Structure of shells in complex networks
Abstract
In a network, we define shell as the set of nodes at distance with respect to a given node and define as the fraction of nodes outside shell . In a transport process, information or disease usually diffuses from a random node and reach nodes shell after shell. Thus, understanding the shell structure is crucial for the study of the transport property of networks. For a randomly connected network with given degree distribution, we derive analytically the degree distribution and average degree of the nodes residing outside shell as a function of . Further, we find that follows an iterative functional form , where is expressed in terms of the generating function of the original degree distribution of the network. Our results can explain the power-law distribution of the number of nodes found in shells with larger than the network diameter , which is the average distance between all pairs of nodes. For real world networks the theoretical prediction of deviates from the empirical . We introduce a network correlation function to characterize the correlations in the network, where is the empirical value and is the theoretical prediction. indicates perfect agreement between empirical results and theory. We apply to several model and real world networks. We find that the networks fall into two distinct classes: (i) a class of {\it poorly-connected} networks with , which have larger average distances compared with randomly connected networks with the same degree distributions; and (ii) a class of {\it well-connected} networks with .
Cite
@article{arxiv.0903.2070,
title = {Structure of shells in complex networks},
author = {Jia Shao and Sergey V. Buldyrev and Lidia A. Braunstein and Shlomo Havlin and H. Eugene Stanley},
journal= {arXiv preprint arXiv:0903.2070},
year = {2015}
}