Abstract
It remains unclear to what extent remote sensing instruments can effectively improve the accuracy of short-term wind power forecasts. This work seeks to address this issue by developing and testing two novel forecasting methodologies, based on measurements from a state-of-the-art long-range scanning Doppler LiDAR. Both approaches aim to predict the total power generated at the wind farm scale with a five minute lead time and use successive low-elevation sector scans as input. The first approach is physically based and adapts the solar short-term forecasting approach referred to as “smart-persistence” to wind power forecasting. The second approaches the same short-term forecasting problem using convolutional neural networks. The two methods were tested over a 72 day assessment period at a large wind farm site in Victoria, Australia, and a novel adaptive scanning strategy was implemented to retrieve high-resolution LiDAR measurements. Forecast performances during ramp events and under various stability conditions are presented. Results showed that both LiDAR-based forecasts outperformed the persistence and ARIMA benchmarks in terms of mean absolute error and root-mean-squared error. This study is therefore a proof-of-concept demonstrating the potential offered by remote sensing instruments for short-term wind power forecasting applications.
Highlights
Worldwide energy markets are undergoing a rapid shift towards low carbon technologies and renewable energy sources
The deep convolutional neural networks” (DCNNs) model exhibited superior accuracy for all error metrics presented in Table 2, with notably 90% of the days reporting improvement over persistence in terms of root-meansquared error (RMSE)
autoregressive integrated moving average (ARIMA) and smart persistence (SP) showed a similar %DOP according to the RMSE, and ARIMA outperformed SP according to the mean absolute error (MAE)
Summary
Worldwide energy markets are undergoing a rapid shift towards low carbon technologies and renewable energy sources. Driven by the latest technology advancements and the associated reduction in investment costs [1], wind power has recently gained considerable traction with more than 60GW installed in 2019 alone, bringing the total installed capacity worldwide to 651GW [2]. A growing number of energy markets are moving towards shorter dispatch and pricing time frames in an effort to limit spot price fluctuations and ensure system reliability In countries such as Belgium, France, Germany [9] and Australia [10], markets operate on a five minute basis, and forecasts at this time scale are required to reduce the uncertainty and costs associated with ancillary services. Doppler LiDARs only measure the radial (or “along-the-beam”) component of the wind, and post-processing is required to retrieve the horizontal wind speed and direction across the area of interest
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