In the last decades wind power became the second largest energy source in the EU covering 16% of its electricity demand. However, due to its volatility, accurate short range wind power predictions are required for successful integration of wind energy into the electrical grid. Accurate predictions of wind power require accurate hub height wind speed forecasts, where the state of the art method is the probabilistic approach based on ensemble forecasts obtained from multiple runs of numerical weather prediction models. Nonetheless, ensemble forecasts are often uncalibrated and might also be biased, thus require some form of post-processing to improve their predictive performance. We propose a novel flexible machine learning approach for calibrating wind speed ensemble forecasts, which results in a truncated normal predictive distribution. In a case study based on 100m wind speed forecasts produced by the operational ensemble prediction system of the Hungarian Meteorological Service, the forecast skill of this method is compared with the predictive performance of three different ensemble model output statistics approaches and the raw ensemble forecasts. We show that compared with the raw ensemble, post-processing always improves the calibration of probabilistic and accuracy of point forecasts and from the four competing methods the novel machine learning based approach results in the best overall performance.
翻译:在过去几十年中,风力成为欧盟中第二大能源来源,占电力需求的16%。然而,由于风力波动性,需要准确的短程风力预测,才能成功地将风能纳入电网。对风力的准确预测需要准确的中枢高度风速预测,其中最先进的方法是基于从多次数字天气预测模型中得出的混合预测的概率性方法。然而,混合预测往往无法校准,也可能有偏差,因此需要某种形式的后处理来改进其预测性能。我们提出一种新的灵活机能学习方法,用于校准风速联合预报,从而导致流速正常的预报分布。在匈牙利气象局操作混合预测系统产生的100米风速预测基础上进行的案例研究中,这一方法的预测技能与三种不同组合模型产出统计方法和原始组合预测性预测性表现相比较,因此,与原始组合、后处理式的机能学习方法相比,从最精准、最精准的四级模型预测结果中,总是改进了以最精确的进度和最优的机能预测。