Space vector PWM for a two-phase VSI

Abstract

This paper proposes space vector pulse width modulation (SVPWM) technique to control a two-phase full bridge voltage source inverter (VSI) having reduced number of static switches with higher phase voltage output. SVPWM gives higher fundamental component amplitude, provides more efficient use of DC supply voltage and generates less harmonic distortion in the output voltages and currents than other pulse width modulation (PWM) techniques. Between asymmetric and symmetric SVPWM only symmetric one is considered so that the harmonic contents are minimized and two different timing sequences and corresponding switching states are proposed. For the implementation three level switching patterns are determined by using software. For real time application these theoretically determined switching signals for the six power transistors are generated by a digital signal processor (DSP) kit and finally the two-phase output voltages are applied to load. The experimental results are found good and in agreement with the theoretical results. Mathematical analysis along with theoretical and experimental performance of the proposed inverter are presented. Total harmonic distortion (THD) and distortion factor (DF) show that the output voltage quality is good enough to apply in any type of practical two-phase load.