A mode‐reduction space vector pulse width modulation control method to VIENNA rectifier yet eliminating input current distortions

• Published in: International journal of circuit theory and applications Vol. 50; no. 12; pp. 4307 - 4324
• Main Authors: Li, Zhizhong, Zhang, Yuandong, Wang, Minghao, Zhang, Guidong, Lin, Jiaqing
• Format: Journal Article
• Language: English
• Published: Bognor Regis Wiley Subscription Services, Inc 01.12.2022
• Subjects: Algorithms; Control algorithms; Control methods; Control theory; controllability; current distortions; Electric communication systems; Harmonic reduction; mode‐reduction SVPWM control; Pulse duration modulation; Rectifiers; Switching; VIENNA rectifier
• ISSN: 0098-9886; 1097-007X
• DOI: 10.1002/cta.3412

The VIENNA rectifier is of high reliability, high power density, and low complexity, which has been widely applied in telecommunication systems. However, it has 25 switching states complicating the control design. Besides, it is easy for the VIENNA rectifier to distort the input currents at zero‐crossing points, which will degrade the grid power quality. To address these problems, a novel mode‐reduction space vector pulse width modulation (SVPWM) control method is proposed in this paper. By analyzing the switching states of the VIENNA rectifier, 3‐mode, 6‐mode, and 18‐mode control framework are compared, and it is found that the 18‐mode has advanced features. Specifically, the proposed 18‐mode control algorithm will have fewer calculation steps and a simpler processing flow. More importantly, it can eliminate the input current distortions for power quality improvement. A 4 kW hardware prototype of the VIENNA rectifier is developed, and experiments have been performed to verify the harmonic reduction feature of the proposed 18‐mode control. In this paper, a novel mode‐reduction space vector pulse width modulation (SVPWM) control method is proposed for VIENNA rectifier. Based on the m‐mode controllability theory, this method simplifies the traditional 25‐mode control to 18‐mode control, which not only has fewer calculation steps and a simpler processing flow but also eliminates the input current distortion for power quality improvement. A 4 kW hardware prototype verifies the harmonic reduction feature of the proposed 18‐mode control.