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POSITION CONTROL OF SYNCHRONOUS MACHINE USING SLIDING MODE TECHNIQUES

Journal Name:

  • Istanbul University Journal of Electrical & Electronics Engineering

Publication Year:

  • 2007

Key Words:

Author NameUniversity of Author
Abstract (2. Language): 
The sliding mode controller is designed for a class of non linear dynamic systems to tackle the problems with model uncertainties, parameter fluctuations and external disturbances. By this design, the bounds of the uncertainties are not required to be known in advance. In this paper, we develop a sliding mode controller for the robust position control of synchronous motor. Also, the load torque disturbance affects directly the motor shaft. An observer is considered to overcome the problem of torque disturbance. An asymptotically stable observer gain can be obtained without affecting the overall system response. The simulation results show the effectiveness of the proposed control strategy with desired tracking accuracy and robustness.
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  • 2
471 – 480
  • English

REFERENCES

References: 

[1] Utkin V. I., “Variable structure system with
sliding modes”, IEEE Trans. on Automatic
Control, vol. AC-22, April 1977, 210–222.
[2] Young K. D., Utkin V. I. and Özgüner Ü.,
“A control engineer’s guide to sliding mode
control”, IEEE Trans. on Control Systems
Technology, Vol. 7, No. 3, May 1999.
[3] Slotine J. J. E., Li W., Applied nonlinear
control, Prentice Hall, USA, 1998.
[4] Astrom K. J., Wittenmark B., Adaptive
control, Addison-Wesley, 1989.
[5] Guldner J., Utkin V. I., “The chattering
problem in sliding mode systems”,
Position Control Of Synchronous Machine Using Sliding Mode Techniques
Abdel Ghani AISSAOUI, Mohamed ABID, Hamza ABID, Ahmed TAHOUR
480
Fourteenth Intenational Symposium of
Mathematical Theory of Networks and
systems, MTNS2000, June 19-23, 2000,
Perpignan, France.
[6] Buhler H., Réglage par mode de glissement,
Presses polytechniques romandes, Lausanne,
1986.
[7] Utkin V. I., “Sliding mode control design
principles and applications to electrical
drives”, IEEE Trans. on Industrial
Electronics, vol. 40, NO. 1, February 1993,
23-36.
[8] Utkin V. I., Šabanović A., “Sliding modes
applications in power electronics and motion
control systems”, IEEE, International
Symposium on Industrial Electronics, Vol.
1, July 1999, pp 22-31.
[9] BOSE B. K., Power electronics and AC
drives, Prentice Hall, Englewood Cliffs,
Newjersey, 1986.
[10] Sturtzer G., Smigiel E., Modélisation et
commande des moteurs triphasés, Edition
Ellipses, 2000.
[11]Cambronne J.P., Le Moigne Ph., et Hautier
J.P., “Synthèse de la commande d’un
onduleur de tension”, J. Phys III France
pp757-778, 1996.
[12] Vas P., Vector control of AC machines,
Edition Oxford University Press, 1990.
[13] Abid M, Aissaoui. A., Bounoua H.,
“sliding mode application in speed and flux
of induction machine,” Journal of Electrical
& Electronics engineering, vo6 No 2, 197-
204, 2006.
[14] Utkin V. I., Sliding modes and their
application in variable structure system,
MIR, Moscow, 1978.
[15]Khalil H. K., Non linear system, MacMillan,
New York, 1992.
[16] J. S. Ko, J. H. Lee, S. K. Chung, and M.J.
Youn, “A robust position control of
Brushless DC motor with Dead Beat Load
Torque observer”, IEEE Transaction on
industrial Electronics, vol. 40, no. 5, pp.
512-520, 1999.
[17] G. Grellet, G. Clerc, Actionneur electrique :
principe, modèle, commande, Edition
EYROLLES, 1997.

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