利用机器学习模型对浮动光伏发电进行短期预测

Mohd Herwan Sulaiman , Mohd Shawal Jadin , Zuriani Mustaffa , Mohd Nurulakla Mohd Azlan , Hamdan Daniyal
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摘要

浮动光伏(FPV)发电需要准确的短期预测,以优化运行效率并加强并网。本研究利用马来西亚彭亨苏丹阿卜杜拉大学(UMPSA)太阳能装置(发电量为 157.20 kWp)的数据,研究了机器学习模型在预测 FPV 发电量中的应用。数据收集时间为 2024 年 1 月 15 日至 1 月 21 日,每隔 15 分钟收集一次,包含九个输入特征,如环境温度、瞬时水平辐照度、每日水平辐照度、交流电压以及 A、B 和 C 相的交流电流,目标变量为以千瓦为单位的总有功功率。数据集分为训练集(前五天)和测试集(剩余两天),并采用了五种机器学习模型--神经网络(NN)、随机森林(RF)、极限学习机(ELM)、支持向量回归(SVR)和长短期记忆(LSTM)。结果表明,就预测准确性而言,神经网络模型始终优于其他机器学习算法。这些发现强调了机器学习技术在预测 FPV 发电量方面的功效,这对提高浮动太阳能装置的运行效率和并网具有重要意义。
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Short-Term forecasting of floating photovoltaic power generation using machine learning models

Floating photovoltaic (FPV) power generation requires accurate short-term forecasting to optimize operational efficiency and enhance grid integration. This study investigates the application of machine learning models for predicting FPV power generation using data from the Universiti Malaysia Pahang Al-Sultan Abdullah (UMPSA) solar installation, which has a capacity of 157.20 kWp. Data were collected at 15-minute intervals from January 15 to January 21, 2024, encompassing nine input features such as ambient temperature, transient horizontal irradiation, daily horizontal irradiation, AC voltages, and AC currents for phases A, B, and C, with the total active power in kW as the target variable. The dataset was divided into a training set (first five days) and a testing set (remaining two days), and five machine learning models—Neural Networks (NN), Random Forest (RF), Extreme Learning Machine (ELM), Support Vector Regression (SVR), and Long Short-Term Memory (LSTM)—were employed. The results indicate that the Neural Networks model consistently outperforms the other machine learning algorithms in terms of predictive accuracy. These findings underscore the efficacy of machine learning techniques in forecasting FPV power generation, which has significant implications for enhancing the operational efficiency and grid integration of floating solar installations.

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