Robust hamiltonicity of random directed graphs
Abstract
In his seminal paper from 1952 Dirac showed that the complete graph on vertices remains Hamiltonian even if we allow an adversary to remove edges touching each vertex. In 1960 Ghouila-Houri obtained an analogue statement for digraphs by showing that every directed graph on vertices with minimum in- and out-degree at least contains a directed Hamilton cycle. Both statements quantify the robustness of complete graphs (digraphs) with respect to the property of containing a Hamilton cycle. A natural way to generalize such results to arbitrary graphs (digraphs) is using the notion of \emph{local resilience}. The local resilience of a graph (digraph) with respect to a property is the maximum number such that has the property even if we allow an adversary to remove an -fraction of (in- and out-going) edges touching each vertex. The theorems of Dirac and Ghouila-Houri state that the local resilience of the complete graph and digraph with respect to Hamiltonicity is . Recently, this statements have been generalized to random settings. Lee and Sudakov (2012) proved that the local resilience of a random graph with edge probability with respect to Hamiltonicity is . For random directed graphs, Hefetz, Steger and Sudakov (2014+) proved an analogue statement, but only for edge probability . In this paper we significantly improve their result to , which is optimal up to the polylogarithmic factor.
Keywords
Cite
@article{arxiv.1410.2198,
title = {Robust hamiltonicity of random directed graphs},
author = {Asaf Ferber and Rajko Nenadov and Andreas Noever and Ueli Peter and Nemanja Škorić},
journal= {arXiv preprint arXiv:1410.2198},
year = {2014}
}