of Dobinski's formula is given for these Bell numbers.

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Eulerian polynomials via the Weyl algebra action

Journal of Algebraic Combinatorics ◽

10.1007/s10801-020-00997-6 ◽

2020 ◽

Author(s):

Jose Agapito ◽

Pasquale Petrullo ◽

Domenico Senato ◽

Maria M. Torres

Keyword(s):

Young Diagram ◽

Weyl Algebra ◽

Geometric Series ◽

Exponential Series ◽

Derivative Operator ◽

Eulerian Polynomials ◽

Combinatorial Description ◽

Rook Numbers

AbstractThrough the action of the Weyl algebra on the geometric series, we establish a generalization of the Worpitzky identity and new recursive formulae for a family of polynomials including the classical Eulerian polynomials. We obtain an extension of the Dobiński formula for the sum of rook numbers of a Young diagram by replacing the geometric series with the exponential series. Also, by replacing the derivative operator with the q-derivative operator, we extend these results to the q-analogue setting including the q-hit numbers. Finally, a combinatorial description and a proof of the symmetry of a family of polynomials introduced by one of the authors are provided.

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Bijections on m-level Rook Placements

Discrete Mathematics & Theoretical Computer Science ◽

10.46298/dmtcs.2430 ◽

2014 ◽

Vol DMTCS Proceedings vol. AT,... (Proceedings) ◽

Author(s):

Kenneth Barrese ◽

Bruce Sagan

Keyword(s):

Special Class ◽

Symmetric Functions ◽

Elementary Symmetric Functions ◽

Rook Placements ◽

Rook Numbers ◽

Ferrers Board ◽

International Audience ◽

Ferrers Boards

International audience Partition the rows of a board into sets of $m$ rows called levels. An $m$-level rook placement is a subset of squares of the board with no two in the same column or the same level. We construct explicit bijections to prove three theorems about such placements. We start with two bijections between Ferrers boards having the same number of $m$-level rook placements. The first generalizes a map by Foata and Schützenberger and our proof applies to any Ferrers board. The second generalizes work of Loehr and Remmel. This construction only works for a special class of Ferrers boards but also yields a formula for calculating the rook numbers of these boards in terms of elementary symmetric functions. Finally we generalize another result of Loehr and Remmel giving a bijection between boards with the same hit numbers. The second and third bijections involve the Involution Principle of Garsia and Milne. Nous considérons les rangs d’un échiquier partagés en ensembles de $m$ rangs appelés les niveaux. Un $m$-placement des tours est un sous-ensemble des carrés du plateau tel qu’il n’y a pas deux carrés dans la même colonne ou dans le même niveau. Nous construisons deux bijections explicites entre des plateaux de Ferrers ayant les mêmes nombres de $m$-placements. La première est une généralisation d’une fonction de Foata et Schützenberger et notre démonstration est pour n’importe quels plateaux de Ferrers. La deuxième généralise une bijection de Loehr et Remmel. Cette construction marche seulement pour des plateaux particuliers, mais ça donne une formule pour le nombre de $m$-placements en terme des fonctions symétriques élémentaires. Enfin, nous généralisons un autre résultat de Loehr et Remmel donnant une bijection entre deux plateaux ayant les mêmes nombres de coups. Les deux dernières bijections utilisent le Principe des Involutions de Garsia et Milne.

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Elliptic Rook and File Numbers

The Electronic Journal of Combinatorics ◽

10.37236/6121 ◽

2017 ◽

Vol 24 (1) ◽

Cited By ~ 3

Author(s):

Michael J. Schlosser ◽

Meesue Yoo

Keyword(s):

Stirling Numbers ◽

Classical Case ◽

Factorization Theorem ◽

Rook Numbers ◽

Generalized Stirling Numbers ◽

Independent Parameters ◽

Ferrers Boards

Utilizing elliptic weights, we construct an elliptic analogue of rook numbers for Ferrers boards. Our elliptic rook numbers generalize Garsia and Remmel's $q$-rook numbers by two additional independent parameters $a$ and $b$, and a nome $p$. The elliptic rook numbers are shown to satisfy an elliptic extension of a factorization theorem which in the classical case was established by Goldman, Joichi and White and extended to the $q$-case by Garsia and Remmel. We obtain similar results for elliptic analogues of Garsia and Remmel's $q$-file numbers for skyline boards. We also provide an elliptic extension of the $j$-attacking model introduced by Remmel and Wachs. Various applications of our results include elliptic analogues of (generalized) Stirling numbers of the first and second kind, Lah numbers, Abel numbers, and $r$-restricted versions thereof.

