Local resilience and Hamiltonicity Maker-Breaker games in random-regular graphs

Abstract

For an increasing monotone graph property the local resilience of a graph G with respect to is the minimal r for which there exists of a subgraph H⊂eq G with all degrees at most r such that the removal of the edges of H from G creates a graph that does not possesses . This notion, which was implicitly studied for some ad-hoc properties, was recently treated in a more systematic way in a paper by Sudakov and Vu. Most research conducted with respect to this distance notion focused on the Binomial random graph model and some families of pseudo-random graphs with respect to several graph properties such as containing a perfect matching and being Hamiltonian, to name a few. In this paper we continue to explore the local resilience notion, but turn our attention to random and pseudo-random regular graphs of constant degree. We investigate the local resilience of the typical random d-regular graph with respect to edge and vertex connectivity, containing a perfect matching, and being Hamiltonian. In particular we prove that for every positive ε and large enough values of d with high probability the local resilience of the random d-regular graph, , with respect to being Hamiltonian is at least (1-ε)d/6. We also prove that for the Binomial random graph model , for every positive ε>0 and large enough values of K, if p>K nn then with high probability the local resilience of with respect to being Hamiltonian is at least (1-ε)np/6. Finally, we apply similar techniques to Positional Games and prove that if d is large enough then with high probability a typical random d-regular graph G is such that in the unbiased Maker-Breaker game played on the edges of G, Maker has a winning strategy to create a Hamilton cycle.