基于广义比例积分观测器的永磁同步电机鲁棒谐振预测电流控制

doi:10.19595/j.cnki.1000-6753.tces.230331

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摘要针对永磁同步电机（PMSM）采用无差拍预测电流控制（DPCC）时,性能易受电机参数失配及死区效应的影响,该文提出一种基于广义比例积分（GPI）观测器的鲁棒谐振预测电流控制（RRPCC）方法。首先,分析PMSM参数失配将产生非周期扰动及逆变器死区效应会导致周期扰动,进而建立带有非周期和周期性扰动的PMSM精确数学模型;其次,基于内模原理,将包含扰动频率的谐振多项式嵌入电流预测模型,可有效地抑制周期性扰动;最后,采用GPI观测器估计由参数失配引起的集总扰动,并通过前馈补偿消除非周期扰动。实验结果表明,该方法能提高系统面对非周期及周期性扰动时的鲁棒性。

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	杨帆
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	王晓东
	刘晓源

关键词 ：参数失配, GPI观测器, 周期扰动, 鲁棒谐振预测电流控制

Abstract：To improve the control performance of a permanent magnet synchronous motor (PMSM), deadbeat predictive current control (DPCC) is adopted for the inner current loop due to its small current ripple and fast dynamic response. However, DPCC is highly dependent on accurate PMSM parameters, and any mismatch may lead to steady-state current errors and system instability. In practical PMSM operation, parameter mismatch is inevitable due to factors such as temperature drift and magnetic saturation. In addition, inverter dead time introduces periodic voltage disturbance, resulting in current distortion and torque ripple, which deteriorates the performance of the PMSM system. Therefore, this paper proposes a robust resonant predictive current control (RRPCC) strategy based on the generalized proportional integral (GPI) observer to mitigate the adverse impacts of parameter mismatch and inverter dead-time effect.
Firstly, the non-periodic disturbance generated by parameter mismatch and the periodic disturbance induced by the dead-time effect are analyzed. A precise mathematical model of the PMSM is established considering both disturbances. Secondly, based on the internal mode principle, a resonant polynomial is incorporated into the current prediction model at the same frequency as the periodic disturbance. The resonant predictive current controller is designed to reject periodic sinusoidal disturbance and achieve smooth current output. Finally, to eliminate non-periodic disturbance, a GPI observer is added to the current controller to estimate and compensate for lumped disturbances induced by parameter mismatch. The stability analysis of the GPI observer in the discrete-time domain is given.
The effectiveness of the proposed method is verified by experiments. The speed reference is set to 800 r/min (ω_e=335 rad/s) in the periodic disturbance test. Apparent d-q axis current pulsations occur with 2 010 rad/s in the conventional DPCC. The pulsation amplitude of i_q and i_d is 0.9 A and 0.7 A, respectively. The FFT analysis shows that 6th current harmonics are significant in the d-q axis. The RRPCC method effectively suppresses 6th harmonics. The pulsation amplitude of i_q and i_d is reduced to 0.3 A and 0.2 A, respectively. In the flux-linkage mismatch test, the flux-linkage is changed in step from 50% to 200% of the nominal value. The flux-linkage variation in the conventional DPCC causes an obvious steady-state current error with 0.9 A in the q-axis. The flux-linkage is maintained at 2ψ_f, and the speed increases from 400 r/min to 1 600 r/min. When the conventional DPCC is adopted, the q-axis current oscillates during the current dynamic process. The current tracking error increases to 1.5 A at 1 600 r/min in the steady state. The proposed RRPCC maintains the d-q axis current stable and smooth, exhibiting good current tracking performance. In the inductance mismatch test, the inductance step changes from 50% to 200% of the nominal value. In the conventional DPCC, current ripples are severely increased with the amplitudes of 1.1 A and 1.6 A in the d-q axis. The current quality of the proposed RRPCC is not affected by maintaining current ripples at 0.5 A and 0.4 A.
The following conclusions can be drawn from the experimental analysis: (1) The dead-time effect generates periodic sinusoidal disturbances. Compared with the conventional DPCC, the resonant predictive current controller is established in RRPCC, which can reject the periodic disturbance. (2) Steady-state current errors induced by PMSM parameter mismatch are compensated by the GPI observer in RRPCC, enhancing system robustness. (3) The proposed RRPCC exhibits good disturbance rejection ability and current tracking performance in the presence of non-periodic and periodic disturbances.

