电网中的级联故障:具有节点中心性的负载能力模型

Chaoyang Chen;Yao Hu;Xiangyi Meng;Jinzhu Yu
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引用次数: 0

摘要

电网由于缺乏网络冗余和结构上的相互依存,特别容易受到级联故障的影响,即少数故障节点的负载超过其容量,会引发所有节点的大面积崩溃。在这里,我们将级联故障(Motter-Lai)模型扩展到一个更现实的视角,即每个节点的负载能力都与节点的中心性非线性相关。我们的分析涵盖了一系列具有小世界或无标度特性的合成网络,以及 IEEE 总线系统和美国电网等现实网络配置。我们发现,当网络节点受到攻击时,对这种非线性关系进行微调可以显著增强网络的鲁棒性,防止出现级联故障。此外,初始节点的选择和攻击策略也会影响整个网络的鲁棒性。我们的研究结果为提高电网的安全性和恢复能力提供了宝贵的见解,使我们更接近于在更现实的背景下理解级联故障。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Cascading Failures in Power Grids: A Load Capacity Model with Node Centrality
Power grids, due to their lack of network redundancy and structural interdependence, are particularly vulnerable to cascading failures, a phenomenon where a few failed nodes-having their loads exceeding their capacities—can trigger a widespread collapse of all nodes. Here, we extend the cascading failure (Motter-Lai) model to a more realistic perspective, where each node's load capacity is determined to be nonlinearly correlated with the node's centrality. Our analysis encompasses a range of synthetic networks featuring small-world or scale-free properties, as well as real-world network configurations like the IEEE bus systems and the US power grid. We find that fine-tuning this nonlinear relationship can significantly enhance a network's robustness against cascading failures when the network nodes are under attack. Additionally, the selection of initial nodes and the attack strategies also impact overall network robustness. Our findings offer valuable insights for improving the safety and resilience of power grids, bringing us closer to understanding cascading failures in a more realistic context.
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CiteScore
7.80
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