Compatible Hamilton cycles in random graphs
Abstract
A graph is Hamiltonian if it contains a cycle passing through every vertex. One of the cornerstone results in the theory of random graphs asserts that for edge probability , the random graph is asymptotically almost surely Hamiltonian. We obtain the following strengthening of this result. Given a graph , an {\em incompatibility system} over is a family where for every , the set is a set of unordered pairs . An incompatibility system is {\em -bounded} if for every vertex and an edge incident to , there are at most pairs in containing . We say that a cycle in is {\em compatible} with if every pair of incident edges of satisfies . This notion is partly motivated by a concept of transition systems defined by Kotzig in 1968, and can be used as a quantitative measure of robustness of graph properties. We prove that there is a constant such that the random graph with is asymptotically almost surely such that for any -bounded incompatibility system over , there is a Hamilton cycle in compatible with . We also prove that for larger edge probabilities , the parameter can be taken to be any constant smaller than . These results imply in particular that typically in for , for any edge-coloring in which each color appears at most times at each vertex, there exists a properly colored Hamilton cycle.
Cite
@article{arxiv.1410.1438,
title = {Compatible Hamilton cycles in random graphs},
author = {Michael Krivelevich and Choongbum Lee and Benny Sudakov},
journal= {arXiv preprint arXiv:1410.1438},
year = {2015}
}