Colour-biased Hamilton cycles in dense graphs and random graphs

Abstract

A classical result of Dirac says that every n-vertex graph with minimum degree at least n2 contains a Hamilton cycle. A `discrepancy' version of Dirac's theorem was shown by Balogh--Csaba--Jing--Pluh\'ar, Freschi--Hyde--Lada--Treglown, and Gishboliner--Krivelevich--Michaeli as follows. Every r-colouring of the edge set of every n-vertex graph with minimum degree at least (12 + 12r + o(1))n contains a Hamilton cycle where one of the colours appears at least (1+o(1))nr times. In this paper, we generalize this result by asymptotically determining the maximum possible value fr,α(n) for every α ∈ [12, 1] such that every r-colouring of the edge set of every n-vertex graph with minimum degree at least α n contains a Hamilton cycle where one of the colours appears at least fr,α(n) times. In particular, we show that fr,α(n) = (1-o(1)) \(2α - 1)n, 2α nr, 2nr+1\ for every α∈ [12 + 12r, 1]. A graph H is called an α-residual subgraph of a graph G if dH(v) α dG[V(H)](v) for every v∈ V(H). Extending Dirac's theorem in the setting of random graphs, Lee and Sudakov showed the following. The Erdos--R\'enyi random graph G(n,p), with p above the Hamiltonicity threshold, typically has the property that every (12 +o(1))-residual spanning subgraph contains a Hamilton cycle. Motivated by this, we prove the following random version of our `discrepancy' result. The random graph G G(n,p), with p above the Hamiltonicity threshold, typically satisfies that every r-colouring of the edge set of every α-residual spanning subgraph of G contains a Hamilton cycle where one of the colours appears at least fr,α(n) times.