Event-Triggered Neural Asynchronous Control of Nonhomogeneous Markov Jump Power Systems With Hybrid Cyberattacks and Unknown States
Wende Luo, Haiyang Chen, Guangdeng Zong, Xudong Zhao
Abstract
This paper studies the observer-based event-triggered neural asynchronous control problem of nonhomogeneous Markov jump power systems (MJPSs) under hybrid cyberattacks. Both periodic denial-of-service attacks and deception attacks (DAs) are involved because of the openness of networks. An event-triggered mechanism is established to ease the network load. Besides, neural network (NN) approaches are adopted to suppress the adverse effects of DAs on nonhomogeneous MJPSs, and the hidden Markov model (HMM) is employed to capture the asynchronous phenomenon between the system mode and the controller mode. With NN approaches and HMM, an observer-based NN asynchronous controller is designed. By constructing the mode- and parameter-dependent Lyapunov function, sufficient criteria ensuring boundedness in probability for nonhomogeneous MJPSs are obtained. Then, a design algorithm is shown to simultaneously obtain the controller gains, observer gains, and event-triggering weight matrices based on the established conditions. Finally, the single-machine infinite-bus power system and 3-machine 6-bus power system are applied to justify the validity of the proposed algorithm.