Identifying time dependence in network growth

Max Falkenberg,Yoshihiro Miyake,Shun-Ichi Amano,Ken-Ichiro Ogawa,Jong-Hyeok Lee,Kazuo Yano,Kim Christensen,Tim S Evans

doi:10.1103/physrevresearch.2.023352

Max Falkenberg, Yoshihiro Miyake + Show 6 more

Open Access

https://doi.org/10.1103/physrevresearch.2.023352

Copy DOI

Abstract

Identifying power-law scaling in real networks - indicative of preferential attachment - has proved controversial. Critics argue that measuring the temporal evolution of a network directly is better than measuring the degree distribution when looking for preferential attachment. However, many of the established methods do not account for any potential time-dependence in the attachment kernels of growing networks, or methods assume that node degree is the key observable determining network evolution. In this paper, we argue that these assumptions may lead to misleading conclusions about the evolution of growing networks. We illustrate this by introducing a simple adaptation of the Barab{\'a}si-Albert model, the "k2 model", where new nodes attach to nodes in the existing network in proportion to the number of nodes one or two steps from the target node. The k2 model results in time dependent degree distributions and attachment kernels, despite initially appearing to grow as linear preferential attachment, and without the need to include explicit time dependence in key network parameters (such as the average out-degree). We show that similar effects are seen in several real world networks where constant network growth rules do not describe their evolution. This implies that measurements of specific degree distributions in real networks are also likely to change over time.

Highlights

The study of complex networks has expanded rapidly over the past 20 years
We will focus on analyzing the attachment kernel and the degree distribution of the k2 model, using the BA model as a comparison
To verify that the deviations in the relative attachment kernel are due to the evolution of the k2 model and not numerical errors, we repeat the analysis shown in Fig. 4 for the BA model where the relative attachment kernel is expected to be time independent

Summary

Introduction

Many real systems have been analyzed using networks with great success, showing many nontrivial properties [1]. Model networks have been defined to understand the origin and development of these properties from elementary principles. The Barabási-Albert (BA) model, an undirected version of the Price model [3], demonstrates that scale free (power-law) degree distributions in real networks can arise from a combination of growth and preferential attachment [4]. These models have given significant insight into the structure of real networks. Real systems almost never reflect the exact details of a model

Objectives

Methods

Results

Conclusion