Vertex covering with monochromatic pieces of few colours

Abstract

In 1995, Erdos and Gy\'arf\'as proved that in every 2-colouring of the edges of Kn, there is a vertex cover by 2n monochromatic paths of the same colour, which is optimal up to a constant factor. The main goal of this paper is to study the natural multi-colour generalization of this problem: given two positive integers r,s, what is the smallest number pcr,s(Kn) such that in every colouring of the edges of Kn with r colours, there exists a vertex cover of Kn by pcr,s(Kn) monochromatic paths using altogether at most s different colours? For fixed integers r>s and as n∞, we prove that pcr,s(Kn) = (n1/), where =\1,2+2s-r\ is the chromatic number of the Kneser gr aph KG(r,r-s). More generally, if one replaces Kn by an arbitrary n-vertex graph with fixed independence number α, then we have pcr,s(G) = O(n1/), where this time around is the chromatic number of the Kneser hypergraph KG(α+1)(r,r-s). This result is tight in the sense that there exist graphs with independence number α for which pcr,s(G) = (n1/). This is in sharp contrast to the case r=s, where it follows from a result of S\'ark\"ozy (2012) that pcr,r(G) depends only on r and α, but not on the number of vertices. We obtain similar results for the situation where instead of using paths, one wants to cover a graph with bounded independence number by monochromatic cycles, or a complete graph by monochromatic d-regular graphs.