Decentralised Reinforcement Learning for Dynamic Cyberattack Response in Microgrid Networks
Suman Rath, Vivek Kumar SinghABSTRACT
Microgrids rely on communication networks for reliable operation, which makes them inherently vulnerable to cyberattacks. Such attacks can destabilise system dynamics and drive states away from their nominal operating trajectories. Although several physics‐informed and machine learning‐based strategies have been developed to counter these threats, the rapidly evolving cyber landscape enables adversaries to bypass static defences or rules‐based mitigation approaches. This paper proposes a dynamic, online‐trained and fully decentralised reinforcement learning (RL)‐based cyberattack response framework to protect microgrids from evolving cyberattacks. The proposed framework deploys multiple deep Q‐networks (DQNs), each associated with a distributed energy resource (DER), to enable localised and adaptive attack mitigation. In this framework, each DQN processes local voltage and frequency measurements—combined with intrusion detection system (IDS) alerts—as observations and rewards to guide decision‐making. Extensive simulation studies demonstrate the robustness of the proposed framework under diverse attack scenarios and varying IDS‐induced detection delays. Comparative analysis highlights its superiority over existing static or preexisting rules‐based mitigation approaches. Finally, we present an analysis that shows the framework's scalability to real‐life microgrids with more interacting agents.