Secondary Defense Strategies of AC Microgrids Against Generally Unbounded Attacks

TL;DR

This paper proposes fully distributed secondary defense strategies for AC microgrids that can withstand a broad class of unbounded cyber-physical attacks, ensuring stability and performance.

Contribution

It introduces novel attack-resilient control strategies that surpass existing methods by handling more general unbounded attacks on control inputs in AC microgrids.

Findings

Strategies achieve bounded convergence in frequency regulation.

Strategies ensure voltage containment and active power sharing.

Validated on IEEE 34-bus test system with inverter DERs.

Abstract

This paper develops a fully distributed attack-resilient secondary defense strategies for AC microgrids, addressing more generally unbounded attacks on control input channels than those addressed in existing literature. The secondary control of local inverter includes consensus-based voltage and current regulators utilizing relative information from neighboring inverters. This distributed control approach relies on localized control and a sparse communication network, making it susceptible to malicious cyber-physical attacks that can impair consensus performance and potentially destabilize the overall microgrid. In contrast to existing solutions that are limited to addressing either bounded faults, noises or unbounded attacks with bounded first-order time derivatives, we aim to surpass these constraints and enhance the defense capabilities of counteracting cyber-physical attacks by enabling the AC microgrids adopting the proposed strategies to withstand a much wider range of unbounded cyber-attack signals. Fully distributed attack-resilient secondary defense strategies are developed for AC microgrids to counteract the detrimental effects of generally unbounded attacks on control input channels. Rigorous proofs using Lyapunov techniques demonstrate that the proposed defense strategies accomplish the uniformly ultimately bounded convergence on frequency regulation and achieve voltage containment and active power sharing simultaneously for multi-inverter-based AC microgrids in the face of generally unbounded attacks. The proposed defense strategies are validated on a modified IEEE 34-bus test feeder benchmark system incorporating four inverter-based DERs.