Counting tight Hamilton cycles in Dirac hypergraphs

Abstract

Suppose G is a k-uniform hypergraph on n vertices such that every (k-1)-subset S of V(G) belongs to at least δ n edges, where δ> 1/2. Let (G) denote the number of tight Hamilton cycles in G, that is, cyclic orderings of V(G) in which every k consecutive vertices form an edge. We prove that (G) kh(G)-nn k-1+n n-n e-o(n), where h(G) is the hypergraph entropy of G, defined via perfect fractional matchings. This bound is tight, for example, for all (nearly) regular hypergraphs, in particular for the binomial random hypergraph. It also implies a conjecture by Ferber, Hardiman and Mond, stating that (G) (δ-o(1))n n!.