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Distributed Event-Triggered Fixed-Time Fault-Tolerant Secondary Control of Islanded AC Microgrid

Ziqiang Wang, Jie Wang, Meiling Ma, Haosen Yang, Dawei Chen, Lingling Wang, Penghan Li

2022IEEE Transactions on Power Systems41 citationsDOI

Abstract

Recently, many distributed fault-tolerant (Di-FT) secondary controls have been designed to improve the robustness of the islanded AC microgrids (MGs) to actuator faults/attacks. However, some problems still exist among the existing research: (a) the convergence speed of the faulty MG's states has not been discussed, which is important for reducing the inter-harmonic component around the fundamental frequency thereby improving the power quality; (b) large computing and sampling resources are required by the relatively high control gain for dealing with the possible serious actuator faults. Therefore, a distributed event-triggered fixed-time (Di-ET-FT) fault-tolerant secondary control of the faulty islanded AC MG is designed in this paper to release the communication burden, save the computing resources, and achieve the fixed-time convergence speed for improving power quality simultaneously. The Di-ET-FT fault-tolerant secondary control has a two-layer control framework, which are the observer layer as the upper layer and the fault-tolerant control layer as the lower layer. Meanwhile, two event-triggered strategies are designed in these two layers to decrease sample/control updating numbers and communication numbers, respectively. Zeno behavior of the Di-ET-FT fault-tolerant secondary control can be evaded effectively by proving that the interevent time is lower bounded by a positive value. The abovementioned advantages of the designed secondary control are validated by the real-time simulation based on NI-PXI simulator.

Topics & Concepts

MicrogridFault toleranceRobustness (evolution)Control theory (sociology)ActuatorControl reconfigurationComputer scienceFault (geology)Distributed computingEngineeringControl (management)Embedded systemSeismologyBiochemistryArtificial intelligenceGeologyGeneChemistryMicrogrid Control and OptimizationSmart Grid Security and ResilienceHVDC Systems and Fault Protection