Sliding Mode Control for Markovian Jump Systems With Stochastic-Sampling-Based Event-Triggered Strategy
Tianshu Xu, Yugang Niu, Zhiru Cao
Abstract
This work focuses on the event-triggered sliding mode control problem for Markovian jump systems under the stochastic sampling that randomly switches between two sampling periods. A stochastic variable is introduced to characterize the delay between the present instant and the previous sampling instant, by which a switching- like event-triggered strategy is proposed via the present sampled state and the previous transmitted state. Meanwhile, a mode-dependent sliding surface is constructed and a switching- like sliding mode controller is well designed via the triggered sampled states. By means of an improved mode-dependent looped functional, the sufficient conditions are obtained for the stochastic stability of the closed-loop system and the reachability of the specified sliding surface. Furthermore, an optimization problem is established and solved via the particle swarm optimization algorithm with the objective of reducing the sliding region. Finally, numerical simulation and practical example are provided to illustrate the proposed event-triggered control scheme under stochastic sampling.