Search search
Publication Date
to
Vol. 148
Latest Volume
All Volumes
PIERC 154 [2025] PIERC 153 [2025] PIERC 152 [2025] PIERC 151 [2025] PIERC 150 [2024] PIERC 149 [2024] PIERC 148 [2024] PIERC 147 [2024] PIERC 146 [2024] PIERC 145 [2024] PIERC 144 [2024] PIERC 143 [2024] PIERC 142 [2024] PIERC 141 [2024] PIERC 140 [2024] PIERC 139 [2024] PIERC 138 [2023] PIERC 137 [2023] PIERC 136 [2023] PIERC 135 [2023] PIERC 134 [2023] PIERC 133 [2023] PIERC 132 [2023] PIERC 131 [2023] PIERC 130 [2023] PIERC 129 [2023] PIERC 128 [2023] PIERC 127 [2022] PIERC 126 [2022] PIERC 125 [2022] PIERC 124 [2022] PIERC 123 [2022] PIERC 122 [2022] PIERC 121 [2022] PIERC 120 [2022] PIERC 119 [2022] PIERC 118 [2022] PIERC 117 [2021] PIERC 116 [2021] PIERC 115 [2021] PIERC 114 [2021] PIERC 113 [2021] PIERC 112 [2021] PIERC 111 [2021] PIERC 110 [2021] PIERC 109 [2021] PIERC 108 [2021] PIERC 107 [2021] PIERC 106 [2020] PIERC 105 [2020] PIERC 104 [2020] PIERC 103 [2020] PIERC 102 [2020] PIERC 101 [2020] PIERC 100 [2020] PIERC 99 [2020] PIERC 98 [2020] PIERC 97 [2019] PIERC 96 [2019] PIERC 95 [2019] PIERC 94 [2019] PIERC 93 [2019] PIERC 92 [2019] PIERC 91 [2019] PIERC 90 [2019] PIERC 89 [2019] PIERC 88 [2018] PIERC 87 [2018] PIERC 86 [2018] PIERC 85 [2018] PIERC 84 [2018] PIERC 83 [2018] PIERC 82 [2018] PIERC 81 [2018] PIERC 80 [2018] PIERC 79 [2017] PIERC 78 [2017] PIERC 77 [2017] PIERC 76 [2017] PIERC 75 [2017] PIERC 74 [2017] PIERC 73 [2017] PIERC 72 [2017] PIERC 71 [2017] PIERC 70 [2016] PIERC 69 [2016] PIERC 68 [2016] PIERC 67 [2016] PIERC 66 [2016] PIERC 65 [2016] PIERC 64 [2016] PIERC 63 [2016] PIERC 62 [2016] PIERC 61 [2016] PIERC 60 [2015] PIERC 59 [2015] PIERC 58 [2015] PIERC 57 [2015] PIERC 56 [2015] PIERC 55 [2014] PIERC 54 [2014] PIERC 53 [2014] PIERC 52 [2014] PIERC 51 [2014] PIERC 50 [2014] PIERC 49 [2014] PIERC 48 [2014] PIERC 47 [2014] PIERC 46 [2014] PIERC 45 [2013] PIERC 44 [2013] PIERC 43 [2013] PIERC 42 [2013] PIERC 41 [2013] PIERC 40 [2013] PIERC 39 [2013] PIERC 38 [2013] PIERC 37 [2013] PIERC 36 [2013] PIERC 35 [2013] PIERC 34 [2013] PIERC 33 [2012] PIERC 32 [2012] PIERC 31 [2012] PIERC 30 [2012] PIERC 29 [2012] PIERC 28 [2012] PIERC 27 [2012] PIERC 26 [2012] PIERC 25 [2012] PIERC 24 [2011] PIERC 23 [2011] PIERC 22 [2011] PIERC 21 [2011] PIERC 20 [2011] PIERC 19 [2011] PIERC 18 [2011] PIERC 17 [2010] PIERC 16 [2010] PIERC 15 [2010] PIERC 14 [2010] PIERC 13 [2010] PIERC 12 [2010] PIERC 11 [2009] PIERC 10 [2009] PIERC 9 [2009] PIERC 8 [2009] PIERC 7 [2009] PIERC 6 [2009] PIERC 5 [2008] PIERC 4 [2008] PIERC 3 [2008] PIERC 2 [2008] PIERC 1 [2008]
All Journals
PIER PIER B PIER C PIER M PIER Letters
2024-10-15
Disturbance-Resistant Control Method for PWM Rectifiers with Proportional-Integral Compensator
By
Lixin Kuang,

