Abstract
In this paper, an integrated design scheme of fault estimation (FE) and fault-tolerant control (FTC) is presented for a closed-loop system with uncertain short delay. Firstly, a closed-loop system with uncertain short delay is modeled as a system with uncertain parameters, and a bi-directional robustness interaction of uncertainty between the observer and the control system is analyzed. Then a fault estimation observer and a fault-tolerant controller are constructed, and the integrated design problem is converted into a robust control problem for the augmented system under $H_{\infty }$ performance index. Furthermore, the parameters of the fault estimation observer and fault-tolerant controller are solved by Lyapunov function and relaxation methods. Finally, the effectiveness and superiority of the proposed method are verified by an aircraft simulation.
Highlights
Modern industrial systems are becoming more complex and larger, and the probability of their failures is increasing
When the unmanned aerial vehicle (UAV) system is disturbed by external faults or changed by the working state, the signal measured by sensors cannot be fed back to the controller and actuator timely, so the fault detection and control system cannot respond accurately and timely
1) The influence of uncertainty caused by time delay on fault diagnosis performance is analyzed, considering its bi-directional robustness interaction between the observer and the control system, the integrated design of fault estimation (FE)/fault-tolerant control (FTC) is proposed
Summary
Modern industrial systems are becoming more complex and larger, and the probability of their failures is increasing. When the UAV system is disturbed by external faults or changed by the working state, the signal measured by sensors cannot be fed back to the controller and actuator timely, so the fault detection and control system cannot respond accurately and timely All these lead to the degradation of system performance and even failure [15], [16]. 1) The influence of uncertainty caused by time delay on fault diagnosis performance is analyzed, considering its bi-directional robustness interaction between the observer and the control system, the integrated design of FE/FTC is proposed. The control system (1) is dispersed at the sampling period h [23], and the equations are x(k
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