LC滤波型电压源逆变器无模型预测电压控制策略

doi:10.19595/j.cnki.1000-6753.tces.221815

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摘要为解决传统模型预测控制在参数失配时预测误差增大的问题,该文提出一种适用于LC滤波型电压源逆变器的无模型预测电压控制策略。该策略建立了基于电压和电流双梯度的查询表,通过计算和存储上一时刻应用矢量作用下的电压和电流梯度,并结合当前时刻的采样值,实现未来时刻电压和电流的无模型预测;进一步重构状态空间预测方程,根据应用矢量作用下的电压和电流梯度实时更新未应用矢量的梯度值,保证了梯度的准确性;使用电压和电流双目标的价值函数进行跟踪评估,进而选取下一控制周期最优的矢量。该方法不依赖于任何系统参数、计算简单,且消除了传统无模型预测中梯度更新停滞现象,改善了输出电压性能。最后通过实验验证了所提方法的有效性和优越性。

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	尹政
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关键词 ：电压源逆变器, LC型滤波, 无模型预测电压控制, 梯度更新

Abstract：This paper proposes a model-free predictive voltage control strategy for LC-filtered voltage source inverters to solve the problem that the prediction error increases when the parameters of conventional model predictive control are mismatched. The strategy establishes a look-up table based on the double gradients of voltage and current. By calculating and storing the voltage and current gradients under the action of the application vectors at the previous time, combined with the sampling values at the current time, the voltage and current at the future time can be predicted. The state space prediction equation is further reconstructed. The gradient value of the unapplied vector is updated according to the voltage and current gradients under the action of the applied vector. The voltage and current cost functions evaluate and select the optimal vector in the next control period. This method is independent of system parameters and simple, which can eliminate the stagnation of gradient updating in the conventional model-free prediction and improve the output voltage performance. Finally, simulation and experiment verify the effectiveness and superiority of the proposed method.
Firstly, the look-up table of the capacitor voltage gradient and the inverter-side current gradient is designed. Based on the gradient information, the voltage and current can be predicted without parameters. Secondly, the proposed method reconstructs the state-space prediction equation to ensure real-time updates of all gradients in each control period, eliminating the stagnation phenomenon of conventional model-free predictive control. In addition, the output voltage quality is further improved using the cost function with two control targets. Finally, the effectiveness of the proposed method is verified by experiments.
Simulation results on the voltage-current gradient updating show that the root mean square error (RMSE) of the conventional updating method is 6.91 V, and the RMSE of the proposed model-free predictive voltage control (MFPVC) updating method is 3.66 V, which is 3.25 V lower than that of the conventional updating method. Experimental results on the accurate model parameters show that the proposed method can achieve similar voltage performance with the conventional model predictive voltage control (MPVC). Experimental results on the inaccurate model parameters show that when the controller parameter mismatches the actual parameter, the proposed MFPVC produces smaller prediction errors than the conventional MPVC. Hence, the parameter robustness of the proposed MFPVC can be verified.1231223The following conclusions can be drawn from the simulation and experimental analysis: (1) The proposed method has good parameter robustness. When the parameters change, the output voltage error of the inverter is significantly reduced, the voltage quality is improved, and the voltage performance is similar to that of MPVC under the condition of accurate parameters. (2) This method proposes an advanced voltage and current gradient updating method, which can update the voltage and current gradient under all vectors in real time, eliminate the stagnation phenomenon and the predicted spikes, and further improve the output voltage quality.
In future studies, the proposed method can be extended to the LCL filter type VSI, or the voltage ripple can be further reduced by vector combination.

Key words： Voltage source inverter LC filter model-free predictive voltage control gradient updating

收稿日期: 2022-09-27

PACS:

TM464

基金资助:国家自然科学基金项目（52207184）、安徽省科技重大专项（202103a05020019）和安徽省自然科学基金杰青项目（2108085J24）资助

通讯作者: 芮涛男,1990年生,讲师,研究方向为基于数据驱动的并网逆变器无参数预测控制技术。E-mail: 19057@ahu.edu.cn

作者简介: 尹政男,1996年生,硕士研究生,研究方向为变流器的调制与控制技术。E-mail: yz@stu.ahu.edu.cn

引用本文:

尹政, 胡存刚, 芮涛, 冯壮壮, 陆格野. LC滤波型电压源逆变器无模型预测电压控制策略[J]. 电工技术学报, 2023, 38(14): 3723-3732. Yin Zheng, Hu Cungang, Rui Tao, Feng Zhuangzhuang, Lu Geye. Model-Free Predictive Voltage Control Strategy for LC-Filtered Voltage Source Inverter. Transactions of China Electrotechnical Society, 2023, 38(14): 3723-3732.

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