Robust Hamiltonicity in families of Dirac graphs

Abstract

A graph is called Dirac if its minimum degree is at least half of the number of vertices in it. Joos and Kim showed that every collection G=\G1,…,Gn\ of Dirac graphs on the same vertex set V of size n contains a Hamilton cycle transversal, i.e., a Hamilton cycle H on V with a bijection φ:E(H)→ [n] such that e∈ Gφ(e) for every e∈ E(H). In this paper, we determine up to a multiplicative constant, the threshold for the existence of a Hamilton cycle transversal in a collection of random subgraphs of Dirac graphs in various settings. Our proofs rely on constructing a spread measure on the set of Hamilton cycle transversals of a family of Dirac graphs. As a corollary, we obtain that every collection of n Dirac graphs on n vertices contains at least (cn)2n different Hamilton cycle transversals (H,φ) for some absolute constant c>0. This is optimal up to the constant c. Finally, we show that if n is sufficiently large, then every such collection spans n/2 pairwise edge-disjoint Hamilton cycle transversals, and this is best possible. These statements generalize classical counting results of Hamilton cycles in a single Dirac graph.