Network Structural Origin of Instabilities in Large Complex Systems

Overview

Journal Sci Adv

Specialties Biology
Science

Date 2022 Jul 20

PMID 35857524

Authors

Chao Duan

Takashi Nishikawa

Deniz Eroglu

Adilson E Motter

Affiliations

Soon will be listed here.

Abstract

A central issue in the study of large complex network systems, such as power grids, financial networks, and ecological systems, is to understand their response to dynamical perturbations. Recent studies recognize that many real networks show nonnormality and that nonnormality can give rise to reactivity-the capacity of a linearly stable system to amplify its response to perturbations, oftentimes exciting nonlinear instabilities. Here, we identify network structural properties underlying the pervasiveness of nonnormality and reactivity in real directed networks, which we establish using the most extensive dataset of such networks studied in this context to date. The identified properties are imbalances between incoming and outgoing network links and paths at each node. On the basis of this characterization, we develop a theory that quantitatively predicts nonnormality and reactivity and explains the observed pervasiveness. We suggest that these results can be used to design, upgrade, control, and manage networks to avoid or promote network instabilities.

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