GenAI-FDIA: Physics-Informed Generative Models for False Data Injection Attacks

Abstract

Training and evaluating false data injection attack (FDIA) detectors for power systems is constrained by data scarcity. Operational grid measurements are commercially sensitive, and hand-crafted attacks fail to capture complex distributional structures imposed by network physics. We present GenAI-FDIA, a framework benchmarking a pool of P=20 architectures for physics-compliant FDIA synthesis, spanning Wasserstein GANs, MMD-VAEs, normalising flows, diffusion models, and cross-family hybrids. These are evaluated across three IEEE testbeds (14-bus DC, 30-bus DC, and 14-bus AC) under a 60/20/20 chronological split using data-driven Bad Data Detection (BDD) threshold calibration. Our empirical results verify that these models generate high-fidelity attacks, with all architectures achieving evasion rates of εBDD 86.6\% on the 14-bus network; additionally, limiting an attacker's topological knowledge induces a measurable degradation in stealthiness (p 0.0022). Crucially, we identify a previously unreported failure mode: applying affine physics projections directly in normalised feature spaces critically displaces the attack vector, collapsing BDD evasion from 55\% to <\!2\% on the 30-bus testbed. We resolve this via a novel inference-time harmoniser, restoring full stealthiness (εBDD=100\%) across all physics-informed variants without retraining. Finally, we isolate a covariance-collapse phenomenon (κ≈ -0.076) within advanced hybrid architectures and rectify it through 50-epoch warm-up schedules (κ 0.785, ΔMMD=-3.1\%). Ultimately, GenAI-FDIA delivers a robust recovery blueprint applicable to any physics-constrained generative model deployed for power-system security.