Direct power control of three-phase PWM-rectifier with backstepping control

Abstract Pulse Width Modulation (PWM) rectifiers belong to the best solutions to improve the quality of electrical energy transfer from a source to a receiver. In fact, this chapter proposes a method for regulating the three-phase PWM rectifier and ensuring the elimination of total harmonic distortion to obtain a non-contaminated system operating within a unity power factor. This regulation method is contracted via analogy to the direct torque control (DTC) of an electrical machine. In place of the torque and stator flux, active and reactive power are the corrected variables. That work suggests the study of a direct power control (DPC) of a three-phase PWM rectifier by deploying a backstepping for the correction of the DC bus voltage. The assessment of the validity and dynamic performance of the control methods was checked by simulation using MATLAB / SIMULINK environment under various conditions, such as the variation of the reference voltage and the load. The results of the simulation showed the robustness of direct power control based on the backstepping control technique.

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