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 r 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 r. Further, we find that r follows an iterative functional form r=φ(r-1), where φ 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 B found in shells with larger than the network diameter d, which is the average distance between all pairs of nodes. For real world networks the theoretical prediction of r deviates from the empirical r. We introduce a network correlation function c(r) r+1/φ(r) to characterize the correlations in the network, where r+1 is the empirical value and φ(r) is the theoretical prediction. c(r)=1 indicates perfect agreement between empirical results and theory. We apply c(r) to several model and real world networks. We find that the networks fall into two distinct classes: (i) a class of poorly-connected networks with c(r)>1, which have larger average distances compared with randomly connected networks with the same degree distributions; and (ii) a class of well-connected networks with c(r)<1.