Abstract

In voltage-source inverters (VSIs), dead time is used to prevent shoot-through over switching devices. However, the existence of the dead time will distort the output phase current, which degrades the performance of the inverter as well as influences the common-mode voltage (CMV), particularly in CMV elimination relevant modulation schemes, such as zero-common-mode (CM) pulsewidth modulation (PWM)-based paralleled inverters. In the light of the situation that the normal sampling-based dead-time compensation (DTC) methods are often disturbed by the current ripple, this paper introduces a novel DTC method for the VSI, which can mitigate the impact of the current ripple and improve the accuracy of DTC. The proposed method deduces the real-time current ripple, which can reconstruct the actual trajectory of phase-leg currents, and the peak values corresponding to rising and falling edges for PWM signals can be predicted. In this way, DTC can be implemented based on the direction of relevant instantaneous switching currents and finally improves the accuracy. Especially, the current-ripple-prediction-based DTC can help to improve the CMV distortion caused by the dead time for paralleled inverters with zero-CM PWM. Simulation and experimental results are provided to validate that the proposed method can be applied to different topologies and modulation schemes with good performance.