Artificial Neural Network-Based Voltage Control of DC/DC Converter for DC Microgrid Applications

Hussain Sarwar Khan, Ihab S. Mohamed, K. Kauhaniemi, Lantao Liu
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引用次数: 11

Abstract

The rapid growth of renewable energy technology enables the concept of microgrid (MG) to be widely accepted in the power systems. Due to the advantages of the DC distribution system such as easy integration of energy storage and less system loss, DC MG attracts significant attention nowadays. The linear controller such as PI or PID is matured and extensively used by the power electronics industry, but their performance is not optimal as system parameters are changed. In this study, an artificial neural network (ANN) based voltage control strategy is proposed for the DC-DC boost converter. In this paper, the model predictive control (MPC) is used as an expert, which provides the data to train the proposed ANN. As ANN is tuned finely, then it is utilized directly to control the step-up DC converter. The main advantage of the ANN is that the neural network system identification decreases the inaccuracy of the system model even with inaccurate parameters and has less computational burden compared to MPC due to its parallel structure. To validate the performance of the proposed ANN, extensive MATLAB/Simulink simulations are carried out. The simulation results show that the ANN-based control strategy has better performance under different loading conditions comparison to the PI controller. The accuracy of the trained ANN model is about 97%, which makes it suitable to be used for DC microgrid applications.
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基于人工神经网络的直流微电网DC/DC变换器电压控制
随着可再生能源技术的快速发展,微电网的概念在电力系统中得到了广泛的应用。由于直流配电系统具有易于集成储能、系统损耗小等优点,直流电网管理受到了人们的广泛关注。PI或PID等线性控制器在电力电子工业中已经成熟并得到了广泛的应用,但随着系统参数的变化,它们的性能并不最优。本文提出了一种基于人工神经网络的DC-DC升压变换器电压控制策略。在本文中,模型预测控制(MPC)作为专家,为训练所提出的人工神经网络提供数据。由于人工神经网络具有良好的调谐特性,因此可以直接用于升压直流变换器的控制。人工神经网络的主要优点是,即使在参数不准确的情况下,神经网络系统识别也降低了系统模型的不准确性,并且由于其并行结构,与MPC相比,计算负担更小。为了验证所提出的人工神经网络的性能,进行了大量的MATLAB/Simulink仿真。仿真结果表明,与PI控制器相比,基于人工神经网络的控制策略在不同负载条件下具有更好的性能。训练后的人工神经网络模型的准确率约为97%,适合用于直流微电网应用。
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