Dynamical robustness of network of oscillators

IF 23.9 1区 物理与天体物理 Q1 PHYSICS, MULTIDISCIPLINARY Physics Reports Pub Date : 2024-06-29 DOI:10.1016/j.physrep.2024.06.003
Soumen Majhi , Biswambhar Rakshit , Amit Sharma , Jürgen Kurths , Dibakar Ghosh
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Abstract

Most complex systems are nonlinear, relying on emergent behavior resulting from many interacting subsystems, which are often characterized by oscillatory dynamics. Having collective oscillatory behavior is an essential requirement for an appropriate functioning of various real-world systems. Complex networks have proven to be exceptionally efficient in elucidating the topological structures of both natural and artificial systems, as well as describing diverse processes taking place over them. Remarkable advancements have been achieved in recent years in comprehending the emergent dynamics atop complex networks. Specifically, among other processes, a large body of works intend to explore the dynamical robustness of complex networks, which is the networks’ ability to withstand dynamical degradation in the network constituents while maintaining collective oscillatory dynamics. Indeed, various physical and biological systems are recognized to undergo a decline in their dynamic activities, whether occurring naturally or influenced by environmental factors. The impact of such damages on network performance can be significant, and the system’s robustness is indicative of its capability to maintain fundamental functionality in the face of dynamic deteriorations, often called aging. This review offers a comprehensive excerpt of notable research endeavors that scrutinize how networks sustain global oscillation under a growing number of inactive dynamical units. We present the contemporary research dedicated to the theoretical understanding and the enhancement mechanisms of the dynamical robustness in complex networks. Our emphasis lies on various network topologies and coupling functions, elucidating the persistence of networked systems. We cover variants of system characteristics from heterogeneity in network connectivity to heterogeneity in the dynamical units. Finally we discuss challenges ahead in this potential field and open areas for future studies.

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振荡器网络的动态稳健性
大多数复杂系统都是非线性的,依赖于许多相互作用的子系统所产生的突发性行为,这些子系统通常具有振荡动力学特征。集体振荡行为是各种现实世界系统正常运行的基本要求。事实证明,复杂网络在阐明自然系统和人工系统的拓扑结构,以及描述在这些系统上发生的各种过程方面都非常有效。近年来,在理解复杂网络顶层的突发动力学方面取得了显著进展。具体来说,除其他过程外,大量研究都在探索复杂网络的动态鲁棒性,即网络在保持集体振荡动态的同时,承受网络成分动态退化的能力。事实上,各种物理和生物系统的动态活动都会发生衰减,无论是自然发生还是受环境因素影响。这种破坏对网络性能的影响可能是巨大的,而系统的鲁棒性则表明其在面对动态退化(通常称为老化)时保持基本功能的能力。本综述全面摘录了一些著名的研究成果,这些成果仔细研究了网络如何在不活跃动态单元数量不断增加的情况下维持全局振荡。我们介绍了当代致力于复杂网络动态鲁棒性的理论理解和增强机制的研究。我们的重点在于各种网络拓扑结构和耦合函数,阐明网络系统的持久性。我们涵盖了从网络连接的异质性到动态单元的异质性等各种系统特征。最后,我们讨论了这一潜在领域面临的挑战以及未来研究的开放领域。
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来源期刊
Physics Reports
Physics Reports 物理-物理:综合
CiteScore
56.10
自引率
0.70%
发文量
102
审稿时长
9.1 weeks
期刊介绍: Physics Reports keeps the active physicist up-to-date on developments in a wide range of topics by publishing timely reviews which are more extensive than just literature surveys but normally less than a full monograph. Each report deals with one specific subject and is generally published in a separate volume. These reviews are specialist in nature but contain enough introductory material to make the main points intelligible to a non-specialist. The reader will not only be able to distinguish important developments and trends in physics but will also find a sufficient number of references to the original literature.
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