Abstract
In this paper, the design of hybrid H-infinity synchronization control for continuous chaotic systems based on sliding mode control (SMC) is considered. H-infinity discrete sliding mode controllers integrated with the digital redesign approach are newly designed to achieve robust chaos synchronization. By the proposed design procedure, an H-infinity discrete-time SMC can be easily obtained to guarantee the robustness of synchronization even if the system is disturbed with unmatched perturbations. Besides, since the saturation function is adopted to eliminate the unexpected chattering phenomenon, this paper also discusses the effect of saturation function in multi-input multi-output (MIMO) SMC and the upper bounds of sliding mode trajectories are obtained which is not indicated in the literature. Finally, we perform the simulation to verify the effectiveness of the proposed controller.
Highlights
Chaotic systems have been widely discussed and studied. Chaotic systems are the systems producing nonlinear characteristics with complex dynamic behavior
In recent decades, chaotic systems have been widely discussed and studied
We will consider the hybrid H-infinity synchronization control for continuous chaotic systems based on digital redesigned sliding mode control (SMC)
Summary
Chaotic systems have been widely discussed and studied. Chaotic systems are the systems producing nonlinear characteristics with complex dynamic behavior. We will consider the hybrid synchronization control for continuous-time chaotic systems by using digital-redesign-based controllers. We will consider the hybrid H-infinity synchronization control for continuous chaotic systems based on digital redesigned SMC.
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