Title :
Finite-horizon H∞ fault estimation for linear time-delay systems
Author :
Xinmin Song ; Xuehua Yan
Author_Institution :
Sch. of Inf. Sci. & Eng., Shandong Normal Univ., Jinan, China
Abstract :
This paper investigates the finite-time H∞ fault estimation problem for linear time-delay systems, where the delay appears in both state and measurement equations. Firstly the design of finite horizon H∞ fault estimation is converted into a minimum problem of certain quadratic form. Then we introduce an stochastic system in Krein space, a sufficient and necessary condition for the minimum is derived by applying innovation analysis approach and projection theory. Finally a solution to the H∞ fault estimation is obtained by recursively computing a partial difference Riccai equation, which has the same dimension as the original system. Compared with the conventional augmented approach, the solving of an high dimension Riccati equation is avoided.
Keywords :
H∞ control; Riccati equations; control system synthesis; delays; fault tolerant control; linear systems; partial differential equations; stochastic systems; Krein space; fault estimation design; finite-horizon H∞ fault estimation; innovation analysis approach; linear time-delay systems; measurement equation; necessary condition; partial difference Riccati equation; projection theory; quadratic form; state equation; stochastic system; sufficient condition; Covariance matrices; Data structures; Delays; Estimation; Fault detection; Riccati equations; Technological innovation; Fault Detection; Indefinite Quadratic Form; Krein Space; State Estimate; Time Delay;
Conference_Titel :
Control Conference (CCC), 2014 33rd Chinese
Conference_Location :
Nanjing
DOI :
10.1109/ChiCC.2014.6895475
