Whitney Numbers for Poset Cones

Galen Dorpalen-Barry; Jang Soo Kim; Victor Reiner

doi:10.1007/s11083-020-09541-4

Whitney Numbers for Poset Cones

Galen Dorpalen-Barry, Jang Soo Kim, Victor Reiner

Mathematics

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5 Scopus citations

Abstract

Hyperplane arrangements dissect ℝⁿ into connected components called chambers, and a well-known theorem of Zaslavsky counts chambers as a sum of nonnegative integers called Whitney numbers of the first kind. His theorem generalizes to count chambers within any cone defined as the intersection of a collection of halfspaces from the arrangement, leading to a notion of Whitney numbers for each cone. This paper focuses on cones within the braid arrangement, consisting of the reflecting hyperplanes x_i = x_j inside ℝⁿ for the symmetric group, thought of as the type A_{n− 1} reflection group. Here, cones correspond to posets,chambers within the cone correspond to linear extensions of the poset,the Whitney numbers of the cone interestingly refine the number of linear extensions of the poset. We interpret this refinement for all posets as counting linear extensions according to a statistic that generalizes the number of left-to-right maxima of a permutation. When the poset is a disjoint union of chains, we interpret this refinement differently, using Foata’s theory of cycle decomposition for multiset permutations, leading to a simple generating function compiling these Whitney numbers.

Original language	English (US)
Pages (from-to)	283-322
Number of pages	40
Journal	Order
Volume	38
Issue number	2
DOIs	https://doi.org/10.1007/s11083-020-09541-4
State	Published - Jul 2021

Bibliographical note

Funding Information:
The first and third authors were partially supported by NSF grant DMS-1601961. The second author was supported by NRF grants #2019R1F1A1059081 and #2016R1A5A1008055. Acknowledgements

Funding Information:
The authors gratefully acknowledge Dennis Stanton for conversations about MacMahon’s Master Theorem, as well as Anders Björner, Jesus DeLoera, Theo Douvropoulos, Michael Falk, Ira Gessel, Benjamin Steinberg, Volkmar Welker, Chi-Ho Yuen for enlightening discussions and references. They thank Philip Zhang for asking them questions about real-rootedness at the 2019 Mid-Atlantic Algebra, Geometry, and Combinatorics Workshop. Finally, the authors thank an anonymous referee for helpful comments.

Publisher Copyright:
© 2021, Springer Nature B.V.

Keywords

Arrangement
Catalan
Cone
Foata
Hyperplane
Multiset
Permutation
Poset
Stirling
Whitney

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abstract = "Hyperplane arrangements dissect ℝn into connected components called chambers, and a well-known theorem of Zaslavsky counts chambers as a sum of nonnegative integers called Whitney numbers of the first kind. His theorem generalizes to count chambers within any cone defined as the intersection of a collection of halfspaces from the arrangement, leading to a notion of Whitney numbers for each cone. This paper focuses on cones within the braid arrangement, consisting of the reflecting hyperplanes xi = xj inside ℝn for the symmetric group, thought of as the type An− 1 reflection group. Here, cones correspond to posets,chambers within the cone correspond to linear extensions of the poset,the Whitney numbers of the cone interestingly refine the number of linear extensions of the poset. We interpret this refinement for all posets as counting linear extensions according to a statistic that generalizes the number of left-to-right maxima of a permutation. When the poset is a disjoint union of chains, we interpret this refinement differently, using Foata{\textquoteright}s theory of cycle decomposition for multiset permutations, leading to a simple generating function compiling these Whitney numbers.",

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author = "Galen Dorpalen-Barry and Kim, {Jang Soo} and Victor Reiner",

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Whitney Numbers for Poset Cones

Abstract

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Keywords

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