Comparative Study Between the Different MPPT Techniques

2020 5th International Conference on Renewable Energies for Developing Countries (REDEC) Pub Date : 2020-06-01 DOI:10.1109/REDEC49234.2020.9163591

M. Mokhlis, M. Ferfra, Hemeyine Ahmed Vall, Rafika EL Idrissi, C. C. Ahmed, A. Taouni

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引用次数: 7

Abstract

This paper proposes a new hybrid controller based MPPT. This one is composed of the Artificial Neural Network and Integral Feedback Linearization Controller (ANN-IFLC). The ANN is used to produce the reference of optimal voltage that corresponds to the maximal power. While the IFLC is designed to track the voltage reference. The integral action is added to ensure zero-static error. Then, a comparison between different existing Maximum Power Point Tracking (MPPT) techniques, which are divided between the classical algorithms and the hybrid controllers, is made. The classical algorithms, treated in this study, are the Perturb and Observe (P & O) and Incremental Conductance (INC). While the hybrid controllers are INC-BSC, P & O-BSC, ANN-ISMC, ANN-BSC, and ANN-IFLC. As can be noticed, these controllers present the combination between the nonlinear controllers and the Artificial Neural network (ANN) or the classical algorithms (P & O and INC). Effectively, the nonlinear controllers used are the Sliding Mode Controller (SMC), the Integral Sliding Mode Controller (ISMC), the Backstepping Controller (BSC) and the proposed IFL Controller. The proposed photovoltaic system consists of the photovoltaic module (Reference: S6M2G240), of the Boost converter and the resistive load. The MPPT techniques are tested using Matlab software. The results show that the hybrid controllers characterize by the tracking performances better than the classical methods. Moreover, the Artificial Neural Network predicts quickly and accurately the Maximum Power Point (MPP) under uniform meteorological conditions. Also, the PV voltage produced, using IFLC or ISMC, has fewer oscillations around its optimum thanks to the integral action added.

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不同MPPT技术的比较研究

本文提出了一种新的基于MPPT的混合控制器。该系统由人工神经网络和积分反馈线性化控制器(ANN-IFLC)组成。利用人工神经网络产生与最大功率相对应的最优电压基准。而IFLC设计用于跟踪参考电压。加入积分动作，保证静态误差为零。然后，对现有的最大功率点跟踪(MPPT)技术进行了比较，将其分为经典算法和混合控制器两种。在本研究中处理的经典算法是摄动和观察(P & O)和增量电导(INC)。混合控制器有:c - bsc、P & O-BSC、ANN-ISMC、ANN-BSC和ANN-IFLC。可以注意到，这些控制器是非线性控制器与人工神经网络(ANN)或经典算法(P & O和INC)的结合。有效地，使用的非线性控制器是滑模控制器(SMC)，积分滑模控制器(ISMC)，反步控制器(BSC)和提出的IFL控制器。所提出的光伏系统由光伏模块(参考编号:S6M2G240)、升压变换器和电阻负载组成。利用Matlab软件对MPPT技术进行了测试。结果表明，该混合控制器具有较好的跟踪性能。此外，在均匀气象条件下，人工神经网络能快速准确地预测最大功率点。此外，使用IFLC或ISMC产生的PV电压，由于添加了积分作用，在其最佳附近的振荡较少。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

2020 5th International Conference on Renewable Energies for Developing Countries (REDEC)

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