Robust fault detection filter for non-linear state-delay networked control system Online publication date: Fri, 07-Nov-2014
by Xiaomei Qi; Chengjin Zhang; Jason Gu
International Journal of Automation and Control (IJAAC), Vol. 6, No. 3/4, 2012
Abstract: A robust fault detection filter (RFDF) problem is investigated for a non-linear state-delay networked control system (NCS) with model uncertainty and data packet dropout. In both sensor-to-controller link and controller-to-actuator link, the random data packet dropouts are described by two variables, which obey the Bernoulli distribution. An observer-based RFDF is presented as a residual generator, and the residual dynamical system is modelled as a novel stochastic non-linear NCS with state-delay, model uncertainty, external disturbance. A performance index is proposed to deal with the robustness issue, which is to enhance the robustness of the residual generator against network-induced uncertainties and disturbances, without significant loss of the sensitivity of faults. Sufficient condition for asymptotically mean-square stable of this residual dynamical system is derived. Then, the desired RFDF is obtained, which is constructed in terms of certain linear matrix inequality. Finally, two numerical examples are employed to illustrate that the proposed approach performs better than the existing approaches.
Existing subscribers:
Go to Inderscience Online Journals to access the Full Text of this article.
If you are not a subscriber and you just want to read the full contents of this article, buy online access here.Complimentary Subscribers, Editors or Members of the Editorial Board of the International Journal of Automation and Control (IJAAC):
Login with your Inderscience username and password:
Want to subscribe?
A subscription gives you complete access to all articles in the current issue, as well as to all articles in the previous three years (where applicable). See our Orders page to subscribe.
If you still need assistance, please email subs@inderscience.com
Our Blog 
Follow us on Twitter 
Visit us on Facebook