English

Distances in random graphs with infinite mean degrees

Probability 2007-05-23 v1 Combinatorics

Abstract

We study random graphs with an i.i.d. degree sequence of which the tail of the distribution function FF is regularly varying with exponent τ(1,2)\tau\in (1,2). Thus, the degrees have infinite mean. Such random graphs can serve as models for complex networks where degree power laws are observed. The minimal number of edges between two arbitrary nodes, also called the graph distance or the hopcount, in a graph with NN nodes is investigated when NN\to \infty. The paper is part of a sequel of three papers. The other two papers study the case where τ(2,3)\tau \in (2,3), and τ(3,),\tau \in (3,\infty), respectively. The main result of this paper is that the graph distance converges for τ(1,2)\tau\in (1,2) to a limit random variable with probability mass exclusively on the points 2 and 3. We also consider the case where we condition the degrees to be at most NαN^{\alpha} for some α>0.\alpha>0. For τ1<α<(τ1)1\tau^{-1}<\alpha<(\tau-1)^{-1}, the hopcount converges to 3 in probability, while for α>(τ1)1\alpha>(\tau-1)^{-1}, the hopcount converges to the same limit as for the unconditioned degrees. Our results give convincing asymptotics for the hopcount when the mean degree is infinite, using extreme value theory.

Keywords

Cite

@article{arxiv.math/0407091,
  title  = {Distances in random graphs with infinite mean degrees},
  author = {Remco van der Hofstad and Gerard Hooghiemstra and Dmitri Znamenski},
  journal= {arXiv preprint arXiv:math/0407091},
  year   = {2007}
}

Comments

20 pages, 2 figures