Data driven weather forecasts trained and initialised directly from observations

arXiv - PHYS - Atmospheric and Oceanic Physics Pub Date : 2024-07-22 DOI:arxiv-2407.15586

Anthony McNally, Christian Lessig, Peter Lean, Eulalie Boucher, Mihai Alexe, Ewan Pinnington, Matthew Chantry, Simon Lang, Chris Burrows, Marcin Chrust, Florian Pinault, Ethel Villeneuve, Niels Bormann, Sean Healy

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Abstract

Skilful Machine Learned weather forecasts have challenged our approach to numerical weather prediction, demonstrating competitive performance compared to traditional physics-based approaches. Data-driven systems have been trained to forecast future weather by learning from long historical records of past weather such as the ECMWF ERA5. These datasets have been made freely available to the wider research community, including the commercial sector, which has been a major factor in the rapid rise of ML forecast systems and the levels of accuracy they have achieved. However, historical reanalyses used for training and real-time analyses used for initial conditions are produced by data assimilation, an optimal blending of observations with a physics-based forecast model. As such, many ML forecast systems have an implicit and unquantified dependence on the physics-based models they seek to challenge. Here we propose a new approach, training a neural network to predict future weather purely from historical observations with no dependence on reanalyses. We use raw observations to initialise a model of the atmosphere (in observation space) learned directly from the observations themselves. Forecasts of crucial weather parameters (such as surface temperature and wind) are obtained by predicting weather parameter observations (e.g. SYNOP surface data) at future times and arbitrary locations. We present preliminary results on forecasting observations 12-hours into the future. These already demonstrate successful learning of time evolutions of the physical processes captured in real observations. We argue that this new approach, by staying purely in observation space, avoids many of the challenges of traditional data assimilation, can exploit a wider range of observations and is readily expanded to simultaneous forecasting of the full Earth system (atmosphere, land, ocean and composition).

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直接根据观测数据训练和初始化数据驱动的天气预报

娴熟的机器学习天气预报对我们的数值天气预报方法提出了挑战，与传统的基于物理的方法相比，它显示出具有竞争力的性能。数据驱动的系统通过学习过去天气的长期历史记录（如 ECMWF ERA5）来预测未来天气。这些数据集已免费提供给包括商业部门在内的更广泛的研究界，这也是 ML 预报系统迅速崛起并达到准确水平的一个重要因素。然而，用于训练的历史再分析和用于初始条件的实时分析都是通过数据同化产生的，是观测数据与基于物理的预报模式的最佳融合。因此，许多 ML 预报系统对它们试图挑战的基于物理的模式有着隐含的、未量化的依赖。在这里，我们提出了一种新方法，即训练一个神经网络，让它完全根据历史观测数据预测未来天气，而不依赖于再分析。我们使用原始观测数据来初始化直接从观测数据中学习的大气模型（观测空间）。通过预测未来时间和任意地点的天气参数观测数据（如 SYNOP 地表数据），可以获得关键天气参数（如地表温度和风）的预报。我们展示了预测未来 12 小时内观测数据的初步结果。这些结果已经证明，我们成功地学习了真实观测数据中捕捉到的物理过程的时间变化。我们认为，这种新方法纯粹停留在观测空间，避免了传统数据同化的许多挑战，可以利用更广泛的观测资料，并可随时扩展到对整个地球系统（大气、陆地、海洋和成分）的同步预报。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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arXiv - PHYS - Atmospheric and Oceanic Physics

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