Ample sets in Cartesian products

Abstract

Ample sets of hypercubes, introduced by A. Dress in 1995, constitute a combinatorial structure with rich properties and important examples. Ample sets can be characterized in a multitude of combinatorial, graph-theoretical, recursive, and geometrical ways, and they are equivalent to lopsided sets introduced by J. Lawrence in 1983. In this paper, we define and investigate ample sets of Cartesian products U=U1×·s× Um. This is done using minor-subproducts of U, which correspond to products of partitions of factors: each minor-subproduct is obtained by partitioning each Ui into blocks and contracting blocks into singletons. For a minor-subproduct M and a set S, we define the notions of shattering of M by S, of copy of M in S, of projection SM of S on M, and of strong-projection SM of S on M. We call a set S ample if for any minor-subproduct M that is shattered by S, there exists a copy of M included in S. We prove that several characterizations of ample sets can be extended to ample sets of Cartesian products. In particular, we show that ampleness of S is equivalent to the ampleness of the complement S*, to superisometricity (isometricity of SM for any minor-subproduct M), and commutativity (SM)M'=(SM')M for all minor-subproducts M,M' with disjoint supports. We also provide more efficient characterizations of ampleness, in particular, by showing that S is ample iff S is isometric and both Se and Se are ample for some elementary minor-subproduct, iff the intersection of S with any interval [u,v] with u,v in S is ample in the classical sense. We characterize ampleness by push downs and provide a decomposition theorem, allowing us to prove that their prism complexes are contractible. We provide new examples of ample sets arising from payoff games, prism-like polyhedra, and quasi-median graphs.

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