Hybrid-driven-based resilient control for networked T-S fuzzy systems with time-delay and cyber-attacks. (English) Zbl 1534.93205
Summary: This work investigates design problem of the hybrid-triggered-based resilient controller for a class of Takagi-Sugeno (T-S) fuzzy systems subject to nondeterministic cyber-attacks, probabilistic time-delay, controller gain variations and actuator failures in which nondeterministic cyber-attacks and hybrid-triggered mechanism are implemented by probabilistic variables gratifying the Bernoulli distributions. To save the network resources, a new kind of hybrid-triggered-based resilient controller design is introduced. By employing Lyapunov technique together with improved Wirtinger’s integral inequalities and event-generator function, new delay-dependent sufficient conditions are constructed which assures that the resulting closed-loop system is mean square asymptotically stable and satisfies a prescribed performance. At last, two numerical examples are provided to display the effectiveness and advantage of the constructed method.
© 2023 John Wiley & Sons Ltd.
© 2023 John Wiley & Sons Ltd.
MSC:
| 93C30 | Control/observation systems governed by functional relations other than differential equations (such as hybrid and switching systems) |
| 93B35 | Sensitivity (robustness) |
| 93B70 | Networked control |
| 93C42 | Fuzzy control/observation systems |
| 93C43 | Delay control/observation systems |
| 93D20 | Asymptotic stability in control theory |
Keywords:
hybrid-triggered scheme; networked control systems; nondeterministic cyber-attacks; resilient control design; T-S fuzzy systemsReferences:
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