Abstract
Variability, intermittency, and limited controllability are inherent characteristics of photovoltaic (PV) generation that result in inaccurate solutions to scheduling problems and the instability of the power grid. As the penetration level of PV generation increases, it becomes more important to mitigate these problems by improving forecasting accuracy. One of the alternatives to improving forecasting performance is to include a seasonal component. Thus, this study proposes using information on extraterrestrial radiation (ETR), which is the solar radiation outside of the atmosphere, in neural network models for day-ahead PV generation forecasting. Specifically, five methods for integrating the ETR into the neural network models are presented: (1) division preprocessing, (2) multiplication preprocessing, (3) replacement of existing input, (4) inclusion as additional input, and (5) inclusion as an intermediate target. The methods were tested using two datasets in Australia using four neural network models: Multilayer perceptron and three recurrent neural network(RNN)-based models including vanilla RNN, long short-term memory, and gated recurrent unit. It was found that, among the integration methods, including the ETR as the intermediate target improved the mean squared error by 4.1% on average, and by 12.28% at most in RNN-based models. These results verify that the integration of ETR into the PV forecasting models based on neural networks can improve the forecasting performance.
Highlights
The use of renewable energy sources (RES) for reducing greenhouse gases and consequent sustainable development has been considered inevitable
M5 reduced the mean squared error (MSE) by 4.1% on average and, at most, by 12.28% in the recurrent neural network (RNN)-based models
This study presents a simple and effective method to improve the forecasting accuracy of PV generation for mitigating the problems caused by the inherent characteristics of PV, such as variability, intermittency, and limited controllability
Summary
The use of renewable energy sources (RES) for reducing greenhouse gases and consequent sustainable development has been considered inevitable. It was projected via an International Energy Agency (IEA) sustainable development scenario that approximately 3268 TWh will be produced by PV generation by 2030 [2] Such an increase in PV generation causes instability in power systems due to its variability, intermittency, and limited controllability. From the perspective of transmission system operators (TSOs), the unfavorable characteristics of RES, including PV generation, can exacerbate the imbalance between power supply and demand [3] and make power system planning and operation more difficult [4] To address such problems, TSOs need to secure a significant number of flexible resources, which is followed by an increase in the electricity bills of customers. From the perspective of distribution system operators (DSOs), a high penetration of PV generation results in the need for investment in various alternative resources to achieve stable power system operation by addressing problems such as voltage fluctuation, increased network losses, and feeder overloading in the distribution network [6,7,8]
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