Large Language Models for Detecting Cyberattacks on Smart Grid Protective Relays
This addresses cybersecurity risks in critical smart grid infrastructure, though it is an incremental application of existing LLM methods to a new domain.
The paper tackles the problem of detecting cyberattacks on transformer current differential relays in smart grids to prevent false tripping, achieving 97.6% detection accuracy with inference latency below 6 ms.
This paper presents a large language model (LLM)-based framework for detecting cyberattacks on transformer current differential relays (TCDRs), which, if undetected, may trigger false tripping of critical transformers. The proposed approach adapts and fine-tunes compact LLMs such as DistilBERT to distinguish cyberattacks from actual faults using textualized multidimensional TCDR current measurements recorded before and after tripping. Our results demonstrate that DistilBERT detects 97.6% of cyberattacks without compromising TCDR dependability and achieves inference latency below 6 ms on a commercial workstation. Additional evaluations confirm the framework's robustness under combined time-synchronization and false-data-injection attacks, resilience to measurement noise, and stability across prompt formulation variants. Furthermore, GPT-2 and DistilBERT+LoRA achieve comparable performance, highlighting the potential of LLMs for enhancing smart grid cybersecurity. We provide the full dataset used in this study for reproducibility.