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Cyber-Physical Fusion for GNN-Based Attack Detection in Smart Power Grids

Jacob Sweeten, A. A. El-Shazly, Abdulrahman Takiddin, Muhammad Ismail, Shady S. Refaat, Rachad Atat

2025IEEE Open Access Journal of Power and Energy6 citationsDOIOpen Access PDF

Abstract

Recent research has shown promise in using machine learning for cyberattack detection in power systems. However, current studies face limitations: (a) dependence on either physical or cyber features, overlooking multi-modal cyber-physical (CP) correlations; (b) unrealistic full observability assumptions; (c) focus on detecting basic attacks instead of advanced threats such as ransomware (RW); and (d) use of deep learning (DL) models built for 2D data, despite the graph-structured nature of power systems. To address these gaps, we develop a CP testbed using OPAL-RT and a cyber range to simulate both physical and cyber layers under full and partial observability. The testbed produces a realistic multi-modal dataset covering normal operations and various cyberattacks, including RW, brute force, false data injection, reverse shell, and backdoor. Using this dataset, we design graph neural network (GNN)-based multi-modal intrusion detection systems (IDSs) that fuse CP features and capture spatio-temporal dependencies. Results show that CP fusion improves detection rates (DRs) by up to 16% compared to single-modal inputs. The proposed GNN-based IDSs outperform benchmarks by up to 26% in DR, remain effective under partial observability, and demonstrate up to 6% improvement in scalability when applied to larger system topologies.

Topics & Concepts

Cyber-physical systemComputer scienceSmart gridComputer securityFusionElectrical engineeringEngineeringOperating systemPhilosophyLinguisticsSmart Grid Security and ResilienceNetwork Security and Intrusion DetectionAdvanced Malware Detection Techniques
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