English

Recognising Graphic and Matroidal Connectivity Functions

Combinatorics 2020-07-10 v1

Abstract

A {\em connectivity function} on a set EE is a function λ:2ER\lambda:2^E\rightarrow \mathbb R such that λ()=0\lambda(\emptyset)=0, that λ(X)=λ(EX)\lambda(X)=\lambda(E-X) for all XEX\subseteq E, and that λ(XY)+λ(XY)λ(X)+λ(Y)\lambda(X\cap Y)+\lambda(X\cup Y)\leq \lambda(X)+\lambda(Y) for all X,YEX,Y \subseteq E. Graphs, matroids and, more generally, polymatroids have associated connectivity functions. In this paper we give a method for identifying when a connectivity function comes from a graph. This method uses no more than a polynomial number of evaluations of the connectivity function. In contrast, we show that the problem of identifying when a connectivity function comes from a matroid cannot be solved in polynomial time. We also show that the problem of identifying when a connectivity function is not that of a matroid cannot be solved in polynomial time.

Keywords

Cite

@article{arxiv.2007.04469,
  title  = {Recognising Graphic and Matroidal Connectivity Functions},
  author = {Nathan Bowler and Susan Jowett},
  journal= {arXiv preprint arXiv:2007.04469},
  year   = {2020}
}
R2 v1 2026-06-23T16:58:07.923Z