Losing Control of Your Linear Network? Try Resilience Theory

IF 5 3区计算机科学 Q2 AUTOMATION & CONTROL SYSTEMS IEEE Transactions on Control of Network Systems Pub Date : 2024-07-19 DOI:10.1109/TCNS.2024.3431409

Jean-Baptiste Bouvier;Sai Pushpak Nandanoori;Melkior Ornik

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Abstract

Resilience of cyber-physical networks to unexpected failures is a critical need widely recognized across domains. For instance, power grids, telecommunication networks, transportation infrastructures, and water treatment systems have all been subject to disruptive malfunctions and catastrophic cyberattacks. Following such adverse events, we investigate scenarios where a node of a linear network suffers a loss of control authority over some of its actuators. These actuators are not following the controller's commands and are instead producing undesirable outputs. The repercussions of such a loss of control can propagate and destabilize the whole network despite the malfunction occurring at a single node. To assess system vulnerability, we establish resilience conditions for networks with a subsystem enduring a loss of control authority over some of its actuators. Furthermore, we quantify the destabilizing impact on the overall network when such a malfunction perturbs a nonresilient subsystem. We illustrate our resilience conditions on two academic examples, on an islanded microgrid and on the linearized IEEE 39-bus system.

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失去对线性网络的控制？试试弹性理论

网络物理网络对意外故障的弹性是跨领域广泛认可的关键需求。例如，电网、电信网络、交通基础设施和水处理系统都受到破坏性故障和灾难性网络攻击的影响。在这些不利事件之后，我们研究了线性网络的一个节点对其一些执行器失去控制权限的情况。这些执行器不遵循控制器的命令，而是产生不希望的输出。尽管故障发生在单个节点上，但这种失去控制的后果可能会传播并破坏整个网络的稳定。为了评估系统脆弱性，我们建立了具有子系统对其某些执行器失去控制权限的网络的弹性条件。此外，当这种故障干扰非弹性子系统时，我们量化了对整个网络的不稳定影响。我们通过孤岛微电网和线性化的IEEE 39总线系统两个学术实例说明了我们的弹性条件。

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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来源期刊

IEEE Transactions on Control of Network Systems Mathematics-Control and Optimization

CiteScore

7.80

自引率

7.10%

发文量

169

期刊介绍： The IEEE Transactions on Control of Network Systems is committed to the timely publication of high-impact papers at the intersection of control systems and network science. In particular, the journal addresses research on the analysis, design and implementation of networked control systems, as well as control over networks. Relevant work includes the full spectrum from basic research on control systems to the design of engineering solutions for automatic control of, and over, networks. The topics covered by this journal include: Coordinated control and estimation over networks, Control and computation over sensor networks, Control under communication constraints, Control and performance analysis issues that arise in the dynamics of networks used in application areas such as communications, computers, transportation, manufacturing, Web ranking and aggregation, social networks, biology, power systems, economics, Synchronization of activities across a controlled network, Stability analysis of controlled networks, Analysis of networks as hybrid dynamical systems.

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