Data-Driven Cyberphysical Anomaly Detection for Microgrids With GFM Inverters

Abstract

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Microgrids (MGs) have gained significant attention considering their enhanced capability to integrate increasing distributed energy resources (DERs). The application of grid forming (GFM) inverters in a MG can control voltage/frequency, enable both islanded and grid-connected operation, and achieve 100% penetration. However, cyberphysical anomaly detection for a MG with GFM inverters has not been investigated before. In this article, the cyberphysical security of an ac MG with multiple GFM inverters is comprehensively assessed by considering short-circuit high-impedance faults (HIFs) as well as firstly exploiting False Data Injection Attacks (FDIAs) against centralized communication networks. Although the applied IEEE 1547-2018 based protection function could detect abnormal conditions, there exist cyberphysical anomalies could bypass it. In order to accomplish the detection and classification of such anomaly cases, a novel LSTM-based approach is proposed to identify the multi-class pattern regarding normal, cyberphysical threats during islanded and grid-connected by utilizing time series point of common coupling (PCC) frequency data as the paramount feature to effectively reflect the system operation status. The simulation is conducted in OPAL-RT real-time environment and the effectiveness of the proposed strategy is verified with an average detection accuracy of 94.72%.

Keywords

• Anomaly detection and classification
• cyberphysical security
• data-driven
• FDIAs
• GFM inverters
• HIFs