Thursday , May 2 2024

Nonlinear Discrete-Time Integral Sliding Mode Control of an
Induction Motor: Real-Time Implementation

Asma CHIHI, Hechmi BEN AZZA, Mohamed JEMLI, Anis SELLAMI
Unit of research C3S, ENSIT, University of Tunis,
5 Av. Taha Hussein, BP 56, Tunis 1008, Tunisia.
asma.chihi@live.fr

ABSTRACT: This paper deals with a new design of discrete-time sliding mode control of an induction motor. Indeed, an integral switching surface is developed to ensure a high quality control with a short settling time and small zero steady state error. Besides, the integral tracking errors action improves the nonlinear system robustness and chattering reduction. Real-time experiments results are carried out using a dSpace system with DS1104 control board based on digital signal processor TMS320F240. To highlight the efficiency and applicability of the presented control scheme, a comparative study with other methods is given.

KEYWORDS: Discrete-Time Integral Sliding Mode Control; Induction Motor; Digital Signal Processor (DSP); Switching Surface.

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CITE THIS PAPER AS:
Asma CHIHI, Hechmi BEN AZZA, Mohamed JEMLI, Anis SELLAMI, Nonlinear Discrete-Time Integral Sliding Mode Control of an Induction Motor: Real-Time Implementation, Studies in Informatics and Control, ISSN 1220-1766, vol. 26(1), pp. 23-32, 2017. https://doi.org/10.24846/v26i1y201703

REFERENCES

  1. Akin, B. & Bhardwaj, M. (2013). Sensored Field Oriented Control of 3-Phase Induction Motors, Texas Instruments, 1-35.
  2. Castillo, T. B., Di Gennaro S., Loukianov, A. G. & Rivera, J. (2008). Discrete time Sliding Mode Control with Application to Induction Motors, Automatica, 44, 3036–3045.
  3. Castillo, T. B., Di Gennaro, S., Loukianov, A. G. & Rivera, J. (2004). On The Discrete-time Modelling and Control of Induction Motors with Sliding Modes, Proceedings of the 2004 American Control Conference (pp.  2598-2602).
  4. Castillo, T. B., Di Gennaro, S., Galicia, M. I., Loukianov, A. G. & Rivera, J. (2010). Indirect Discrete-time Sliding Mode Torque Control of Induction Motors, XIX International Conference on Electrical Machines (ICEM) (pp. 1-6).
  5. Chihi, A., Chbeb, A. & Sellami, A. (2015). Switching Function Optimization of Sliding Mode Control to Photovoltaic Pumping System, Advances and Applications in Sliding Mode Control Systems, 576, 463-493.
  6. Chihi, A., Sellami, A. & Khalfa, M. A. (2012). Sliding Mode Control of a Photovoltaic Pumping System, Mediterranean Elecrotechnical Conference (MELECON) (pp. 936-939).
  1. Chihi, A. & Sellami, A. (2016). Nonlinear Discrete Time Sliding Mode Control Applied to Pumping System, Advances and Applications in Nonlinear Control Systems, 635, 595-609.
  2. Dominguez, J. R. (2015). Discrete time Modelling and Control of Induction Motors by Means of Variational Integrators and Sliding Modes-Part II: Control Design, IEEE Transactions on Industrial Electronics, 62 (10), 6183-6193.
  3. Furuta, K. & Morisada, M. (1988). Implementation of Sliding Mode Control by a Digital Computer, 14 Annual Conference of Industrial Electronics Society IECON’88 (pp. 453-458).
  4. Furute, K. (1990). Sliding Mode Control of a Discrete System, Systems & Control Letters, 14 (2), 145-152.
  5. Jawad, S. A., Iqbal, J., Khan, A. A. & Mehmood, A. (2015). Disturbance-Observer-Based Robust Control of a Serial-link Robotic Manipulator using SMC and PBC Techniques, Studies in Informatics and Control, 24 (4), 401-408.
  6. Maraba, A. & Kuzucuoglu, A. E. (2011). Speed Control of an Asynchronous Motor using PID Neural Networks, Studies in Informatics and Control, 20 (3), 199-209.
  7. Ortega, R. & Taoutaou, D. (1996). A Globally Stable Discrete-Time Controller for Current Fed Induction Motors, Systems & Control Letters, 28 (3), 123-128.
  8. Proca, A., Keyhani, A., Utkin, V. & Miller, J. (2002). Discrete Time Sliding Mode, Continuous Time Sliding Mode and Vector Control of Induction Motors, International Journal of Control, 75 (12), 901-909.
  9. Robyns, B., Francois, B., Degobrt, P. & Hautier, J. P. (2012). Vector Control of Induction Machines, Desensitisation and Optimisation through Fuzzy Logic, pp. XXVI-222.
  10. Skender, M. R. & Tlemcani, A. (2016). Implementation of a New Super Twisting Mode Algorithm Controlled by dSpace: Application to Series Multicell converter, Studies in Informatics and Control, 25 (2), 255-264.
  11. Taoutaou, D., Puerto, R., Ortega, R. & Loron L. (1997). A New Field-Oriented Discrete Time Controller for Current Fed Induction Motors, Control Engineering Practice, 5 (2) 209-217.
  12. Veselic, B., Drazenovic, B. & Milosavljevic, C. (2010). Improved Discrete Time Sliding Mode Position Control Using Euler Velocity Estimation, IEEE Transactions on Industrial Electronics, 57 (11), 3840-3847.
  13.  Wang, H., Zhang, W., Tian, Y. & Qu, Q. (2015). Sliding Mode Control for Diesel Engine using Extended State Observer, Studies in Informatics and Control, 24 (4), 439-448.
  14.  Wu, M. & Chen, J. S. (2014). A Discrete-Time Global Quasi-Sliding Mode Control Scheme with Bounded External Disturbance Rejection, Asian Journal of Control, 16 (6), 1-10.

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