PARTICULARITIES OF ROTOR FIELD ORIENTATION CONTROL IMPLEMENTATION ON INDUSTRIAL DSP SYSTEMS
DOI:
https://doi.org/10.59277/RRST-EE.2025.1.3Keywords:
Digital signal processing (DSP) control, Traction system, Rotor field orientation, Induction motorAbstract
The aim of this paper is the experimental implementation and validation of field-oriented control for asynchronous machine traction systems, on the one hand, with a special interest in the motor flux estimator and the implementation intricacies specific to the DSP implementation of discrete control systems, on the other hand. The implementation was done on a prototyping dSPACE DS1103 control system for an experimental 50 kW induction motor experimental stand. The prototyping system programming was done in the MATLAB/Simulink environment. Given that the control algorithm is intended to be used in an industrial system, the control model must be suitable to be converted into production code. Therefore, the study aims to overcome the limitations of industrial DSP systems for rotor field-oriented drive systems with induction motors.
References
(1) A. Bitoleanu, M. Popescu, C.V. Suru. Implementation of rotor flux-oriented control on traction system of autonomous electric locomotives, International Conference on Electromechanical and Energy Systems (SIELMEN), 1-6 (2023).
(2) S. Benaicha. Robust sensorless speed control of an induction motor drive using a synergetic approach, Rev. Roum. Sci. Techn. – Électrotechn. Et Énerg, 68, 4, pp. 381–387 (2023).
(3) A. Ahriche, M. Kidouche, A. Idir, Y. Deia. Combining sliding mode and second Lyapunov function for flux estimation, Rev. Roum. Sci. Techn. – Électrotechn. Et Énerg, 61, 2, pp. 106-110 (2016).
(4) M. Popescu, A. Bitoleanu, C.V. Suru. Estimation of the rotor flux in the traction systems with induction motors and field-oriented control, International Conference on Electromechanical and Energy Systems (SIELMEN), Craiova, Romania, pp. 1-6 (2023).
(5) R. Bojoi, G. Griva, F. Profumo. Field-oriented control of dual three-phase induction motor drives using a Luenberger flux observer, IEEE Industry Applications Conference Forty-First IAS Annual Meeting, Tampa, FL, USA, pp. 1253-1260 (2006).
(6) X. Xu, D.W. Novotny. Implementation of direct stator flux orientation control on a versatile DSP based system, IEEE Industry Applications Society Annual Meeting, 1, pp. 404-409 (1990).
(7) U.M. Ascher, L.R. Petzold. Computer Methods for Ordinary Differential Equations and Differential-Algebraic Equations. Philadelphia: Society for Industrial and Applied Mathematics (1998).
(8) J.C. Butcher. Numerical Methods for Ordinary Differential Equations. New York: John Wiley & Sons (2003).
(9) A. Hadăr, C. Marin, C. Petre, A. Voicu. Numerical Methods in Engineering (in Romanian). Politehnica Press, București (2004).
(10) C.F. Chan Man Fong, D.D. Kee, P.N. Kaloni. Advanced Mathematics for Engineering and Science. MA, USA: World Scientific (2003).
(11) *** Real-Time Interface (RTI and RTI-MP) Implementation Guide, release 5.2, dSpace Gmbh (2006).
(12) *** Simulink Solvers – Simulink, https://www.mathworks.com/help/simulink/gui/solver.html?searchHighlight=explicit%20solver&s_tid=doc_srchtitle
(13) *** dSPACE TargetLink, Code Generator Options, Influencing the generated, optimized code, V. 1.0, December 2015.
(14) *** ControlDesk Next Generation Reference For ControlDesk 5.3, Release 2014-B, November 2014.
(15) *** ControlDesk Next Generation Experiment Guide, For ControlDesk 5.3, Release 2014-B, November 2014.
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