    Dr. Lixin Kuang

    State Grid Jiangsu Electric Power Co., Ltd

    China

    Homepage

Xiaodong Xu,

    Dr. Xiaodong Xu

    State Grid Jiangsu Electric Power Co., Ltd

    China

    Homepage

Weiping Zhu,

    Dr. Weiping Zhu

    State Grid Jiangsu Electric Power Co., Ltd

    China

    Homepage

Jinsong Jia,

    Dr. Jinsong Jia

    State Grid Nanjing Power Supply Company

    China

    Homepage

Guofeng Liu,

    Dr. Guofeng Liu

    State Grid Nanjing Power Supply Company

    China

    Homepage

Yingjiao Zhang

    Dr. Yingjiao Zhang

    State Grid Nanjing Power Supply Company

    China

    Homepage

Progress In Electromagnetics Research C, Vol. 148, 181-188, 2024
doi:10.2528/PIERC24072306
Abstract
Subjected to external interference, the input current of a voltage source pulse width modulation (PWM) rectifier distorts, leading to fluctuation in the dc bus voltage. In order to suppress current distortion and DC voltage fluctuation caused by disturbance, a disturbance-resistant control strategy for the PWM rectifiers is proposed. The mathematical model of the conventional double closed-loop control system is built, and the disturbance compensation mechanism is investigated. In addition, the design procedure of the proportional-integral compensator (PIC) is provided. To validate the proposed method, simulation and experiment are considered. The results show that low input current distortion and high bus voltage stability can be realized using the proposed method under the condition of disturbance. The control method is simple and easy to implement in the practical application.
Download Full Article (100) View Full Article volume
Citation
Lixin Kuang, Xiaodong Xu, Weiping Zhu, Jinsong Jia, Guofeng Liu, and Yingjiao Zhang, "Disturbance-Resistant Control Method for PWM Rectifiers with Proportional-Integral Compensator," Progress In Electromagnetics Research C, Vol. 148, 181-188, 2024.
doi:10.2528/PIERC24072306
References

1. Song, Tianbao, Yun Zhang, Fei Gao, Chengqian Xu, and Xinshan Zhu, "Data-driven adaptive negative sequence current control method for PWM rectifier under unbalanced grid," IEEE Transactions on Power Electronics, Vol. 39, No. 4, 4771-4780, 2024.

2. Le, Van-Tien and Hong-Hee Lee, "An enhanced model-free predictive control to eliminate stagnant current variation update for PWM rectifiers," IEEE Journal of Emerging and Selected Topics in Power Electronics, Vol. 9, No. 6, 6804-6816, 2021.

3. Spadacini, Giordano, Flavia Grassi, and Sergio A. Pignari, "Modelling and simulation of conducted emissions in the powertrain of electric vehicles," Progress In Electromagnetics Research B, Vol. 69, 1-15, 2016.
doi:10.2528/PIERB16051604

4. Mahmood, Alaa Shakir, "Enhancing performance of photovoltaic pump systems in remote areas using a sliding mode technique for maximum power point tracking," Progress In Electromagnetics Research B, Vol. 104, 131-146, 2024.
doi:10.2528/PIERB23110206

5. Wang, Meng, Haoran Wang, Yanyan Shi, Minghui Shen, and Jian Song, "A modified sliding-mode controller-based mode predictive control strategy for three-phase rectifier," International Journal of Circuit Theory and Applications, Vol. 48, No. 10, 1564-1582, 2020.

6. Zhang, Zhigang, Jiamian Chang, Mengdi Li, Pengcheng Zhang, and Wenjuan Zhang, "Optimization of bus capacitance of six-phase permanent magnet power generation system based on PWM modulation," Progress In Electromagnetics Research C, Vol. 138, 261-273, 2023.
doi:10.2528/PIERC23070505

7. Fu, Cheng, Chenghui Zhang, Guanguan Zhang, Chen Zhang, and Qijun Su, "Finite-time command filtered control of three-phase AC/DC converter under unbalanced grid conditions," IEEE Transactions on Industrial Electronics, Vol. 70, No. 7, 6876-6886, 2023.

8. Nguyen, Minh Hoang, Sangshin Kwak, and Seungdeog Choi, "Model predictive based direct power control method using switching state preference for independent phase loss decrease of three-phase pulsewidth modulation (PWM) rectifiers," IEEE Access, Vol. 12, 5864-5881, 2024.

