Optimal development of location and technology independent machine learning photovoltaic performance predictive models

2019 IEEE 46th Photovoltaic Specialists Conference (PVSC) Pub Date : 2019-06-01 DOI:10.1109/PVSC40753.2019.8980474

Andreas Livera, M. Theristis, G. Makrides, S. Ransome, J. Sutterlueti, G. Georghiou

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引用次数: 9

Abstract

Photovoltaic (PV) power prediction is important for monitoring the performance of PV plants. The scope of this work is to develop a methodology for deriving an optimized location and technology independent machine learning (ML) model for power prediction. The prediction accuracy results demonstrated that the performance of the ML model was primarily affected by the dataset split method. In particular, for a 70:30 % train and test set approach, the ML model achieved a normalized root mean square error (nRMSE) of 0.88 % when using randomly selected samples compared to 0.94 % when using continuous samples. The accuracy of the developed model was also affected by the duration of the train set. For a random 70:30 % train and test set approach, the constructed ML topology achieved a nRMSE of 0.88 %, while when the dataset was split into a 30:30 % portion, the nRMSE was 0.95 %. Moreover, when low irradiance conditions were filtered out and 70 % of the entire dataset was randomly chosen for model training, a nRMSE of 1.41 % was obtained demonstrating that the model’s accuracy was not improved. Finally, for a random 10:30 % train and test set approach, the FNNN achieved the lowest nRMSE of 1.10 % when the model was trained using the prevailing irradiance classes.

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位置与技术无关的光伏性能预测模型的优化开发

光伏发电功率预测对光伏电站性能监测具有重要意义。这项工作的范围是开发一种方法，用于导出用于功率预测的优化位置和技术独立的机器学习(ML)模型。预测精度结果表明，数据集分割方法主要影响机器学习模型的性能。特别是，对于70:30%的训练和测试集方法，ML模型在使用随机选择的样本时实现了0.88%的归一化均方根误差(nRMSE)，而使用连续样本时为0.94%。建立的模型的准确性也受到列车集持续时间的影响。对于随机的70:30%的训练和测试集方法，构建的ML拓扑实现了0.88%的nRMSE，而当数据集被分成30:30%的部分时，nRMSE为0.95%。此外，当过滤掉低辐照度条件并随机选择整个数据集的70%进行模型训练时，得到的nRMSE为1.41%，表明模型的精度没有提高。最后，对于随机的10:30 %训练集和测试集方法，当使用流行的辐照度类别训练模型时，FNNN的nRMSE最低，为1.10%。

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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2019 IEEE 46th Photovoltaic Specialists Conference (PVSC)

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