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Adaptive Sliding Mode Control of the Furuta Pendulum Read chapter Read first chapter

2015 | OriginalPaper | Chapter

Sliding Modes for Fault Tolerant Control

Authors : Hemza Mekki, Djamel Boukhetala, Ahmad Taher Azar

Published in: Advances and Applications in Sliding Mode Control systems

Publisher: Springer International Publishing

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Abstract

As modern technological systems increase in complexity, their corresponding control systems become more and more sophisticated. In order to increase the reliability, which is crucial topic in industrial applications. The main focus of this chapter will be on the design of fault tolerant control (FTC) strategy. Therefore, FTC has found extensive applications in multiple domains including mechanical engineering, electrical engineering, control engineering, biomedical engineering, and micro-engineering. This chapter gives a brief overview in the field of FTC (definitions, practical requirements and classification). On the other hand, give a brief introduction to the concept of sliding mode control and examine its properties. Sliding surface design and tracking requirements are also discussed. In many ways, this chapter demonstrates the true theoretical and applications depth to which the sliding mode control paradigm has been developed today in the fields of FTC. Also, highlights the benefits and give discussions of some FTC approaches based SMC. At the end, in order to introduce the concept and to prove the effectiveness of the proposed approach a permanent magnet synchronous motor (PMSM) systems case study will be presented.

