DP-Colorings of Hypergraphs

Abstract

Classical problems in hypergraph coloring theory are to estimate the minimum number of edges, m2(r) (respectively, m2(r)), in a non-2-colorable r-uniform (respectively, r-uniform and simple) hypergraph. The best currently known bounds are \[c · r/ r · 2r \,≤slant\, m2(r) \,≤slant\, C · r2 · 2r and c' · r- · 4r \,≤slant\, m2(r) \,≤slant\, C' · r4 · 4r,\] for any fixed > 0 and some c, c', C, C' > 0 (where c' may depend on ). In this paper we consider the same problems in the context of DP-coloring (also known as correspondence coloring), which is a generalization of list coloring introduced by Dvor\'ak and Postle and related to local conflict coloring studied independently by Fraigniaud, Heinrich, and Kosowski. Let m2(r) (respectively, m2(r)) denote the minimum number of edges in a non-2-DP-colorable r-uniform (respectively, r-uniform and simple) hypergraph. By definition, m2(r) ≤slant m2(r) and m2(r)≤slant m2(r). While the proof of the bound m2(r) = ( r-3 4r) due to Erdos and Lov\'asz also works for m2(r), we show that the trivial lower bound m2(r) ≥slant 2r-1 is asymptotically tight, i.e., m2(r) ≤slant (1 + o(1))2r-1. On the other hand, when r ≥slant 2 is even, we prove that the lower bound m2(r) ≥slant 2r-1 is not sharp, i.e., m2(r) ≥slant 2r-1+1. Whether this result holds for any odd values of r remains an open problem. Nevertheless, we conjecture that the difference m2(r) - 2r-1 can be arbitrarily large.