Reviving a failed network via microscopic interventions

arXiv: Adaptation and Self-Organizing Systems Pub Date : 2020-12-09 DOI:10.21203/rs.3.rs-116071/v1

Hillel Sanhedrai, Jianxi Gao, M. Schwartz, S. Havlin, B. Barzel

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引用次数: 4

Abstract

From mass extinction to cell death, complex networked systems often exhibit abrupt dynamic transitions between desirable and undesirable states. Such transitions are often caused by topological perturbations, such as node or link removal, or decreasing link strengths. The problem is that reversing the topological damage, namely retrieving the lost nodes/links or reinforcing the weakened interactions, does not guarantee the spontaneous recovery to the desired functional state. Indeed, many of the relevant systems exhibit a hysteresis phenomenon, remaining in the dysfunctional state, despite reconstructing their damaged topology. To address this challenge, we develop a two-step recovery scheme: first - topological reconstruction to the point where the system can be revived, then dynamic interventions, to reignite the system's lost functionality. Applied to a range of nonlinear network dynamics, we identify a complex system's recoverable phase, a state in which the system can be reignited by a microscopic intervention, i.e. controlling just a single node. Mapping the boundaries of this newly discovered phase, we obtain guidelines for our two-step recovery.

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通过微观干预重振失败的网络

从大规模灭绝到细胞死亡，复杂的网络系统经常在理想状态和不理想状态之间表现出突然的动态转变。这种转变通常是由拓扑扰动引起的，例如节点或链路的移除，或链路强度的降低。问题是，逆转拓扑损伤，即恢复丢失的节点/链接或加强减弱的相互作用，并不能保证自发恢复到所需的功能状态。事实上，许多相关系统表现出一种滞后现象，尽管重建了损坏的拓扑结构，但仍处于功能失调状态。为了应对这一挑战，我们制定了两步恢复方案:首先进行拓扑重建，使系统能够恢复，然后进行动态干预，以重新点燃系统失去的功能。应用于一系列非线性网络动力学，我们确定了复杂系统的可恢复阶段，即系统可以通过微观干预(即仅控制单个节点)重新点燃的状态。通过绘制这个新发现阶段的边界，我们获得了两步恢复的指导方针。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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arXiv: Adaptation and Self-Organizing Systems

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