English

Inverting sets and the packing problem

Combinatorics 2016-09-06 v1

Abstract

Given a set VV, a subset SS, and a permutation π\pi of VV, we say that π\pi permutes SS if π(S)S=\pi (S) \cap S = \emptyset. Given a collection \cS={V;S1,,Sm}\cS = \{V; S_1,\ldots , S_m\}, where SiV  (i=1,,m)S_i \subseteq V ~~(i=1,\ldots ,m), we say that \cS\cS is invertible if there is a permutation π\pi of VV such that π(Si)VSi\pi (S_i) \subseteq V-S_i. In this paper, we present necessary and sufficient conditions for the invertibility of a collection and construct a polynomial algorithm which determines whether a given collection is invertible. For an arbitrary collection, we give a lower bound for the maximum number of sets that can be inverted. Finally, we consider the problem of constructing a collection of sets such that no sub-collection of size three is invertible. Our constructions of such collections come from solutions to the packing problem with unbounded block sizes. We prove several new lower and upper bounds for the packing problem and present a new explicit construction of packing.

Keywords

Cite

@article{arxiv.math/9409213,
  title  = {Inverting sets and the packing problem},
  author = {Vance Faber and Mark Goldberg and Emanuel Knill and Thomas Spencer},
  journal= {arXiv preprint arXiv:math/9409213},
  year   = {2016}
}

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16 pages