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previous chapter Rigid Spacecraft Fault-Tolerant Control Using Adaptive Fast Terminal Sliding Mode
next chapter Transient Stability Enhancement of Power Systems Using Observer-Based Sliding Mode Control
Literature
Akar, M., Çankaya, İ.: Diagnosis of static eccentricity fault in permanent magnet synchronous motor by on-line monitoring of motor current and voltage. J. Electr. Electron. Eng. 9(2), 951–958 (2009)
Alwi, H., Edwards, C.: Fault tolerant control using sliding modes with online control allocation. Automatica 44(7), 1859–1866 (2008)CrossRefMathSciNetMATH
Alwi, H., Edwards, C., Tan, C.P.: Fault Detection and Fault-Tolerant Control Using Sliding Modes. Springer, London (2011)CrossRefMATH
Attou, A., Massoum, A., Chiali, E.:Sliding mode control of a permanent magnets synchronous machine. In: 2013 Fourth International Conference on Power Engineering, Energy and Electrical Drives (POWERENG), pp. 115–119. Istanbul, 13–17 May 2013, doi:10.​1109/​PowerEng.​ 6635591
Benbouzid, M.E.H., Diallo, D., Zeraoulia, M.: Advanced fault tolerant control of induction-motor drives for EV/HEV traction applications: from conventional to modern and intelligent control techniques. IEEE Trans. Veh. Technol. 56(2), 519–528 (2007)CrossRef
Bonivento, C., Isidori, A., Marconi, L., Paoli, A.: Implicit fault tolerant control: application to induction motors. Automatica 40(3), 355–371 (2004)CrossRefMathSciNetMATH
Blanke, M., Staroswiecki, M., Wu, N. E.: Concepts and methods in fault-tolerant control. In: Proceedings of the 2001 American Control Conference, vol. 4, pp. 2606–2620. Arlington, VA, 25 Jun 2001–27 Jun 2001, doi:10.​1109/​ACC.​2001.​946264
Bennett, S.M., Patton, R.J., Daley, S.: Sensor fault-tolerant control of a rail traction drive. Control Eng. Pract. 7(2), 217–225 (1999)CrossRef
Benosman, M., Lum, K.Y.: Passive actuators’ fault-tolerant control for affine nonlinear systems. IEEE Trans. Consum. Electron. 18(1), 152–163 (2010)
Corradini, M.L., Orlando, G., Parlangeli, G.: A fault tolerant sliding mode controller for accommodating actuator failures. In: 44th IEEE Conference on Decision and Control, pp. 3091–3096. Spain, 12–15 December 2005, doi:10.​1109/​CDC.​2005.​1582636
Cortés-Romero, J., Rojas-Cubides, H., Coral-Enriquez, H., Sira-Ramírez, H., Luviano-Juárez, A.: Active disturbance rejection approach for robust fault-tolerant control via observer assisted sliding mode control. Mathematical Problems in Engineering, vol. 2013, ID 609523, pp. 12. (2013)
Ebrahimi, B.M., Faiz, J., Roshtkhari, M.J.: Static, dynamic and mixed eccentricity fault diagnosis in permanent magnet synchronous motors. IEEE Trans. Industr. Electron. 56(11), 4727–4739 (2009)CrossRef
Edwards, C., Spurgeon, S.K.: Sliding Mode Control: Theory and Applications. Taylor & Francis, London (1998)
Enns, D.: Control allocation approaches. In: AIAA Guidance, Navigation and Control, pp. 98–108. (1998)
Erginer, V., Sarul, M.H.: High Performance and Reliable Torque Control of Permanent Magnet Synchronous Motors in Electric Vehicle Applications. Elektronika ir Elektrotechnika 19(7), 41–46 (2013)CrossRef
Eterno, J.S., Looze, D.P., Weiss, J.L., Willsky, A.S.: Design issues for fault-tolerant restructurable aircraft control. In: Proceeding 24th IEEE Conference on Decision and Control, Fort Lauderdale, pp. 900–905. (1985), doi:10.​1109/​CDC.​1985.​268630
Ezzat, M.: Nonlinear control of a permanent magnet synchronous motor without mechanical sensor. Ph.D. Thesis, Central School Nantes, France (2011)
Fekih, A.: Effective fault tolerant control design for nonlinear systems: application to a class of motor control system. IET Control Theory Appl. 2(9), 762–772 (2008)CrossRefMathSciNet
Fridman, L., Moreno, J., Iriarte, R.: Sliding Modes after the First Decade of the 21st Century - State of the Art. Springer, Berlin (2011)
Gouichiche, A., Boucherit, S.M., Tadjine, M., Safa, A., Messlem, Y.: An improved stator winding fault tolerance architecture for vector control of induction motor: theory and experiment. Electr. Power Syst. Res. 104(2013), 129–137 (2013)
Hamayun, M.T., Edwards, C., Alwi, H.: A fault tolerant control allocation scheme with output integral sliding modes. Automatica 49(6), 1830–1837 (2013)CrossRefMathSciNet
Härkegard, O., Glad, S.T.: Resolving actuator redundancy-optimal control versus control allocation. Automatica 41(1), 137–144 (2005)MathSciNetMATH
