Graph Homomorphisms via Vector Colorings

Abstract

In this paper we study the existence of homomorphisms G H using semidefinite programming. Specifically, we use the vector chromatic number of a graph, defined as the smallest real number t 2 for which there exists an assignment of unit vectors i pi to its vertices such that pi, pj -1/(t-1), when i j. Our approach allows to reprove, without using the Erdos-Ko-Rado Theorem, that for n>2r the Kneser graph Kn:r and the q-Kneser graph qKn:r are cores, and furthermore, that for n/r = n'/r' there exists a homomorphism Kn:r Kn':r' if and only if n divides n'. In terms of new applications, we show that the even-weight component of the distance k-graph of the n-cube Hn,k is a core and also, that non-bipartite Taylor graphs are cores. Additionally, we give a necessary and sufficient condition for the existence of homomorphisms Hn,k Hn',k' when n/k = n'/k'. Lastly, we show that if a 2-walk-regular graph (which is non-bipartite and not complete multipartite) has a unique optimal vector coloring, it is a core. Based on this sufficient condition we conducted a computational study on Ted Spence's list of strongly regular graphs and found that at least 84% are cores.