Low-Frequency Current Oscillation Reduction for Six-Step Operation of Three-Phase Inverters

Abstract

This paper investigates a control method to significantly reduce the low-frequency current oscillation for six-step operation of a three-phase inverter. The six-step operation of an ac electric machine drive system under high speeds has a few advantages compared with pulse width modulation (PWM) operation including reduced switching losses, a better utilization of the dc bus voltage, and an enhanced speed capability. In digital implementation of the six-step control, power electronics may not be able to switch on and off exactly at the zero crossing points of reference voltages, which will result in a dc offset in phase voltages and cause a low-frequency oscillation in phase currents. The low-frequency oscillation will create issues such as higher power losses, lower efficiency, and excessive heat that may demagnetize magnets on the rotor for a permanent magnet synchronous machine. This research presents a control algorithm using asymmetric PWM to ensure that power electronics switch on and off exactly at the reference voltage zero crossing points. Both simulation and experimental results demonstrate the algorithm can reduce the low-frequency oscillation in phase currents by more than 90%.