A Dirac-type theorem for Berge cycles in random hypergraphs

Abstract

A Hamilton Berge cycle of a hypergraph on n vertices is an alternating sequence (v1, e1, v2, …, vn, en) of distinct vertices v1, …, vn and distinct hyperedges e1, …, en such that \v1,vn\⊂eq en and \vi, vi+1\ ⊂eq ei for every i∈ [n-1]. We prove the following Dirac-type theorem about Berge cycles in the binomial random r-uniform hypergraph H(r)(n,p): for every integer r ≥ 3, every real γ>0 and p ≥ 17r nnr-1 asymptotically almost surely, every spanning subgraph H ⊂eq H(r)(n,p) with minimum vertex degree δ1(H) ≥ (12r-1 + γ) p nr-1 contains a Hamilton Berge cycle. The minimum degree condition is asymptotically tight and the bound on p is optimal up to some polylogarithmic factor.