Fractality in complex networks: critical and supercritical skeletons

TL;DR

This paper investigates the fractal properties of complex networks by introducing a new box-covering algorithm, analyzing the skeleton structure, and modeling networks with critical and supercritical branching trees to understand their scaling behaviors.

Contribution

It presents a modified box-covering algorithm and a fractal network model based on skeletons and shortcuts, highlighting the role of branching criticality in network fractality.

Findings

Fractal networks have a skeleton based on edge betweenness centrality.

The model shows power-law and exponential growth depending on skeleton criticality.

Box mass distribution follows a power law with size-dependent exponent.

Abstract

Fractal scaling--a power-law behavior of the number of boxes needed to tile a given network with respect to the lateral size of the box--is studied. We introduce a new box-covering algorithm that is a modified version of the original algorithm introduced by Song et al. [Nature (London) 433, 392 (2005)]; this algorithm enables effective computation and easy implementation. Fractal networks are viewed as comprising a skeleton and shortcuts. The skeleton, embedded underneath the original network, is a special type of spanning tree based on the edge betweenness centrality; it provides a scaffold for the fractality of the network. When the skeleton is regarded as a branching tree, it exhibits a plateau in the mean branching number as a function of the distance from a root. Based on these observations, we construct a fractal network model by combining a random branching tree and local shortcuts. The scaffold branching tree can be either critical or supercritical, depending on the small-worldness of a given network. For the network constructed from the critical (supercritical) branching tree, the average number of vertices within a given box grows with the lateral size of the box according to a power-law (an exponential) form in the cluster-growing method. The distribution of box masses, i.e., the number of vertices within each box, follows a power law P_m(M) sim M^{-eta}. The exponent eta depends on the box lateral size ell_B. For small values of ell_B, eta is equal to the degree exponent gamma of a given scale-free network, whereas eta approaches the exponent tau=gamma/(gamma-1) as ell_B increases, which is the exponent of the cluster-size distribution of the random branching tree. We also study the perimeter of a given box as a function of the box mass.