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A $p,q$-analogue of a Formula of Frobenius

The Electronic Journal of Combinatorics ◽

10.37236/1702 ◽

2003 ◽

Vol 10 (1) ◽

Cited By ~ 5

Author(s):

Karen S. Briggs ◽

Jeffrey B. Remmel

Keyword(s):

Stirling Numbers ◽

Combinatorial Interpretation ◽

Eulerian Polynomials ◽

Major Index ◽

Rook Placements ◽

Rook Numbers ◽

Nonnegative Coefficients ◽

Ferrers Boards

Garsia and Remmel (JCT. A 41 (1986), 246-275) used rook configurations to give a combinatorial interpretation to the $q$-analogue of a formula of Frobenius relating the Stirling numbers of the second kind to the Eulerian polynomials. Later, Remmel and Wachs defined generalized $p,q$-Stirling numbers of the first and second kind in terms of rook placements. Additionally, they extended their definition to give a $p,q$-analogue of rook numbers for arbitrary Ferrers boards. In this paper, we use Remmel and Wach's definition and an extension of Garsia and Remmel's proof to give a combinatorial interpretation to a $p,q$-analogue of a formula of Frobenius relating the $p,q$-Stirling numbers of the second kind to the trivariate distribution of the descent number, major index, and comajor index over $S_n$. We further define a $p,q$-analogue of the hit numbers, and show analytically that for Ferrers boards, the $p,q$-hit numbers are polynomials in $(p,q)$ with nonnegative coefficients.

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A Short Proof of the Rook Reciprocity Theorem

The Electronic Journal of Combinatorics ◽

10.37236/1234 ◽

1996 ◽

Vol 3 (1) ◽

Cited By ~ 3

Author(s):

Timothy Chow

Keyword(s):

Present Author ◽

Short Proof ◽

Reciprocity Theorem ◽

Combinatorial Proof ◽

Reciprocity Law ◽

Rook Numbers ◽

New Formula

Rook numbers of complementary boards are related by a reciprocity law. A complicated formula for this law has been known for about fifty years, but recently Gessel and the present author independently obtained a much more elegant formula, as a corollary of more general reciprocity theorems. Here, following a suggestion of Goldman, we provide a direct combinatorial proof of this new formula.

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Rook numbers and the normal ordering problem

Journal of Combinatorial Theory Series A ◽

10.1016/j.jcta.2005.07.012 ◽

2005 ◽

Vol 112 (2) ◽

pp. 292-307 ◽

Cited By ~ 30

Author(s):

Anna Varvak

Keyword(s):

Normal Ordering ◽

Rook Numbers

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Elliptic rook and file numbers

Discrete Mathematics & Theoretical Computer Science ◽

10.46298/dmtcs.6362 ◽

2020 ◽

Vol DMTCS Proceedings, 28th... ◽

Author(s):

Michael J. Schlosser ◽

Meesue Yoo

Keyword(s):

Stirling Numbers ◽

Classical Case ◽

Factorization Theorem ◽

Rook Numbers ◽

International Audience ◽

Number Case

International audience In this work, we construct elliptic analogues of the rook numbers and file numbers by attaching elliptic weights to the cells in a board. We show that our elliptic rook and file numbers satisfy elliptic extensions of corre- sponding factorization theorems which in the classical case were established by Goldman, Joichi and White and by Garsia and Remmel in the file number case. This factorization theorem can be used to define elliptic analogues of various kinds of Stirling numbers of the first and second kind as well as Abel numbers. We also give analogous results for matchings of graphs, elliptically extending the result of Haglund and Remmel.

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