Matroid invariants and counting graph homomorphisms
Abstract
The number of homomorphisms from a finite graph to the complete graph is the evaluation of the chromatic polynomial of at . Suitably scaled, this is the Tutte polynomial evaluation and an invariant of the cycle matroid of . De la Harpe and Jaeger \cite{dlHJ95} asked more generally when is it the case that a graph parameter obtained from counting homomorphisms from to a fixed graph depends only on the cycle matroid of . They showed that this is true when has a generously transitive automorphism group (examples include Cayley graphs on an abelian group, and Kneser graphs). Using tools from multilinear algebra, we prove the converse statement, thus characterizing finite graphs for which counting homomorphisms to yields a matroid invariant. We also extend this result to finite weighted graphs (where to count homomorphisms from to includes such problems as counting nowhere-zero flows of and evaluating the partition function of an interaction model on ).
Cite
@article{arxiv.1512.01507,
title = {Matroid invariants and counting graph homomorphisms},
author = {Andrew Goodall and Guus Regts and Lluis Vena},
journal= {arXiv preprint arXiv:1512.01507},
year = {2016}
}
Comments
Section 2 is slightly updated. In particular, Theorem 2.1 has been improved and a short proof is supplied. Additionally, some typos have been fixed and some small changes have been made. All based on comments of a referee, Linear Algebra and its Applications 494, (2016)