Robust Predictive Torque Control of N*3-Phase PMSM for High-Power Traction Application

Abstract

The permanent magnet synchronous motor (PMSM) has become a core component of electromechanical energy conversion in the modern industrial field. In order to expand the application of the PMSM in the field of high-power traction, a robust predictive torque control (R-PTC) strategy for the N -segment three-phase PMSM ( N *3-phase PMSM) is proposed in this article. First, the output characteristics of the N *3-phase PMSM are illustrated with the finite-element analysis method, and the mathematical model is established. Then, the six-segment three-phase PMSM predictive control system driven by six parallel inverters is designed to generate the required torque. Furthermore, the influence of the parameter mismatch on the predicted torque and stator flux is taken into consideration based on the conventional predictive torque control (PTC). Finally, a novel R-PTC method with the proportional controller is developed for the N *3-phase PMSM, which can effectively improve the accuracy and robustness of predictive control performance under the parameters mismatch. The simulation and experimental results verify that, compared with the conventional PTC, the proposed R-PTC method can make the predicted stator flux and torque value accurately track its reference values while achieving lower stator flux and torque ripple.