An Enhanced Detection Scheme and Distributed Resilient Asynchronous Event-Triggered Control of AC Microgrids Subject to Replay Attacks
针对交流微电网中重放攻击导致转换器失同步的问题,提出一种分布式弹性异步事件触发机制和增强型水印检测方案,提升通信效率并简化攻击检测过程。
The transmission of information between distributed energy resource units (DERUs) within Microgrids (MGs) relies on sensing and communication systems that are vulnerable to cybersecurity threats. This article addresses the challenge of achieving resilient synchronization in networked AC MGs under cyber-attack conditions, specifically in scenarios where adversaries aim to desynchronize converters by intercepting, recording, and replaying communication signals. To mitigate these threats, we propose a distributed resilient event-triggered mechanism (DRETM) for secondary control of AC MGs during replay attacks. Unlike existing cybersecurity strategies, the proposed asynchronous event-based scheme enhances communication efficiency and reduces network resource consumption by employing a dual trigger function tailored for the communication links between the leader and informed DERUs, as well as among neighboring DERUs. Furthermore, to improve the detection of replay attacks, an enhanced distributed watermark-based detection scheme (EDWDS) is introduced. This mechanism minimizes the adverse effects of watermark signals on the system and streamlines the detection process by eliminating the need for complex parameter calculations or neighboring state estimations, in contrast to current detection methods. Finally, simulation results conducted in MATLAB/Simulink validate the effectiveness and accuracy of the proposed mechanisms.