When is a scale-free graph ultra-small?
Abstract
In this paper we study typical distances in the configuration model, when the degrees have asymptotically infinite variance. We assume that the empirical degree distribution follows a power law with exponent , up to value for some and . This assumption is satisfied for power law i.i.d. degrees, and also includes truncated power-law distributions where the (possibly exponential) truncation happens at . We show that the graph distance between two uniformly chosen vertices centers around , with tight fluctuations. Thus, the graph is an \emph{ultrasmall world} whenever . We determine the distribution of the fluctuations around this value, in particular we prove that these are non-converging tight random variables that show -periodicity. We describe the topology and number of shortest paths: We show that the number of shortest paths is of order , where is a random variable that oscillates with . The two end-segments of any shortest path have length +tight, and the total degree is increasing towards the middle of the path on these segments. The connecting middle segment has length +tight, and it contains only vertices with degree at least of order , thus all the degrees on this segment are comparable to the maximal degree. Our theorems also apply when instead of truncating the degrees, we start with a configuration model and we remove every vertex with degree at least , and the edges attached to these vertices. This sheds light on the attack vulnerability of the configuration model with infinite variance degrees.
Cite
@article{arxiv.1611.03639,
title = {When is a scale-free graph ultra-small?},
author = {Remco van der Hofstad and Julia Komjathy},
journal= {arXiv preprint arXiv:1611.03639},
year = {2017}
}
Comments
36 pages, 1 figure