Key words： Parameter mismatch GPI observer periodic disturbance robust resonant predictive current control (RRPCC)

收稿日期: 2023-03-21 出版日期: 2024-06-07

PACS:

TM351

基金资助:辽宁省博士科研启动基金计划资助项目（2022-BS-177）

通讯作者: 赵希梅女,1979年生,教授,博士生导师,研究方向为直线伺服、智能控制、鲁棒控制等。E-mail: zhaoxm_sut@163.com

作者简介: 杨帆男,1985年生,博士研究生,副研究员,研究方向为电机控制、电力电子、预测控制等。E-mail: sailing_0402@163.com

引用本文:

杨帆, 赵希梅, 金鸿雁, 王晓东, 刘晓源. 基于广义比例积分观测器的永磁同步电机鲁棒谐振预测电流控制[J]. 电工技术学报, 2024, 39(10): 2995-3006. Yang Fan, Zhao Ximei, Jin Hongyan, Wang Xiaodong, Liu Xiaoyuan. Robust Resonant Predictive Current Control Based on Generalized Proportional Integral Observer for Permanent Magnet Synchronous Motor. Transactions of China Electrotechnical Society, 2024, 39(10): 2995-3006.

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[1] 章回炫, 范涛, 边元均, 等. 永磁同步电机高性能电流预测控制[J]. 电工技术学报, 2022, 37(17): 4335-4345.
Zhang Huixuan, Fan Tao, Bian Yuanjun, et al.Predictive current control strategy of permanent magnet synchronous motors with high performance[J]. Transactions of China Electrotechnical Society, 2022, 37(17): 4335-4345.
[2] 赵凯辉, 周瑞睿, 冷傲杰, 等. 一种永磁同步电机的有限集无模型容错预测控制算法[J]. 电工技术学报, 2021, 36(1): 27-38.
Zhao Kaihui, Zhou Ruirui, Leng Aojie, et al.Finite control set model-free fault-tolerant predictive control for permanent magnet synchronous motor[J]. Transa- ctions of China Electrotechnical Society, 2021, 36(1): 27-38.
[3] 陈卓易, 屈稳太, 邱建琪. 一种开关频率可控的有限集模型预测控制[J]. 电工技术学报, 2022, 37(16): 4134-4142.
Chen Zhuoyi, Qu Wentai, Qiu Jianqi.A switching- frequency-controlled finite-control-set model predi- ctive control method[J]. Transactions of China Electrotechnical Society, 2022, 37(16): 4134-4142.
[4] Pei Genji, Liu Jiaxi, Gao Xiaonan, et al.Deadbeat predictive current control for SPMSM at low switching frequency with moving horizon estimator[J]. IEEE Journal of Emerging and Selected Topics in Power Electronics, 2021, 9(1): 345-353.
[5] 郭磊磊, 王朋帅, 李琰琰, 等. 不同代价函数下永磁同步电机模型预测控制参数失配可视化分析[J]. 电工技术学报, 2023, 38(4): 903-914.
Guo Leilei, Wang Pengshuai, Li Yanyan, et al.Visual analysis of parameters mismatch in model predictive control for permanent magnet synchronous motor under different cost functions[J]. Transactions of China Electrotechnical Society, 2023, 38(4): 903-914.
[6] Wang Zitan, Chai Jianyun, Xiang Xuewei, et al.A novel online parameter identification algorithm designed for deadbeat current control of the permanent-magnet synchronous motor[J]. IEEE Transactions on Industry Applications, 2022, 58(2): 2029-2041.
[7] Zhou Ying, Zhang Shuo, Zhang Chengning, et al.Current prediction error based parameter identi- fication method for SPMSM with deadbeat predictive current control[J]. IEEE Transactions on Energy Conversion, 2021, 36(3): 1700-1710.
