Hamilton Cycles in a Class of Random Directed Graphs

## Abstract We study the resilience of random and pseudorandom directed graphs with respect to the property of having long directed cycles. For every 08γ81/2 we find a constant __c__ = __c__(γ) such that the following holds. Let __G__ = (__V, E__) be a (pseudo)random directed graph on __n__ vertice

Let G be chosen uniformly at random from the set G G r, n of r-regular graphs w x Ž . with vertex set n . We describe polynomial time algorithms that whp i find a Ž . Hamilton cycle in G, and ii approximately count the number of Hamilton cycles in G.

We consider the standard random geometric graph process in which n vertices are placed at random on the unit square and edges are sequentially added in increasing order of edge-length. For fixed k ≥ 1, we prove that the first edge in the process that creates a k-connected graph coincides a.a.s. with

Select four perfect matchings of 2n vertices, independently at random. We find the asymptotic probability that each of the first and second matchings forms a Hamilton cycle with each of the third and fourth. This is generalised to embrace any fixed number of perfect matchings, where a prescribed set

## Abstract We prove that the strong product of any __n__ connected graphs of maximum degree at most __n__ contains a Hamilton cycle. In particular, __G__^Δ(__G__)^ is hamiltonian for each connected graph __G__, which answers in affirmative a conjecture of Bermond, Germa, and Heydemann. © 2005 Wile