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Fault Estimation and Tolerant Control for Discrete-Time Multiple Delayed Fuzzy Stochastic Systems With Intermittent Sensor and Actuator Faults

Shaoxin Sun, Huaguang Zhang, Juan Zhang, Kun Zhang

2020IEEE Transactions on Cybernetics39 citationsDOI

Abstract

This article is concerned with observer-based fault estimation (FE) and tolerant controller design for a series of discrete-time Takagi-Sugeno (T-S) fuzzy stochastic systems. There exist multiple time-varying state delays, intermittent sensor and actuator faults, nonlinear dynamics, and exogenous disturbances in the systems. Compared with the results of the existence, this approach suggested in this article is more flexible and feasible. By means of the FE information, a novel fuzzy adaptive descriptor observer is developed to obtain the error dynamics. Then, an active observer-based fault-tolerant controller is designed to stabilize the closed-loop fuzzy system. Furthermore, a set of delay-dependent sufficient conditions are provided by the fuzzy Lyapunov function with the way of linear matrix inequalities (LMIs), which has less conservatism compared with the ones of the existing observers and fault-tolerant controllers. Finally, a simulation example is shown to illustrate the advantages and effectiveness of this approach depicted in this article.

Topics & Concepts

Control theory (sociology)Observer (physics)ActuatorFuzzy logicLyapunov functionNonlinear systemDiscrete time and continuous timeComputer scienceController (irrigation)Fault toleranceFuzzy control systemLinear matrix inequalityMathematicsControl (management)Mathematical optimizationArtificial intelligencePhysicsAgronomyBiologyStatisticsDistributed computingQuantum mechanicsStability and Control of Uncertain SystemsNeural Networks Stability and SynchronizationCybersecurity and Information Systems
Fault Estimation and Tolerant Control for Discrete-Time Multiple Delayed Fuzzy Stochastic Systems With Intermittent Sensor and Actuator Faults | Litcius