Abstract
As the relative importance of renewable energy in electric power systems increases, the prediction of photovoltaic (PV) power generation has become a crucial technology, for improving stability in the operation of next-generation power systems, such as microgrid and virtual power plants (VPP). In order to improve the accuracy of PV power generation forecasting, a fair amount of research has been applied to weather forecast data (to a learning process). Despite these efforts, the problems of forecasting PV power generation remains challenging since existing methods show limited accuracy due to inappropriate cloud amount forecast data, which are strongly correlated with PV power generation. To address this problem, we propose a PV power forecasting model, including a cloud amount forecasting network trained with satellite images. In addition, our proposed model adopts convolutional self-attention to effectively capture historical features, and thus acquire helpful information from weather forecasts. To show the efficacy of the proposed cloud amount forecast network, we conduct extensive experiments on PV power generation forecasting with and without the cloud amount forecast network. The experimental results show that the Mean Absolute Percentage Error (MAPE) of our proposed prediction model, combined with the cloud amount forecast network, are reduced by 22.5% compared to the model without the cloud amount forecast network.
Highlights
As the penetration level of distributed energy resources (DERs) increases in microgrids and virtual power plants (VPPs), the problem of photovoltaic (PV) power generation forecasting is becoming crucial for such generation power systems [1]
Microgrids are power systems consisting of DERs and electrical end users, with controllable elastic loads, all distributed in limited areas [2]
Results of PV Power Generation Forecasting order to validate the applicability of our prediction model, we conduct two sets of experiments
Summary
As the penetration level of distributed energy resources (DERs) increases in microgrids and virtual power plants (VPPs), the problem of photovoltaic (PV) power generation forecasting is becoming crucial for such generation power systems [1]. To deal with this problem, many previous studies have attempted to use historical weather data to improve the accuracy of forecasting PV power generation [10,11,12,13,14,15] These previous researches have constructed a predictive model by independently using or combining recurrent neural network (RNN) and convolution neural network (CNN). These approaches used weather data to learn the correlation with PV power generation, cloud amount forecasts from the meteorological administration, which is strongly correlated with PV power generation, might be inappropriate for PV power generation prediction, because they provide only long-term (e.g., 3-h or more) forecasts, and wide area forecasts, instead of a prediction for a specific location where PV panels are installed.
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