Modular hierarchical and power-law small-world networks bear structural optima for minimal first passage times and cover time

Maier, Benjamin F.; Huepe, Cristian; Brockmann, Dirk

Abstract

Networks that are organized as a hierarchy of modules have been the subject of much research, mainly focusing on algorithms that can extract this community structure from data. The question of why modular hierarchical (MH) organizations are so ubiquitous in nature, however, has received less attention. One hypothesis is that MH topologies may provide an optimal structure for certain dynamical processes. We revisit a MH network model that interpolates, using a single parameter, between two known network topologies: from strong hierarchical modularity to an Erdos-Renyi random connectivity structure. We show that this model displays a similar small-world effect as the Kleinberg model, where the connection probability between nodes decays algebraically with distance. We find that there is an optimal structure, in both models, for which the pair-averaged first passage time (FPT) and mean cover time of a discrete-time random walk are minimal, and provide a heuristic explanation for this effect. Finally, we show that analytic predictions for the pair-averaged FPT based on an effective medium approximation fail to reproduce these minima, which implies that their presence is due to a network structure effect.

Más información

Título según WOS: ID WOS:000509770800003 Not found in local WOS DB
Título de la Revista: JOURNAL OF COMPLEX NETWORKS
Volumen: 7
Número: 6
Editorial: OXFORD UNIV PRESS
Fecha de publicación: 2019
Página de inicio: 865
Página final: 895
DOI:

10.1093/comnet/cnz010

Notas: ISI