Convolutional encoding and normalizing flows: a deep learning approach for offshore wind speed probabilistic forecasting in the Mediterranean Sea

Robin Marcille, P. Tandeo, Maxime Thiébaut, Pierre Pinson, R. Fablet
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Abstract

The safe and efficient execution of offshore operations requires short-term (1 to 6 hours ahead) high-quality probabilistic forecasts of metocean variables. The development areas for offshore wind projects, potentially in high depths, make it difficult to gather measurement data. This paper explores the use of deep learning for wind speed forecasting at an unobserved offshore location. The proposed convolutional architecture jointly exploits coastal measurements and numerical weather predictions to emulate multivariate probabilistic short-term forecasts. We explore both Gaussian and non-Gaussian neural representations using normalizing flows. We benchmark these approaches with respect to state-of-art data-driven schemes, including analog methods and quantile forecasting. The performance of the models, and resulting forecast quality, are analyzed in terms of probabilistic calibration, probabilistic and deterministic metrics, and as a function of weather situations. We report numerical experiments for a real case-study off the French Mediterranean coast. Our results highlight the role of regional numerical weather prediction and coastal in situ measurement in the performance of the post-processing. For single-valued forecasts, a 40% decrease in RMSE is observed compared to the direct use of numerical weather predictions. Significant skill improvements are also obtained for the probabilistic forecasts, in terms of various scores, as well as an acceptable probabilistic calibration. The proposed architecture can process a large amount of heterogeneous input data, and offers a versatile probabilistic framework for multivariate forecasting.
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卷积编码和归一化流量:地中海近海风速概率预报的深度学习方法
要安全、高效地执行海上作业,需要对海洋变量进行短期(提前 1 至 6 小时)高质量的概率预报。海上风电项目的开发区域可能位于很深的海底,因此很难收集测量数据。本文探讨了在未观测到的离岸位置使用深度学习进行风速预测。所提出的卷积架构联合利用了海岸测量和数值天气预报,以模拟多元概率短期预测。我们利用归一化流量探索了高斯和非高斯神经表征。我们将这些方法与最先进的数据驱动方案(包括模拟方法和量化预测)进行比较。我们从概率校准、概率和确定性指标以及天气情况的函数等方面分析了模型的性能和由此产生的预报质量。我们报告了法国地中海沿岸一个实际案例的数值实验。我们的结果强调了区域数值天气预报和沿岸实地测量在后处理性能中的作用。与直接使用数值天气预报相比,单值预报的均方根误差降低了 40%。概率预报的各种评分以及可接受的概率校准也得到了显著提高。所提出的架构可以处理大量异构输入数据,并为多元预报提供了一个通用的概率框架。
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