Hess, R.A., Wells, S.R.: Sliding mode control applied to reconfigurable flight control design. J. Guidance Control Dyn. 26(3), 452–462 (2003)CrossRef
Hung, J.Y., Gao, W.B., Hung, J.C.: Variable structure control: A survey. IEEE Trans. Industr. Electron. 40(1), 2–22 (1993)CrossRef
Isermann, R., Balle, P.: Trends in the application of model-based fault detection and diagnosis of technical processes. Control Eng. Pract. 5(5), 709–719 (1997)CrossRef
Jiang, J., Xiang, Y.: Fault-tolerant control systems: a comparative study between active and passive approaches. Annu. Rev. Control 36(1), 60–72 (2012)CrossRefMathSciNet
Jones, C.N.: Reconfigurable flight control: First year report. Cambridge University, Technical report (2005)
Klinkhieo, S.: On-line Estimation Approaches to Fault-Tolerant Control of Uncertain Systems. Ph.D. thesis, The University of Hull (2009)
Liao, F., Wang, J.L., Yang, G.H.: Reliable robust flight tracking control: An LMI approach. IEEE Trans. Control Syst. Technol. 10(1), 76–89 (2002)CrossRef
Mekki, H., Benzineb, O., Boukhetala, D., Tadjine, M.: Fault tolerant control based sliding mode application to induction motor. In: Proceeding Engineering and Technology, PET vol. 3, pp. 1–6. (2013)
Nieamann, H., Stoustrup, J.: Passive fault tolerant control of a double inverted pendulium-a case study. Control Eng. Pract. 13(8), 1047–1059 (2005)CrossRef
Noura, H., Sauter, D., Hamelin, F., Theilliol, D.: Fault tolerant control in dynamic systems application to a winding machine. IEEE Control Mag. 20(1), 33–49 (2000)CrossRef
Noura, H., Theilliol, D., Ponsart, J.C., Chamseddine, A.: Fault-Tolerant Control Systems Design and Practical Applications. Springer, London (2009)CrossRefMATH
Patton, R.J.: Fault tolerant control systems: the 1997 situation. In: Proceedings of the IFAC Safe process, pp. 1033–1055. Hull, UK (1997)
Patton, R.J., Frank, P.M., Clark, R.N.: Fault Diagnosis in Dynamic Systems: Theory and Application. Prentice-Hall, New York (1989)
Prashant, M., Jinfeng, L., Panagiotis, D.C.: Fault-Tolerant Process Control Methods and Applications. Springer, London (2013)MATH
Shin, D., Moon, G., Kim, Y.: Design of reconfigurable flight control system using adaptive sliding mode control: actuator fault. Proc. Inst. Mech. Eng. Part G J. Aerosp. Eng. 219(4), 321–328 (2005)CrossRef
Slotine, J.J.: Sliding controller design for nonlinear system. I. J. C. 4(2), 421–434 (1984)
Stengel, R.F.: Intelligent failure-tolerant control. IEEE Control Syst. 11(4), 14–23 (1991)CrossRef
Tabbache, B., Rizoug, N., Benbouzid, M.E.H., Kheloui, A.: A control reconfiguration strategy for post-sensor FTC in induction motor based EVs. IEEE Trans. Veh. Technol. 62(3), 965–971 (2013)CrossRef
Tang, R.Y.: Modern Permanent Magnet Synchronous Motor Theory and Design. Machinery Industry Press, Beijing (1997)
Teng, Q., Zhu, J., Wang, T., Lei, G.: Fault tolerant direct torque control of three-phase permanent magnet synchronous motors. WSEAS Trans. Syst. 11(8), 465–476 (2012)
Utkin, V. (ed.): Sliding Modes in Control Optimization. Springer, Berlin (1992)MATH
Utkin, V., Guldner, J., Shi, J.: Sliding Mode Control in Electromechanical Systems. Taylor & Francis, New York (1999)
Vas, P.: Parameter Estimation, Condition Monitoring and Diagnosis of Electrical Machines. Oxford Science Publications, Oxford (1994)
Xiao, B., Hu, Q., Zhang, Y.: Adaptive sliding mode fault tolerant attitude tracking control for flexible spacecraft under actuator saturation. IEEE Trans. Control Syst. Technol. 20(6), 1605–1612 (2012)CrossRefMathSciNet
Yan, X.G., Edwards, C.: Nonlinear robust fault reconstruction and estimation using a sliding mode observer. Automatica 43(2007), 1605–1614 (2007)CrossRefMathSciNetMATH
Yang, G.H., Ye, D.: Reliable H1 control of linear systems with adaptive mechanism. IEEE Trans. Autom. Control 55(1), 242–247 (2010)CrossRefMathSciNet
Zhang, Y., Jiang, J.: Bibliographic review on reconfigurable fault-tolerant control systems. Annu. Rev. Control 32(2), 229–252 (2008)CrossRef
Metadata
Title
Sliding Modes for Fault Tolerant Control
Authors
Hemza Mekki
Djamel Boukhetala
Ahmad Taher Azar
Copyright Year
2015
Book
Advances and Applications in Sliding Mode Control systems

Print ISBN: 978-3-319-11172-8

Electronic ISBN: 978-3-319-11173-5

Copyright Year: 2015

DOI
https://doi.org/10.1007/978-3-319-11173-5_15

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