F.B. Salem and N. Derbel


  1. [1] B. De Fornel, La Vitesse Variable dans la Recherche etl’Industrie, Colloque sur les Entrainements Electriques `aVitesse variable, ENIT, Tunis-Tunisie, 1998, B1–B13.
  2. [2] F. Blaschke, The principal of field oriented applied to the new transvector closed loop control system for rotating field machines, Simens Review (39), 1972, 217–220.
  3. [3] G. Diana & R.G. Harley, An aid for teaching field oriented control applied to induction machines, IEEE Trans. on Power Systems, 4(3), August 1989, 1258–1262. doi:10.1109/59.32626
  4. [4] D.W. Novotny & R.D. Lorenz, Introduction to field oriented and high performance A.C. Drive, IEEE Industry Application Society Annual Meeting, Toronto, Canada, 1985, 2.1–2.65.
  5. [5] N. Derbel, A. Masmoudi, & A. Ouali, Squirrel cage induction motor drive flux oriented control emulated by neural network based control, International Conference on Electric Machines, ICEM’98, Turkey, 1998.
  6. [6] A. Nabae, K. Otsuka, H. Uchino, & R. Korosawa, An approach to flux control of induction motors operated with variable 211 frequency power supply, IEEE Trans. on Industry Applications, 16(3), 1980, 342–349.
  7. [7] D.W. Novotny & T.A. Lipo, Principles of vector control and field orientation, IEEE Industry Application Society Annual Meeting Conf., Toronto, Canada, October 1985, 2.0–2.65.
  8. [8] B. Robys, Y. Fu, H. Buyse, & F. Labrique, Flux controlperformance of an induction motor indirect F.O.C using asimplified current control strategy, Int. Conf. on Electrical Machines 2, Paris, France, 1994, 374–379.
  9. [9] P. Vas, Vector control of AC machines (Oxford, UK: Clarendon Press, 1990).
  10. [10] A. Jerbi & A. Masmoudi, Direct field oriented control implantation in a CRPWM voltage inverter fed induction machine, Proc. Int. Conf. On Artificial and Computational Intelligence For Decision, Control and Automation in Engineering and Industrial Applications (ACIDCA’2000), 2000, 118–124.
  11. [11] K. Jelassi, Positionnement d’une Machine Asynchrone par la M´ethode du Flux Orient´e, Th`ese de doctorat, INP.Toulouse, France, Juillet 1991.
  12. [12] P. Aquino, M. Feemster, D.M. Dawson, & A. Behl, Adaptive partial state feedback control of the induction motor: elimination of rotor flux and rotor velocity measurements, International Journal of Adaptative Control and Signal Processing, 14(2–3), 2000, 83–108. doi:10.1002/(SICI)1099-1115(200003/05)14:2/3<83::AID-ACS581>3.0.CO;2-6
  13. [13] V. Utkin, Sliding mode control design principles and application to electric drives, IEEE Trans. on Industry Applications, 40(1), 1993, 23–36.
  14. [14] W. Gao Hung & J.C. Hung, Variable structure control: a survey, IEEE Trans. on Industrial Electronics, 40(1), 1993, 45–55. doi:10.1109/41.184820
  15. [15] K.D. Young, V.I. Utkin, & U. Ozguner, A control engineers guide to sliding mode control, IEEE Trans. on Control Systems Technique, 7(3), 1999, 328–342. doi:10.1109/87.761053
  16. [16] M.O. Mahmoudi, N. Madani, M.F. Ben Khouris, & F. Boudjemaa, Cascade sliding mode control of a field oriented induction machine drive, The European Physical Journal, Applied Physics, 7, 1999, 277–225.

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