Polynomial graph invariants from homomorphism numbers

Abstract

We give a method of generating strongly polynomial sequences of graphs, i.e., sequences (Hk) indexed by a multivariate parameter k=(k1,…, kh) such that, for each fixed graph G, there is a multivariate polynomial p(G;x1,…, xh) such that the number of homomorphisms from G to Hk is given by the evaluation p(G;k1,…, kh). A classical example is the sequence (Kk) of complete graphs, for which hom(G,Kk)=P(G;k) is the evaluation of the chromatic polynomial at k. Our construction produces a large family of graph polynomials that includes the Tutte polynomial, the Averbouch-Godlin-Makowsky polynomial and the Tittmann-Averbouch-Makowsky polynomial. We also introduce a new graph parameter, the branching core size of a simple graph, related to how many involutive automorphisms with fixed points it has. We prove that a countable family of graphs of bounded branching core size (which in particular implies bounded tree-depth) is always contained in a finite union of strongly polynomial sequences.