时滞依赖H∞滤波器的有限频故障检测方法

本文研究了线性离散时滞系统的有限频鲁棒故障检测问题.利用故障估计技术,将故障检测滤波器设计问题转化为时滞依赖的H∞滤波器设计问题.本文直接给出刻画有限频故障检测性能的线性矩阵不等式条件,避免因引入加权函数而产生的不准确性.最后,仿真算例表明时滞依赖的有限频故障检测滤波器可以取得比已有结果更好的故障检测性能.     

一类线性Markov 跳跃区间时滞系统的 鲁棒??∞ 故障检测滤波器设计

研究一类线性Markov跳跃区间时滞系统的鲁棒H∞故障检测滤波器设计问题.采用基于自适应观测器的故障检测滤波器作为残差产生器,将鲁棒H∞故障检测滤波器设计问题归结为随机H∞滤波问题.应用Lyapunov-Krasovskii方法,通过引入松弛矩阵推导证明了问题可解的时滞依赖充分条件,并进一步通过求解线性矩阵不等式给出了故障检测滤波器参数矩阵的解.仿真算例验证了所提出方法的有效性.     

线性时滞系统故障检测滤波器设计H∞优化方法

研究一类线性时滞系统的基于观测器的故障检测滤波器设计问题.通过对线性时滞系统进行广义坐标变换,得到了只包含输入、输出时滞,无状态时滞的新的系统表达形式.在此基础上,选用基于观测器的故障检测滤波器作为残差产生系统,使得到的残差动态方程为仅包含未知输入时滞和故障时滞的线性时不变形式,进而可应用已取得的线性时不变系统故障诊断研究成果设计故障检测滤波器.同时给出一种线性时滞系统故障检测滤波器设计的H∞优化设计方法,并通过算例验证了所提方法的有效性.     

一类非线性时滞系统的H_∞鲁棒故障检测滤波器设计

研究一类受时变时滞影响的非线性不确定系统H∞鲁棒故障检测滤波器设计问题.首先采用基于观测器的故障检测滤波器作为残差产生器,将故障检测滤波器设计归结为H∞滤波问题;然后应用Lyapunov-Krasovskii方法,推导并证明了问题可解的依赖时滞的充分条件,通过求解线性矩阵不等式得到了观测器增益矩阵的解;最后通过算例验证了所提出方法的有效性.     

含未知输入的时滞系统的函数观测器及输出反馈镇定

考虑了含未知输入的时滞系统的线性函数观测器设计.在一个不失一般性的秩条件假定下,以线性矩阵不等式(LMI)的形式给出了观测器存在的时滞无关型及时滞相关型判据,进而得到函数观测器改进的设计方法.此外,还讨论了降维状态观测器的设计,给出了基于观测器的反馈镇定控制器,实现了闭环的特征根分离及内稳定.具体算例说明了本文方法的有效性.     

Lipschitz非线性系统的H_/L∞故障检测观测器设计

针对Lipschitz非线性系统提出了一种基于H_-/L_∞故障检测观测器的设计方法.首先,利用有限频域的H_-指标来刻画观测器生成残差的最小故障敏感度,利用未知干扰到残差的L_∞范数来描述残差对干扰的鲁棒性能.其次,提出了基于L_∞范数性能指标的残差评价与动态阈值生成方法.此外,给出了H_-/L_∞故障检测观测器的存在条件并整理成线性矩阵不等式.最后,仿真算例验证了本文所提方法的正确性与有效性.     

基于概率密度函数的时滞依赖故障检测与诊断

针对包含时滞的随机分布系统,提出了一种基于概率密度函数（PDF）的时滞依赖故障检测与诊断方法。建立了基于PDF信息的故障检测残差,利用故障检测与诊断理论,设计了基于线性矩阵不等式的故障检测观测器和故障估计器,并且通过了稳定性分析,实现了对该系统的故障检测以及估计。通过数值仿真,证明了该方法的有效性。     

基于时滞依赖H ∞滤波器的时滞系统故障诊断

针对一类具有不确定输入的状态时滞系统,基于时滞依赖H∞滤波器探讨了系统的鲁棒故障诊断(RFD)问题.首先,引入一个参考模型,形成广义残差系统,以此广义残差信号对扰动信号及其故障信号L2的增益来体现其对扰动的鲁棒性和对故障的灵敏性;其次,利用对偶原理,针对对偶系统,借助线性矩阵不等式(LM I)技术,研究基于状态观测器的时滞依赖RFD系统设计问题,并推导出具有时滞依赖解存在的条件及观测器增益矩阵的求解方法;最后,通过仿真实例验证了该方法的可行性和有效性.     

一种新的基于自适应观测器中立时滞系统故障估计的设计方法

研究了基于自适应观测器中立时滞系统的故障估计问题. 首先, 本文提出了一种新的快速自适应故障估计算法提升了故障估计的快速性和准确性. 同时, 一个时滞相关的判据用于减少设计过程中的保守性, 特别对于小时滞系统. 然后, 应用线性矩阵不等式技巧, 给出了详细的设计步骤. 最后, 仿真结果验证了所提方法的有效性.     

在低频域内对线性时滞系统的故障检测滤波器设计

对线性时滞系统, 本文在低频域内考虑了故障检测问题. H∞范数用来度量外界扰动, H-指标用来度量故障敏感性. 本文主要结果包括得到了故障检测观测器存在的充分条件而且通过解线性矩阵不等式得到了观测器的增益解. 最后, 数值例子解说明了本文方法的有效性.     

