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Review of Information Engineering and Applications

June 2019, Volume 6, 2, pp 29-36

Speed Control of Induction Motor on C2000 DSP Platform

Nguyen Hong Quang

Nguyen Hong Quang 1

  1. Department of Automation, Faculty of Electrical Engineering, Thai Nguyen University of Technology (TNUT), Viet Nam. 1

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on PubMed

Pages: 29-36

DOI: 10.18488/journal.79.2019.62.29.36

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Article History:

Received: 04 September, 2019
Revised: 07 October, 2019
Accepted: 13 November, 2019
Published: 11 December, 2019


Three-phase AC motors are widely used in the industry. Nowadays, it accounts for 90% of the motors used in engine applications in technological lines. Control methods for this object are also quite complete and installed in industrial inverters in commerce. For commercial equipment, operators must not interfere with the control structure due to the closed nature of the system. For small-scale applications and applications that require operators, it is necessary to intervene in the control structure to customize the technology process. However, it cannot be done with commercially available equipment. Therefore, the authors propose a solution to build a standardized hardware system that can interfere with the control structure using the C2000 family microcontroller. The advantage of this solution is that it is inexpensive and allows us to install different algorithms. Besides, it is possible to connect to PC via Matlab/Simulink in real-time control problem.
Contribution/ Originality
This study contributes to the existing literature by investigating the application of DSP C2000 in the control of alternating current electric motors creates an open system. Therefore, the operator can intervene directly in the control structure, which is not possible with commercial devices. This is particularly suitable for specialized applications that need to be customized according to technology.


IM, C2000, FOC, V/f Control, PWM.


[1]          N. Quang and J. Dittrich, Vector control of three-phase AC machines – system development in the practice: Springer Berlin Heidelberg, 2008.

[2]          B. Ion and A. N. Syed, The induction machine handbook: CRC Press, 2002.

[3]          K. B. Pabitra, K. B. Manoj, and K. S. Amit, "Speed Control of Induction Motor using Scalar Control," International Journal of Computer Applications, vol. 975, p. 8887, 2014.

[4]          F. El-Faouri, O. Mohamed, and W. Abu-Elhaija, "D-Q model and control of a three-phase induction motor considering mutual flux saturation effect," pp. 1-6, 2017.

[5]          Texas Intruments, "Texas intruments, scalar (V/f) control of 3-phase induction motors (2013), application report, SPRABQ8-July 2013," 2013.

[6]          N. H. Quang, N. P. Dao, H. M. Nguyen, T. T. Nguyen, and C. P. Nguyen, "Design an exact linearization controller for permanent stimulation synchronous linear motor polysolenoid," SSRG International Journal of Electrical and Electronics Engineering, vol. 4, pp. 7-12, 2017. Available at:

[7]          N. H. Quang, "Multi parametric programming based model predictive control for tracking control of polysolenoid linear motor," Special issue on Measurement, Control and Automation, vol. 19, pp. 31-37, 2017.

[8]          H. Q. Nguyen, P. Q. Nguyen, N. H. Nguyen, and T. B. Nguyen, "Min max model predictive control for polysolenoid linear motor," International Journal of Power Electronics and Drive Systems, vol. 9, pp. 1666-1675, 2018. Available at:

[9]          H. Q. Nguyen, P. Q. Nguyen, D. P. Nam, and T. B. Nguyen, "Multi parametric model predictive control based on laguerre model for permanent magnet linear synchronous motors," International Journal of Electrical and Computer Engineering, vol. 9, pp. 1067-1077, 2019. Available at:

[10]        P. N. Dao, "Multi parametric programming and exact linearization based model predictive control of a permanent magnet linear synchronous motor," in International Conference on System Science and Engineering, 2017, pp. 743-747.

[11]        A. Bilal and B. Manish, Sensored field oriented control of 3-Phase induction motors, C2000 systems and applications: Texas Instruments, Inc, 2013.

[12]        E. K. Karrar and S. M. Ajang, "Field oriented control of induction motor," 2010.

[13]        Z. Dong, Y. Yong, L. Wenshuang, B. Wang, and X. Dianguo, "Flux-weakening control for induction motor in voltage extension region: Torque analysis and dynamic performance improvement," IEEE Transactions on Industrial Electronics, 2018.

[14]        A.-R. Haitham, I. Atif, and G. Jaroslaw, High performance control of AC drives with MATLAB/Simulink models: John Wiley & Sons, 2012.

[15]        A. Bilal and C. Chris, "Digital motor control methodology for C2000™ Real-Time control microcontrollers, texas instruments," 2010.

[16]        Texas, "Texas intruments, TMS320F2806x Piccolo™ microcontrollers datasheet (Rev. G)," 2018.

[17]        Texas, "Texas intruments, launchxl - F28069 overview," 2019.

[18]        Texas, "Texas intruments, TMS320x2806x piccolo technical reference guide," 2017.

[19]        L.-F. Shi, F.-B. Liu, H.-S. He, X.-Y. Mao, and X.-Q. Lai, "Design of adaptive dead-time control circuit for resonant half-bridge driver," International Journal of Electronics, vol. 100, pp. 1317-1331, 2013. Available at:

[20]        Agilent, "Agilent technilogies, isolation amplifier technical data," 2002.

[21]        Math, "Math work, induction machine scalar control," 2019.


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This study received no specific financial support.

Competing Interests:

The author declares that there are no conflicts of interests regarding the publication of this paper.


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