Vector Coloring the Categorical Product of Graphs

Abstract

A vector t-coloring of a graph is an assignment of real vectors p1, …, pn to its vertices such that piTpi = t-1 for all i=1, …, n and piTpj -1 whenever i and j are adjacent. The vector chromatic number of G is the smallest real number t 1 for which a vector t-coloring of G exists. For a graph H and a vector t-coloring p1,…,pn of a graph G, the assignment (i,) pi is a vector t-coloring of the categorical product G × H. It follows that the vector chromatic number of G × H is at most the minimum of the vector chromatic numbers of the factors. We prove that equality always holds, constituting a vector coloring analog of the famous Hedetniemi Conjecture from graph coloring. Furthermore, we prove a necessary and sufficient condition for when all of the optimal vector colorings of the product can be expressed in terms of the optimal vector colorings of the factors. The vector chromatic number is closely related to the well-known Lov\'asz theta function, and both of these parameters admit formulations as semidefinite programs. This connection to semidefinite programming is crucial to our work and the tools and techniques we develop could likely be of interest to others in this field.