Integral Sliding Mode Fault-Tolerant Control for Uncertain Linear Systems Over Networks With Signals Quantization

Summary This paper explores the finite‐time H∞ control problem for singular stochastic systems with actuator saturation and time‐varying state delay through the sliding‐mode approach. Time delay is a kind of positive differentiable bounded delay. A novel suitable switching function and a suitable sliding‐mode control law are given to guarantee that the closed‐loop actuator saturating system is singular stochastic H∞ finite‐time boundedness on the specified sliding surface. Sensor failures are taken into consideration for the error system, and sufficient criteria are provided to ensure the error system is singular stochastic finite‐time boundedness. The gain matrices of sliding‐mode controller and state observer are obtained by solving the corresponding linear matrix inequalities. Finally, simulation examples are given to illustrate the proposed method.

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Reliable finite‐time H_∞ control for singular Markovian jump system with actuator saturation via sliding‐mode approach

Liu

et al. 2018

“…The sliding mode control (also known as variable structure control) is an effective approach for practical engineering systems. Recently, sliding mode control has been widely applied in practical engineering systems . The technique can be divided into 2 stages: First, a sliding surface is designed with some appropriate performance criterion to control the system trajectories.…”

Section: Introductionmentioning

confidence: 99%

“…Recently, sliding mode control has been widely applied in practical engineering systems. [17][18][19] The technique can be divided into 2 stages: First, a sliding surface is designed with some appropriate performance criterion to control the system trajectories. Second, a discontinuous control law is considered that the system states are driven to the surface and stay there.…”

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confidence: 99%

Reliable sliding mode finite‐time control for discrete‐time singular Markovian jump systems with sensor fault and randomly occurring nonlinearities

Liu

Wang

2017

Summary This paper focuses on the problem of finite‐time H∞ control for one family of discrete‐time uncertain singular Markovian jump systems with sensor fault and randomly occurring nonlinearities through a sliding mode approach. The failure of sensor is described as a general and practical continuous fault model. Nonlinear disturbance satisfies the Lipschitz condition and occurs in a probabilistic way. Firstly, based on the state estimator, the discrete‐time close‐loop error system can be constructed and sufficient criteria are provided to guarantee the augment system is sliding mode finite‐time boundedness and sliding mode H∞ finite‐time boundedness. The sliding mode control law is synthesized to guarantee the reachability of the sliding surface in a short time interval, and the gain matrices of state feedback controller and state estimator are achieved by solving a feasibility problem in terms of linear matrix inequalities through a decoupling technique. Finally, numerical examples are given to illustrate the effectiveness of the proposed method.

“…At this situation, it is important to design robust fault-tolerant/reliable controller against actuator fault. In view of this advantage, the research of fault-tolerant control or fault-reliable control has been developed for several decades, and fruitful results have been reported [23][24][25][26][27][28][29][30]. To mention few representative works, in [31], the authors investigated H 1 fault-tolerant control problem for discrete-time piecewise linear time-delays systems with the assumption that actuator faults lie in a bounded interval.…”

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confidence: 99%

Delay‐dependent fault‐tolerant controller for time‐delay systems with randomly occurring uncertainties

Sakthivel

Selvaraj

et al. 2017

Summary This paper addresses the passivity‐based H∞ control problem for a class of time‐varying delay systems subject to nonlinear actuator faults and randomly occurring uncertainties via fault‐tolerant controller. More precisely, the uncertainties are described in terms of stochastic variables, which satisfies Bernoulli distribution, and the existence of actuator faults are assumed not only linear but also nonlinear, which is a more general one. The main objective of this paper is to design a state feedback‐reliable controller such that the resulting closed‐loop time‐delay system is stochastically stable under a prescribed mixed H∞ and passivity performance level γ>0 in the presence of all admissible uncertainties and actuator faults. Based on Lyapunov stability method and some integral inequality techniques, a new set of sufficient conditions is obtained in terms of linear matrix inequality (LMI) constraints to ensure the asymptotic stability of the considered system. Moreover, the control design parameters can be computed by solving a set of LMI constraints. Finally, two examples including a quarter‐car model are provided to show the efficiency and usefulness of the proposed control scheme. Copyright © 2017 John Wiley & Sons, Ltd.