English

Almost all permutation matrices have bounded saturation functions

Combinatorics 2020-12-29 v1

Abstract

Saturation problems for forbidden graphs have been a popular area of research for many decades, and recently Brualdi and Cao initiated the study of a saturation problem for 0-1 matrices. We say that 0-1 matrix AA is saturating for the forbidden 0-1 matrix PP if AA avoids PP but changing any zero to a one in AA creates a copy of PP. Define sat(n,P)sat(n, P) to be the minimum possible number of ones in an n×nn \times n 0-1 matrix that is saturating for PP. Fulek and Keszegh proved that for every 0-1 matrix PP, either sat(n,P)=O(1)sat(n, P) = O(1) or sat(n,P)=Θ(n)sat(n, P) = \Theta(n). They found two 0-1 matrices PP for which sat(n,P)=O(1)sat(n, P) = O(1), as well as infinite families of 0-1 matrices PP for which sat(n,P)=Θ(n)sat(n, P) = \Theta(n). Their results imply that sat(n,P)=Θ(n)sat(n, P) = \Theta(n) for almost all k×kk \times k 0-1 matrices PP. Fulek and Keszegh conjectured that there are many more 0-1 matrices PP such that sat(n,P)=O(1)sat(n, P) = O(1) besides the ones they found, and they asked for a characterization of all permutation matrices PP such that sat(n,P)=O(1)sat(n, P) = O(1). We affirm their conjecture by proving that almost all k×kk \times k permutation matrices PP have sat(n,P)=O(1)sat(n, P) = O(1). We also make progress on the characterization problem, since our proof of the main result exhibits a family of permutation matrices with bounded saturation functions.

Keywords

Cite

@article{arxiv.2012.14150,
  title  = {Almost all permutation matrices have bounded saturation functions},
  author = {Jesse Geneson},
  journal= {arXiv preprint arXiv:2012.14150},
  year   = {2020}
}
R2 v1 2026-06-23T21:28:52.051Z