Vienna rectifier with voltage outer loop sliding mode control based on an RBF neural network

被引：0

作者：

Yang X. ^{[1
]}

Chen Y. ^{[1
]}

Jia W. ^{[2
]}

Fang J. ^{[1
]}

Luo X. ^{[1
]}

Gao Z. ^{[1
]}

机构：

[1] School of Automation Engineering, Shanghai Electric Power University, Shanghai

[2] Shanghai Solar Energy Engineering Technology Research Center, Shanghai

来源：

Dianli Xitong Baohu yu Kongzhi/Power System Protection and Control | 2022年 / 50卷 / 18期

基金：

中国国家自然科学基金;

关键词：

near rate; RBF neural network; sliding mode variable structure control; Vienna rectifier; voltage outer ring;

D O I：

10.19783/j.cnki.pspc.211361

中图分类号：

学科分类号：

摘要：

A Vienna rectifier is used as the research object, and an adaptive voltage outer loop sliding mode control algorithm based on the approximation rate is analyzed for its traditional voltage outer loop sliding mode variable structure control invariance and sensitivity to system parameter perturbation. By effectively combining the RBF neural network with the sliding mode control algorithm, the algorithm also adds the midpoint potential balance control to the design of the RBF neural network adaptive voltage outer-loop sliding mode control algorithm. It uses the RBF neural network for adaptive approximation of the voltage outer-loop nonlinear system. This can effectively reduce the switching gain, weaken the jitter and enhance the anti-interference capability of the system. Lastly, simulation analysis and experimental tests are conducted to verify the effectiveness of the proposed control algorithm. The algorithm is compared with the traditional sliding mode control algorithm and the PI control algorithm, and the results show that the use of this voltage external loop control algorithm can provide fast tracking of the target value of the DC output voltage and balanced midpoint potential. This improves the dynamic and static performance of the system and enhances its anti-interference capability. © 2022 Power System Protection and Control Press. All rights reserved.

引用

页码：103 / 115

页数：12

共 27 条

[1] THANGAVELU T, SHANMUGAM P, RAJ K., Modelling and control of VIENNA rectifier a single phase approach, IET Power Electronics, 8, 12, pp. 2471-2482, (2015)
[2] MA HUI, XIE, YUNXIANG, SUN, BIAOGUANG, Et al., Modeling and direct power control method of Vienna rectifiers using the sliding mode control approach, Journal of power electronics: a publications of the Korean Institute of Power Electronics, 15, 1, pp. 190-201, (2015)
[3] ZHU Wenjie, CHEN Changsong, DUAN Shanxu, Et al., A carrier-based discontinuous PWM method with varying clamped area for Vienna rectifier, IEEE Transactions on Industrial Electronics, 66, 9, pp. 7177-7188, (2019)
[4] ZHANG Li, ZHAO Rui, JU Ping, Et al., A modified DPWM with neutral point voltage balance capability for three-phase Vienna rectifiers, IEEE Transactions on Power Electronics, 36, 1, pp. 263-273, (2021)
[5] HANG Lijun, ZHANG Ming, LI Bin, Et al., Space vector modulation strategy for VIENNA rectifier and load unbalanced ability, IET Power Electronics, 6, 7, pp. 1399-1405, (2013)
[6] ZHOU Zuo, WANG Yang, LI Zhengming, Model predictive control strategy of a Vienna rectifier based on duty cycle control, Power System Protection and Control, 49, 10, pp. 162-169, (2021)
[7] XING Xiangyang, LI Xiaoyan, QIN Changwei, Et al., Two-layer pulsewidth modulation strategy for common-mode voltage and current harmonic distortion reduction in Vienna rectifier, IEEE Transactions on Industrial Electronics, 67, 9, pp. 7470-7483, (2020)
[8] FADAEIAN T, GHOLAMIAN S A, GHOREISHY H., A novel discontinuous pulse width modulation strategy based on circuit-level decoupling concept for Vienna rectifier, Revue Roumaine des Sciences Techniques. Serie Electrotechnique et Energetique, 65, 1, pp. 87-95, (2020)
[9] LI Zhengming, KONG Ming, Research on midpoint potential balance control strategy of VIENNA rectifier, Electrical Measurement & Instrumentation, 57, 6, pp. 120-125, (2020)
[10] YUAN Donglin, SHAO Ruping, XU Wenqian, Et al., Research on VIENNA rectifier control strategy based on new active disturbance rejection control, Power Electronics, 53, 12, pp. 102-105, (2019)

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