Abstract
This work compares the solar power forecasting performance of tree-based methods that include implicit regime-based models to explicit regime separation methods that utilize both unsupervised and supervised machine learning techniques. Previous studies have shown an improvement utilizing a regime-based machine learning approach in a climate with diverse cloud conditions. This study compares the machine learning approaches for solar power prediction at the Shagaya Renewable Energy Park in Kuwait, which is in an arid desert climate characterized by abundant sunshine. The regime-dependent artificial neural network models undergo a comprehensive parameter and hyperparameter tuning analysis to minimize the prediction errors on a test dataset. The final results that compare the different methods are computed on an independent validation dataset. The results show that the tree-based methods, the regression model tree approach, performs better than the explicit regime-dependent approach. These results appear to be a function of the predominantly sunny conditions that limit the ability of an unsupervised technique to separate regimes for which the relationship between the predictors and the predictand would differ for the supervised learning technique.
Highlights
Utility scale solar power capacity continues to have worldwide growth with a total installed capacity of 180 GW at the end of 2018 [1]
Forecasting solar power depends upon first identifying the diurnal pattern of irradiance at a given location, determining the amount of irradiance attenuated from clouds and aerosols such as dust
The results showed a substantial improvement from 15-min to 3-h lead time for solar irradiance prediction using the regime-dependent artificial neural network (RD-Artificial Neural Networks (ANNs)), including an improvement over an ANN trained on all data
Summary
Utility scale solar power capacity continues to have worldwide growth with a total installed capacity of 180 GW at the end of 2018 [1]. Forecasting solar power depends upon first identifying the diurnal pattern of irradiance at a given location, determining the amount of irradiance attenuated from clouds and aerosols such as dust. The diurnal pattern of irradiance is a well understood geometric calculation; the cloud growth and evolution is a dynamic process that must be well predicted to capture the irradiance reaching the solar panels at the earth’s surface. Various algorithms have different predictive ability for cloud growth and evolution at different forecast lead times. The predictive skill depends inherently on the height of the cloud and the prevailing wind speed but is generally limited to 15 min or less of forecast lead time
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