Robustness and resilience of complex networks

IF 44.8 1区 物理与天体物理 Q1 PHYSICS, APPLIED Nature Reviews Physics Pub Date : 2024-01-08 DOI:10.1038/s42254-023-00676-y
Oriol Artime, Marco Grassia, Manlio De Domenico, James P. Gleeson, Hernán A. Makse, Giuseppe Mangioni, Matjaž Perc, Filippo Radicchi
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Abstract

Complex networks are ubiquitous: a cell, the human brain, a group of people and the Internet are all examples of interconnected many-body systems characterized by macroscopic properties that cannot be trivially deduced from those of their microscopic constituents. Such systems are exposed to both internal, localized, failures and external disturbances or perturbations. Owing to their interconnected structure, complex systems might be severely degraded, to the point of disintegration or systemic dysfunction. Examples include cascading failures, triggered by an initially localized overload in power systems, and the critical slowing downs of ecosystems which can be driven towards extinction. In recent years, this general phenomenon has been investigated by framing localized and systemic failures in terms of perturbations that can alter the function of a system. We capitalize on this mathematical framework to review theoretical and computational approaches to characterize robustness and resilience of complex networks. We discuss recent approaches to mitigate the impact of perturbations in terms of designing robustness, identifying early-warning signals and adapting responses. In terms of applications, we compare the performance of the state-of-the-art dismantling techniques, highlighting their optimal range of applicability for practical problems, and provide a repository with ready-to-use scripts, a much-needed tool set. Complex biological, social and engineering systems operate through intricate connectivity patterns. Understanding their robustness and resilience against disturbances is crucial for applications. This Review addresses systemic breakdown, cascading failures and potential interventions, highlighting the importance of research at the crossroad of statistical physics and machine learning.

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复杂网络的稳健性和复原力
复杂网络无处不在:细胞、人脑、人群和互联网都是相互连接的多体系统的例子,这些系统的宏观特性无法从其微观组成部分的特性中简单推导出来。这些系统既会受到内部局部故障的影响,也会受到外部干扰或扰动的影响。由于其结构相互关联,复杂系统可能会严重退化,以至于解体或系统功能失调。这方面的例子包括电力系统最初局部过载引发的级联故障,以及生态系统的严重衰退可能导致灭绝。近年来,人们通过将局部性和系统性故障归结为可改变系统功能的扰动,对这一普遍现象进行了研究。我们利用这一数学框架,回顾了表征复杂网络鲁棒性和恢复力的理论和计算方法。我们从设计鲁棒性、识别预警信号和调整响应等方面讨论了减轻扰动影响的最新方法。在应用方面,我们比较了最先进的拆解技术的性能,强调了它们对实际问题的最佳适用范围,并提供了一个包含即用脚本的资源库,这是一套急需的工具。
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来源期刊
CiteScore
47.80
自引率
0.50%
发文量
122
期刊介绍: Nature Reviews Physics is an online-only reviews journal, part of the Nature Reviews portfolio of journals. It publishes high-quality technical reference, review, and commentary articles in all areas of fundamental and applied physics. The journal offers a range of content types, including Reviews, Perspectives, Roadmaps, Technical Reviews, Expert Recommendations, Comments, Editorials, Research Highlights, Features, and News & Views, which cover significant advances in the field and topical issues. Nature Reviews Physics is published monthly from January 2019 and does not have external, academic editors. Instead, all editorial decisions are made by a dedicated team of full-time professional editors.
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