9. Fu, Cheng, Chenghui Zhang, Guanguan Zhang, and Qijun Su, "Finite-time adaptive fuzzy control for three-phase PWM rectifiers with improved output performance," IEEE Transactions on Circuits and Systems II: Express Briefs, Vol. 70, No. 8, 3044-3048, 2023.

10. Kakkar, Sushma, Tanmoy Maity, Rajesh Kumar Ahuja, Pratima Walde, R. K. Saket, Baseem Khan, and Sanjeevikumar Padmanaban, "Design and control of grid-connected PWM rectifiers by optimizing fractional order PI controller using water cycle algorithm," IEEE Access, Vol. 9, 125941-125954, 2021.

11. Al Razehi, Mohammed, Rachid Errouissi, Mahdi Debouza, and Hussain Shareef, "Mitigation of 2ω-ripple in dc-link voltage of PWM rectifiers under unbalanced grid conditions," IEEE Transactions on Industry Applications, Vol. 59, No. 6, 7608-7622, 2023.

12. Gao, Xian, Dao Zhou, Amjad Anvari-Moghaddam, and Frede Blaabjerg, "Stability analysis of grid-following and grid-forming converters based on state-space modelling," IEEE Transactions on Industry Applications, Vol. 60, No. 3, 4910-4920, 2024.

13. Song, Tianbao, Yun Zhang, Fei Gao, Xinshan Zhu, Jiali Shan, and Zhiguo Kong, "Power model free voltage ripple suppression method of three-phase PWM rectifier under unbalanced grid," IEEE Transactions on Power Electronics, Vol. 37, No. 11, 13799-13807, 2022.

14. Le, Van-Tien and Hong-Hee Lee, "Grid-voltage sensorless model-free predictive current control for PWM rectifiers with measurement noise suppression," IEEE Transactions on Power Electronics, Vol. 37, No. 9, 10681-10697, 2022.

15. Qamar, Haleema, Hafsa Qamar, Nikhil Korada, and Rajapandian Ayyanar, "240º-clamped PWM applied to transformerless grid connected PV converters with reduced common mode voltage and superior performance metrics," IEEE Open Journal of Power Electronics, Vol. 3, 153-167, 2022.
doi:10.1109/OJPEL.2022.3155053

16. Zarei, Seyed Fariborz, Hossein Mokhtari, Mohammad Amin Ghasemi, Saeed Peyghami, Pooya Davari, and Frede Blaabjerg, "Control of grid-following inverters under unbalanced grid conditions," IEEE Transactions on Energy Conversion, Vol. 35, No. 1, 184-192, 2020.

17. Gui, Yonghao, Frede Blaabjerg, Xiongfei Wang, Jan D. Bendtsen, Dongsheng Yang, and Jakob Stoustrup, "Improved dc-link voltage regulation strategy for grid-connected converters," IEEE Transactions on Industrial Electronics, Vol. 68, No. 6, 4977-4987, 2021.

18. Yu, Hongguo, Zhongjian Kang, and Ping He, "Extended state observer based nonsingular terminal sliding mode control for voltage source converter station with uncertain disturbances," IEEE Access, Vol. 9, 122228-122235, 2021.

19. Yang, Xiaowei, Haitao Hu, Hai Hu, Yunjiang Liu, and Zhengyou He, "A quasi-resonant extended state observer-based predictive current control strategy for three-phase PWM rectifier," IEEE Transactions on Industrial Electronics, Vol. 69, No. 12, 13910-13917, 2022.

20. Pan, Zhifeng, Xiaohong Wang, Ziyi Zheng, and Lianfang Tian, "Fractional-order linear active disturbance rejection control strategy for grid-side current of PWM rectifiers," IEEE Journal of Emerging and Selected Topics in Power Electronics, Vol. 11, No. 4, 3827-3838, 2023.

21. Liao, Huanyue, Xin Zhang, and Zhijun Ma, "Robust dichotomy solution-based model predictive control for the grid-connected inverters with disturbance observer," CES Transactions on Electrical Machines and Systems, Vol. 5, No. 2, 81-89, 2021.

22. Nguyen, Thanh-Luan and Hong-Hee Lee, "Simplified model predictive control for AC/DC matrix converters with active damping function under unbalanced grid voltage," IEEE Journal of Emerging and Selected Topics in Power Electronics, Vol. 8, No. 3, 2907-2917, 2020.

Download Full Article (100) View Full Article volume
The EM Academy piers.org jpier.org Who's Who in EM
Copyright © 2022 The Electromagnetics Academy. All Rights Reserved.