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基于弹性振荡器的网络攻击检测,用于逆变器接口孤岛微电网的分布式二次控制。

Resilient oscillator-based cyberattack detection for distributed secondary control of inverter-interfaced Islanded microgrids.

作者信息

Zargarzadeh-Esfahani Fahimeh, Fani Bahador, Keyvani-Boroujeni Babak, Sadeghkhani Iman, Sajadieh Mahdi

机构信息

Department of Electrical Engineering, Isf.C., Islamic Azad University, Isfahan, Iran.

Department of Electrical Engineering, Bor.C., Islamic Azad University, Borojen, Iran.

出版信息

Sci Rep. 2025 Jul 1;15(1):20685. doi: 10.1038/s41598-025-05524-w.

DOI:10.1038/s41598-025-05524-w
PMID:40596147
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC12214637/
Abstract

With the increasing integration of Distributed Generation (DG) units and advanced control systems, microgrids have become more vulnerable to cyberattacks, particularly those targeting secondary control mechanisms. False Data Injection (FDI) and Denial-of-Service (DoS) attacks can significantly disrupt the stability and performance of microgrids by manipulating communication links and control signals. This paper proposes a robust cyber-resilient strategy to mitigate the impact of cyberattacks on secondary control in islanded AC microgrids. The proposed approach enhances the resilience of frequency regulation and real power sharing by integrating adaptive anomaly detection and hierarchical control mechanisms. The approach's effectiveness is evaluated through comprehensive simulations in MATLAB/Simulink, considering various cyberattack scenarios, including FDI and DoS attacks on critical communication links. Results demonstrate that, under normal conditions, the primary and secondary controllers ensure frequency stability and balanced power distribution. However, in the presence of cyberattacks, the conventional control strategy fails to maintain stability, leading to frequency deviations and power imbalances. The proposed approach successfully detects and mitigates these attacks, restoring system stability and ensuring robust operation. Furthermore, the effectiveness of the proposed approach is validated across different microgrid topologies, including networked, looped-type, and bus-type configurations, demonstrating its adaptability and effectiveness in diverse network structures.

摘要

随着分布式发电(DG)单元与先进控制系统的日益融合,微电网变得更容易受到网络攻击,尤其是针对二次控制机制的攻击。虚假数据注入(FDI)和拒绝服务(DoS)攻击可通过操纵通信链路和控制信号,显著扰乱微电网的稳定性和性能。本文提出一种强大的网络弹性策略,以减轻网络攻击对孤岛交流微电网二次控制的影响。所提出的方法通过集成自适应异常检测和分层控制机制,增强了频率调节和有功功率共享的弹性。该方法的有效性通过在MATLAB/Simulink中进行的综合仿真进行评估,考虑了各种网络攻击场景,包括对关键通信链路的FDI和DoS攻击。结果表明,在正常情况下,一次和二次控制器可确保频率稳定性和功率平衡分配。然而,在存在网络攻击的情况下,传统控制策略无法维持稳定性,导致频率偏差和功率不平衡。所提出的方法成功地检测并减轻了这些攻击,恢复了系统稳定性并确保了稳健运行。此外,所提出方法的有效性在不同的微电网拓扑结构中得到了验证,包括联网型、环型和母线型配置,证明了其在不同网络结构中的适应性和有效性。

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