[8] Xu Cheng, Han Zaikun, Lu Shuai.Deadbeat predictive current control for permanent magnet synchronous machines with closed-form error com- pensation[J]. IEEE Transactions on Power Electronics, 2020, 35(5): 5018-5030.
[9] 卜飞飞, 罗捷, 刘皓喆, 等. 双绕组感应发电机系统无差拍电流预测控制策略[J]. 电工技术学报, 2021, 36(24): 5213-5224.
Bu Feifei, Luo Jie, Liu Haozhe, et al.Deadbeat predictive current control strategy of dual winding induction generator system[J]. Transactions of China Electrotechnical Society, 2021, 36(24): 5213-5224.
[10] 李争, 安金峰, 肖宇, 等. 基于自适应观测器的永磁同步直线电机模型预测控制系统设计[J]. 电工技术学报, 2021, 36(6): 1190-1200.
Li Zheng, An Jinfeng, Xiao Yu, et al.Design of model predictive control system for permanent magnet synchronous linear motor based on adaptive observer[J]. Transactions of China Electrotechnical Society, 2021, 36(6): 1190-1200.
[11] Wang Lijun, Zhao Jiwen, Yang Xing, et al.Robust deadbeat predictive current regulation for permanent magnet synchronous linear motor drivers with parallel parameter disturbance and load observer[J]. IEEE Transactions on Power Electronics, 2022, 37(7): 7834-7845.
[12] Zhang Yongchang, Jin Jialin, Huang Lanlan.Model- free predictive current control of PMSM drives based on extended state observer using ultralocal model[J]. IEEE Transactions on Industrial Electronics, 2021, 68(2): 993-1003.
[13] Wang Junxiao, Wang Fengxiang, Wang Gaolin, et al.Generalized proportional integral observer based robust finite control set predictive current control for induction motor systems with time-varying dis- turbances[J]. IEEE Transactions on Industrial Infor- matics, 2018, 14(9): 4159-4168.
[14] Yang Jun, Wu Han, Hu Liang, et al.Robust predictive speed regulation of converter-driven DC motors via a discrete-time reduced-order GPIO[J]. IEEE Transa- ctions on Industrial Electronics, 2019, 66(10): 7893-7903.
[15] Geng Yiwen, Deng Renxiong, Dong Wenming, et al.An overlap-time compensation method for current- source space-vector PWM inverters[J]. IEEE Transa- ctions on Power Electronics, 2018, 33(4): 3192-3203.
[16] Liang Donglai, Li Jian, Qu Ronghai, et al.Adaptive second-order sliding-mode observer for PMSM sensorless control considering VSI nonlinearity[J]. IEEE Transactions on Power Electronics, 2018, 33(10): 8994-9004.
[17] Shen Zewei, Jiang Dong.Dead-time effect com- pensation method based on current ripple prediction for voltage-source inverters[J]. IEEE Transactions on Power Electronics, 2019, 34(1): 971-983.
[18] Li Yongfei, Li Yong, Wang Qian.Robust predictive current control with parallel compensation terms against multi-parameter mismatches for PMSMs[J]. IEEE Transactions on Energy Conversion, 2020, 35(4): 2222-2230.
[19] Zhou Zhanqing, Xia Changliang, Yan Yan, et al.Disturbances attenuation of permanent magnet syn- chronous motor drives using cascaded predictive- integral-resonant controllers[J]. IEEE Transactions on Power Electronics, 2018, 33(2): 1514-1527.