English

Powerful sets: a generalisation of binary matroids

Combinatorics 2017-05-23 v1

Abstract

A set S{0,1}ES\subseteq\{0,1\}^E of binary vectors, with positions indexed by EE, is said to be a \textit{powerful code} if, for all XEX\subseteq E, the number of vectors in SS that are zero in the positions indexed by XX is a power of 2. By treating binary vectors as characteristic vectors of subsets of EE, we say that a set S2ES\subseteq2^E of subsets of EE is a \textit{powerful set} if the set of characteristic vectors of sets in SS is a powerful code. Powerful sets (codes) include cocircuit spaces of binary matroids (equivalently, linear codes over F2\mathbb{F}_2), but much more besides. Our motivation is that, to each powerful set, there is an associated nonnegative-integer-valued rank function (by a construction of Farr), although it does not in general satisfy all the matroid rank axioms. In this paper we investigate the combinatorial properties of powerful sets. We prove fundamental results on special elements (loops, coloops, frames, near-frames, and stars), their associated types of single-element extensions, various ways of combining powerful sets to get new ones, and constructions of nonlinear powerful sets. We show that every powerful set is determined by its clutter of minimal nonzero members. Finally, we show that the number of powerful sets is doubly exponential, and hence that almost all powerful sets are nonlinear.

Keywords

Cite

@article{arxiv.1705.07437,
  title  = {Powerful sets: a generalisation of binary matroids},
  author = {Graham E. Farr and Andrew Y. Z. Wang},
  journal= {arXiv preprint arXiv:1705.07437},
  year   = {2017}
}

Comments

19 pages. This work was presented at the 40th Australasian Conference on Combinatorial Mathematics and Combinatorial Computing (40ACCMCC), University of Newcastle, Australia, Dec. 2016

R2 v1 2026-06-22T19:53:49.367Z