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About the Journal
News
Publication Ethics and Publication Malpractice Statement
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PEAD in Sciendo
Special Section
Special Section in 2024 vol. 9 (44) - Modern Control Methods of Electrical Drives
Special Section in 2024 vol. 9 (44) - Renewable Energy Conversion and Energy Storage Systems
Special Section in 2023 vol. 8 (43) - Artificial Intelligent Based Designs and Applications for the Control of Electrical Drives
Special Section in 2023 vol. 8 (43) - Advanced Control Methods of Electrical Machines and Drives
Optimisation of Model Predictive Torque Control Strategy with Standard and Multi-Objective Genetic Algorithms
1
Ege University
2
Nigde Omer Halisdemir University
Power Electronics and Drives 2023;8(Special Section - Artificial Intelligent Based Designs and Applications for the Control of Electrical Drives )
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ABSTRACT
In this paper, the flux error-related weighting factor (WF) of the predictive torque control (PTC) strategy for induction motor (IM) control is optimised by a standard genetic algorithm (SGA) through speed errors only and multi-objective genetic algorithm (MOGA) through torque and flux errors. This paper compares the performances of both optimisation methods. Compared to MOGA, SGA offers a straightforward way to select WF and does not need a decision-making method to choose a final solution. But MOGA considers the given problem in a multi-objective way and directly optimises the control objectives of the PTC strategy. Comparisons are made over the flux and torque ripples, total harmonic distortion of stator phase current, and average switching frequency for different operating conditions. Simulation results show that both methods choose a close WF value. Consequently, SGA stands out in the optimisation of the PTC strategy with its simple structure.
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| eISSN: | 2543-4292 |
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