The comparison of ANN-BP and ANN-PSO as learning algorithm to track MPP in PVSystem

2017 7th International Annual Engineering Seminar (InAES) Pub Date : 2017-08-01 DOI:10.1109/INAES.2017.8068573

A. Muhtar, I. Mustika, Suharyanto

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引用次数: 12

Abstract

The P-V curve of photovoltaic system exhibits multiple peaks under various conditions of function and changes in meteorological conditions which reduce the effectiveness of conventional maximum power point tracking (MPPT) methods. Artificial Neural Network (ANN) is one of soft computing used for learning, modeling, and analyzing a very complicated phenomenon. Furthermore, there is an algorithm based on meta-heuristic, which is usually used for some optimization problems. One of meta-heuristic algorithms used in this paper is Particle Swarm Optimization (PSO) algorithm. In this paper, a comparison between ANN using PSO and ANN used back propagation as a learning algorithm to track MPP in photovoltaic system. Each training model was conducted with different learning rate, but the number of neurons and activation functions used was similar in each training model. To evaluate both training models of ANN, Mean Square Error (MSE) was used. The result showed that ANN using PSO as a training algorithm require 17 epochs to convergent, but ANN using back propagation require 105 epochs to convergent. Furthermore, the average value of power generated from PV system, ANN using PSO as training algorithm for track MPP was 90.92 kW and ANN using back propagation as training algorithm for track MPP was 88.65 kW.

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在PVSystem中，ANN-BP与ANN-PSO作为学习算法跟踪MPP的比较

光伏系统的P-V曲线在各种功能条件和气象条件变化下呈现多峰特征，降低了传统最大功率点跟踪方法的有效性。人工神经网络(ANN)是一种用于学习、建模和分析非常复杂现象的软计算技术。此外，还有一种基于元启发式的算法，通常用于一些优化问题。本文使用的一种元启发式算法是粒子群优化算法(PSO)。本文比较了采用粒子群算法的人工神经网络与采用反向传播作为学习算法的人工神经网络在光伏系统MPP跟踪中的应用。每个训练模型以不同的学习速率进行，但每个训练模型中使用的神经元数量和激活函数是相似的。采用均方误差(MSE)对两种神经网络训练模型进行评价。结果表明，使用粒子群算法的神经网络需要17个epoch才能收敛，而使用反向传播算法的神经网络需要105个epoch才能收敛。此外，采用粒子群优化算法的神经网络对轨道MPP的平均发电量为90.92 kW，采用反向传播算法的神经网络对轨道MPP的平均发电量为88.65 kW。

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

2017 7th International Annual Engineering Seminar (InAES)

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