Title :
Disturbance Attenuation in Fault Detection of Gas Turbine Engines: A Discrete Robust Observer Design
Author :
Dai, Xuewu ; Gao, Zhiwei ; Breikin, Tim ; Wang, Hong
fDate :
3/1/2009 12:00:00 AM
Abstract :
This study is motivated by the onboard fault detection of gas turbine engines (GTEs), where the computation resources are limited and the disturbance is assumed to be band-limited. A fast Fourier transformation (FFT)-based disturbance frequency estimation approach is proposed and performance indexes are improved by integrating such frequency information. Furthermore, in the left eigenvector assignment, both eigenvalues and free parameters are optimized. As illustrated in the application to the actuator fault detection of a GTE, significant improvements are achieved compared to the existing methods. By combining the frequency estimation and eigenvalue optimization, the main contribution of the paper is the reduction of the computation complexity and the avoidance of the local optimal solution due to fixed eigenvalues.
Keywords :
actuators; computational complexity; control system synthesis; discrete systems; eigenvalues and eigenfunctions; engines; failure analysis; fast Fourier transforms; fault diagnosis; flaw detection; frequency estimation; gas turbines; observers; optimisation; robust control; actuator fault detection; computation complexity; discrete robust observer design; disturbance attenuation; eigenvalue optimization; eigenvector assignment; fast Fourier transformation-based disturbance frequency estimation approach; gas turbine engine; performance index; Fast Fourier transformation (FFT); fault detection; gas turbine engine (GTE); robust observer design;
Journal_Title :
Systems, Man, and Cybernetics, Part C: Applications and Reviews, IEEE Transactions on
DOI :
10.1109/TSMCC.2008.2005845
