Evaluation of the photovoltaic power prediction performance of a neural network based on input data

Agbokpanzo Richard Gilles, Didavi Audace, H. Aristide, Oloulade Arouna, Espanet Christophe
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引用次数: 1

Abstract

This paper aims to show the influence of the data size and the number of meteorological data used in the prediction of the output power of a photovoltaic installation with neural networks. We trained with different input data with the 2019a MATLAB Neural Network Start (NNS) tool, three feedforward networks. To train these networks, we used the algorithm of Levenberg-Marquardt and as data meteorological data such as wind speed at 10m from the ground, air temperature at 2m from the ground, position of the sun, direct radiation on an inclined plane and diffuse radiation on an inclined plane downloaded in the PVGIS database for a period from January 1, 2005 to December 31, 2016 for Natitingou city in the Republic of Benin. The first network was trained with wind speed at 10m, air temperature at 2m and sun position as input, the second network with wind speed at 10m, air temperature at 2m, sun position and direct radiation on an inclined plane and the third network with wind speed at 10m, air temperature at 2m, sun position, direct radiation on an inclined plane and diffuse radiation on an inclined plane. For the three networks we took the best results from 10 trainings. Thus, we obtained for the three networks respectively as mean square error 6186, 191 and 0.46 and as regression values 0.95, 0.998 and 0.999 respectively. In descending order according to the data used, the best performance was obtained with: • wind speed at 10m, air temperature at 2m, position of the sun, radiation, direct on an inclined plane and diffuse radiation on an inclined plane; • wind speed at 10m, air temperature at 2m, position of the sun, and the direct radiation on an inclined plane; • wind speed at 10m, air temperature at 2m and position of the sun.
基于输入数据的神经网络光伏功率预测性能评价
本文旨在利用神经网络对光伏发电装置的输出功率进行预测,研究数据大小和气象数据数量对预测结果的影响。我们使用2019a MATLAB神经网络启动(NNS)工具,三个前馈网络,使用不同的输入数据进行训练。为了训练这些网络,我们使用Levenberg-Marquardt算法,并将PVGIS数据库中下载的贝宁共和国纳亭沟市2005年1月1日至2016年12月31日距离地面10m处的风速、距离地面2m处的气温、太阳位置、斜面直接辐射和斜面散射辐射等气象数据作为数据。第一个网络以风速10m、气温2m、太阳位置为输入;第二个网络以风速10m、气温2m、太阳位置、斜面直接辐射为输入;第三个网络以风速10m、气温2m、太阳位置、斜面直接辐射和斜面漫射为输入。对于这三个网络,我们从10次训练中获得了最好的结果。因此,我们得到三个网络的均方误差分别为6186、191和0.46,回归值分别为0.95、0.998和0.999。根据所使用的数据由大到小依次为:风速10m、气温2m、太阳位置、辐射、斜面直射、斜面漫射;•风速10m,气温2m,太阳位置,斜面上的直接辐射;•风速10m,气温2m,太阳位置。
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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