Long Paths and Hamiltonian paths in Inhomogenous Random Graphs

Abstract

In this paper, we study long paths and Hamiltonian paths in inhomogenous random graphs. In the first part of the paper, we consider an inhomogenous Erdos-R\'enyi random graph GE with average edge density pn. We prove that if npn2 ∞ as n → ∞, then the longest path contains at least n-ne-δ1 npn2 nodes with high probability (i.e., with probability converging to one as n → ∞), for some constant δ1> 0 . In particular, if npn2 = Mn for some constant M > 0 large, then GE is Hamiltonian with high probability; i.e., the longest path contains all the nodes of GE. In the second part of the paper, we consider a random geometric graph GR consisting of n nodes, each independently distributed according to a (not necessarily uniform) density f. If rn is the connectivity radius and nrn2 ∞, then with high probability, the longest cycle contains at least n-ne-δ2 nrn2 nodes for some constant δ2 > 0. As a consequence of our proof, we obtain that if nrn2 = n + 7n + ωn and ωn ∞ as n → ∞, then with high probability GR contains a Hamiltonian cycle.