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In this paper, a Fault Tolerant Control (FTC) strategy for Linear Parameter Varying (LPV) systems that can be used in the case of actuator faults is proposed. The idea of this FTC method is to adapt the faulty plant instead of adapting the controller to the faulty plant. This approach can be seen as a kind of virtual actuator. An integrated FTC design procedure for the fault identification and fault-tolerant control schemes using LPV techniques is provided as well. Fault identification is based on the use of an Unknown Input Observer (UIO). The FTC controller is implemented as a state feedback controller and designed using polytopic LPV techniques and Linear Matrix Inequality (LMI) regions in such a way as to guarantee the closed-loop behavior in terms of several LMI constraints. To assess the performance of the proposed approach, a two degree of freedom helicopter is used.
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Tom
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161--171
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Bibliogr. 29 poz., rys., wykr.
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autor
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- Advanced Control Systems Group (SAC), Institute of Robotics and Industrial Informatics (IRI-CSIC) Technical University of Catalunya (UPC), Pau Gargallo, 5, 08028 Barcelona, Spain, saul.montes.de.oca@upc.edu
Bibliografia
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- [7] Chilali, M. and Gahinet, P. (1996). H-infinity design with pole placement constraints: An LMI approach, IEEE Transactions on Automatic Control 41(3): 358-367.
- [8] Dziekan, Ł. (2011). Neuro-Fuzzy-Based Takagi-Sugeno Modelling in Fault-Tolerant Control, Lecture Notes in Control and Computer Science, Vol. 16, University of Zielona Góra Press, Zielona Góra.
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- [12] Hallouzi, R., Verdult, V., Babuska, R. and Verhaegen, M. (2005). Fault detection and identification of actuator faults using linear parameter varying models, 16th IFAC Triennial World Congress, Prague, Czech Republic, pp. 119-124.
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- [17] Lunze, J. (2006). Control reconfiguration after actuator failures: The generalised virtual actuator, Proceedings of the 6th IFAC Symposium on Fault Detection, Supervision and Safety for Technical Processes (SAFEPROCESS), Beijing, China, pp. 1309-1314.
- [18] Maki, M., Jiang, J. and Hagino, K. (2004). A stability guaranteed active fault-tolerant control system against actuator failures, International Journal of Robust and Nonlinear Control 14(12): 1061-1077.
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- [23] Rodrigues, M., Theilliol, D., Aberkane, S. and Sauter, D. (2007). Fault tolerant control design for polytopic LPV systems, International Journal of Applied Mathematics and Computer Science 17(1): 27-37, DOI: 10.2478/v10006-007-0004-5.
- [24] Rodrigues, M., Theilliol, D., Medina, M. A. and Sauter, D. (2008). A fault detection and isolation scheme for industrial systems based on multiple operating models, Control Engineering Practice 16(2): 225-239.
- [25] Rodrigues, M., Theilliol, D. and Sauter, D. (2005). Design of an active fault tolerant control and polytopic unknown input observer for systems described by a multi-model representation, 44th IEEE Conference on Decision and Control/European Control Conference ECC, Sevilla, Spain, pp. 3816-3820.
- [26] Wan, Z. and Kothare, M. V. (2003). Efficient scheduled stabilizing output feedback model predictive control for constrained nonlinear systems, Proceedings of the American Control Conference, Denver, CO, USA, Vol. 1 (4-6), pp. 489-494.
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Bibliografia
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bwmeta1.element.baztech-article-BPZ7-0001-0012