Title :
A method for the design of fault-tolerant systems in case of sensor and actuator faults
Author :
Kanev, S. ; Verhaegen, M. ; Nijsse, G.
Author_Institution :
TN/SCE, Univ. of Twente, Enschede, Netherlands
Abstract :
In this paper a new approach for fault-tolerant control (FTC) of systems subjected to multiple sensor and multiple actuator faults is presented. A model set is designed in such a way that the system in its normal or in each possible faulty mode of operation can be represented as a linear combination of the models in the model set. A possible way of selecting the model set in cases of sensor and actuator faults is presented. A recursive parameter estimation algorithm, in combination with a recursive Kalman filter, are used to produce estimates of the weights in the linear combination. These estimates are then used for reconfiguration of a generalized predictive controller. The proposed algorithm is illustrated in a case study using a linearized model of one joint of a real-life space robot manipulator, subjected to faults.
Keywords :
Kalman filters; aerospace robotics; control system synthesis; fault tolerant control; linearisation techniques; manipulators; optimal control; predictive control; recursive estimation; stability; FTC; actuator fault; fault-tolerant control; fault-tolerant system design; faulty operation mode; generalized predictive controller; linearized model; model set design; optimal reconfiguration; real-life space robot manipulator; recursive Kalman filter; recursive parameter estimation algorithm; sensor fault; stable reconfiguration; weight estimate; Actuators; Algorithm design and analysis; Equations; Fault tolerance; Fault tolerant systems; Mathematical model; Robot sensing systems; Fault-Tolerant Control; Quantitative and Qualitative Methods of Fault Diagnosis;
Conference_Titel :
Control Conference (ECC), 2001 European
Conference_Location :
Porto
Print_ISBN :
978-3-9524173-6-2
