Vulnerability Assessment Against Cyber Attacks for Microgrid Cyber Physical System with Wind Power Integration

被引：0

作者：

Yan, Minrui ^{[1
]}

Yu, Miao ^{[1
]}

Wan, Keting ^{[1
]}

Qi, Donglian ^{[1
]}

机构：

[1] College of Electrical Engineering, Zhejiang University, Hangzhou

来源：

Dianli Xitong Zidonghua/Automation of Electric Power Systems | 2024年 / 48卷 / 24期

基金：

中国国家自然科学基金;

关键词：

cyber attack; cyber physical system; microgrid; vulnerability assessment;

D O I：

10.7500/AEPS20230815010

中图分类号：

学科分类号：

摘要：

With the evolution of the informatization and intelligence level of microgrids, malicious cyber attacks are becoming more serious threats to the safe and stable operation of microgrids. Compared with the distribution network, the microgrid has smaller scale, higher renewable energy penetration, and weaker adjustment capacity, and is more vulnerable to cyber attacks. In order to analyze the vulnerability of microgrid cyber physical system against cyber attacks, first, a physical-side model of microgrid considering control strategy and renewable energy output uncertainty, and a data flow based cyber-side model considering cyber attacks are formulated. Secondly, in order to analyze cyber attacks, the correlation matrix of attack method and attack target and a bi-level programming model considering the behavior of the attacker and the dispatching center are established. Then, based on the characteristics of load redistribution and Shapley value method, a vulnerability index calculation method based on attack consequences and vulnerability assessment process are proposed. Finally, the simulation is carried out on a 38-bus system to assess the vulnerability of the microgrid cyber physical system against cyber attacks, and the effectiveness of the proposed method and its guiding significance for formulating defense strategy are analyzed and verified. © 2024 Automation of Electric Power Systems Press. All rights reserved.

引用

页码：88 / 100

页数：12

共 33 条

[21] ZHANG H, MENG W C, QI J J, Et al., Distributed load sharing under false data injection attack in an inverter-based microgrid[J], IEEE Transactions on Industrial Electronics, 66, 2, pp. 1543-1551, (2019)
[22] WANG Zhengang, CHEN Yuanrui, ZENG Jun, Et al., Modeling and reliability assessment of completely distributed microgrid cyber physical system [J], Power System Technology, 43, 7, pp. 2413-2421, (2019)
[23] TABAR V S, GHASSEMZADEH S, TOHIDI S., Increasing resiliency against information vulnerability of renewable resources in the operation of smart multi-area microgrid, Energy, 220, (2021)
[24] LI Y L, YAN J., Cybersecurity of smart inverters in the smart grid:a survey[J], IEEE Transactions on Power Electronics, 38, 2, pp. 2364-2383, (2023)
[25] DU D J, ZHU M G, LI X, Et al., A review on cybersecurity analysis, attack detection, and attack defense methods in cyber-physical power systems[J], Journal of Modern Power Systems and Clean Energy, 11, 3, pp. 727-743, (2023)
[26] VOSUGHI A, TAMIMI A, KING A B, Et al., Cyber-physical vulnerability and resiliency analysis for DER integration: a review, challenges and research needs, Renewable and Sustainable Energy Reviews, 168, (2022)
[27] WANG Chen, MENG Jianhui, WANG Yi, Et al., Multi-source coordinated control strategy considering battery’s SOC for islanded DC microgrid, High Voltage Engineering, 44, 1, pp. 160-168, (2018)
[28] ZHANG Jing, ZHANG Zhiwen, HU Sijia, Et al., A flexible power distribution strategy with wind turbine generator and energy storage for frequency regulation in isolated microgrid, Transactions of China Electrotechnical Society, 37, 15, pp. 3767-3780, (2022)
[29] YANG Jie, GUO Yihao, GUO Chuangxin, Et al., A review of dynamic security protection on a cyber physical power system considering model and data driving, Power System Protection and Control, 50, 7, pp. 176-187, (2022)
[30] YUAN Y L, LI Z Y, REN K., Modeling load redistribution attacks in power systems[J], IEEE Transactions on Smart Grid, 2, 2, pp. 382-390, (2011)

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