A finite frequency domain approach to fault detection for linear discrete-time systems

This paper deals with the fault detection (FD) problem in the finite frequency domain for linear time-invariant discrete-time systems with bounded disturbances. A fault detection observer is designed by employing two performance indesxes which are used to increase the fault sensitivity in finite frequency domain and attenuate the effects of disturbances in full frequency domain. With the aid of the generalized Kalman–Yakubovich–Popov (GKYP) Lemma, the design methods are presented in terms of solutions to a set of linear matrix inequalities (LMIs). Numerical examples are given to illustrate the effectiveness of the proposed method.     

线性系统的H2/H-故障检测优化方法设计

针对一类具有未知扰动的线性系统的故障检测(FD)问题,通过对系统进行重构,设计出了系统的H2/H-优化FD观测器。利用构造的Lyapunov函数和线性矩阵不等式,证明并给出了FD观测器有解的充分条件和优化设计方法。所设计的观测器使系统具有渐近稳定性,抑制干扰能力强,满足所给的范数指标。仿真结果验证了所设计方法的有效性。     

Asynchronous fault detection observer design for discrete‐time piecewise linear systems

This paper studies the problem of asynchronous fault detection (FD) observer design for piecewise linear systems. Considering that the states of the FD observer and the system may stay at different regions of the state space, asynchronous FD observers are designed at different instants to cope with the challenges incurred by exogenous disturbances and fault signals. By employing new piecewise Lyapunov functions that depend on the different regions where the states are located, it is proved that the proposed asynchronous FD observers ensure the stability and H_∞ performance of the error systems. Three examples are given to show that the new design scheme provides better FD results than the existing design methods.     

Fault detection for discrete-time LPV systems using interval observers

This paper is concerned with the fault detection (FD) problem for discrete-time linear parameter-varying systems subject to bounded disturbances. A parameter-dependent FD interval observer is designed based on parameter-dependent Lyapunov and slack matrices. The design method is presented by translating the parameter-dependent linear matrix inequalities (LMIs) into finite ones. In contrast to the existing results based on parameter-independent and diagonal Lyapunov matrices, the derived disturbance attenuation, fault sensitivity and nonnegative conditions lead to less conservative LMI characterisations. Furthermore, without the need to design the residual evaluation functions and thresholds, the residual intervals generated by the interval observers are used directly for FD decision. Finally, simulation results are presented for showing the effectiveness and superiority of the proposed method.     

Unknown Input Fault Detection and Isolation Observer Design for Neutral Systems

This paper deals with actuator fault diagnosis of neutral delayed systems with multiple time delays using an unknown input observer. The main purpose is to design an observer that guarantees the asymptotic stability of the estimate error dynamics and the actuator fault detection. The existence conditions for such an observer are established. The main problem studied in this paper aims at designing observer‐based fault detection and isolation. The designed observer enhances the robust diagnosis performance, including rapidity and accuracy, and generates residuals that enjoy perfect decoupling properties among faults. Based on Lyapunov stability theory, the design of the observer is formulated in terms of linear matrix inequalities, and the diagnosis scheme is based on a bank of unknown input observers for residual generation that guarantees fault detection and isolation in the presence of external disturbances. A numerical example is presented to illustrate the efficiency of the proposed approach.     

Fault detection for singular switched linear systems with multiple time-varying delay in finite frequency domain

This paper deals with the problem of the fault detection (FD) for continuous-time singular switched linear systems with multiple time-varying delay. In this paper, the actuator fault is considered. Besides, the systems faults and unknown disturbances are assumed in known frequency domains. Some finite frequency performance indices are initially introduced to design the switched FD filters which ensure that the filtering augmented systems under switching signal with average dwell time are exponentially admissible and guarantee the fault input sensitivity and disturbance robustness. By developing generalised Kalman–Yakubovic–Popov lemma and using Parseval's theorem and Fourier transform, finite frequency delay-dependent sufficient conditions for the existence of such a filter which can guarantee the finite-frequency H_? and H_∞ performance are derived and formulated in terms of linear matrix inequalities. Four examples are provided to illustrate the effectiveness of the proposed finite frequency method.     

Fault detection for a class of impulsive switched systems

The problem of fault detection for a class of nonlinear impulsive switched systems is investigated in this paper. Fault detection filters are designed such that the augmented systems are stable, and the residual error signal generated by the filters guarantees the H∞ performance for disturbances and faults. Sufficient conditions for the design of fault detection(FD) filters are presented by linear matrix inequalities. Moreover, the filter gains are characterized according to a solution of a convex optimization. Finally, an example derived from a pulse-width-modulation-driven boost converter is given to illustrate the effectiveness of the FD design approach.     

A stable fault detection observer design in finite frequency domain

This article addresses the stable fault detection observer design problem for linear time-invariant continuous-time systems in finite-frequency domain. The fault detection filter design is a synthesised optimal Luenberger observer that guarantees two requested performance indexes of fault sensitivity and stability. With the aid of generalised Kalman–Yakubovich–Popov lemma and increasing dimensions of slack variable matrix, the stability and H _? performance analysis of the closed-loop system with a fault detection observer has been translated into a convex linear matrix inequality (LMI) optimisation problem to avoid the complexity of system associated with weight functions. An iterative LMI algorithm has been presented for the fault detection observer design. The effectiveness of proposed approaches is demonstrated by two numerical examples.