Physics-constrained deep learning postprocessing of temperature and humidity

Artificial intelligence for the earth systems Pub Date : 2023-10-24 DOI:10.1175/aies-d-22-0089.1

Francesco Zanetta, Daniele Nerini, Tom Beucler, Mark A. Liniger

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Abstract

Abstract Weather forecasting centers currently rely on statistical postprocessing methods to minimize forecast error. This improves skill but can lead to predictions that violate physical principles or disregard dependencies between variables, which can be problematic for downstream applications and for the trustworthiness of postprocessing models, especially when they are based on new machine learning approaches. Building on recent advances in physics-informed machine learning, we propose to achieve physical consistency in deep learning-based postprocessing models by integrating meteorological expertise in the form of analytic equations. Applied to the post-processing of surface weather in Switzerland, we find that constraining a neural network to enforce thermodynamic state equations yields physically-consistent predictions of temperature and humidity without compromising performance. Our approach is especially advantageous when data is scarce, and our findings suggest that incorporating domain expertise into postprocessing models allows the optimization of weather forecast information while satisfying application-specific requirements.

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物理约束的深度学习温度和湿度后处理

摘要气象预报中心目前主要依靠统计后处理方法来减少预报误差。这提高了技能，但可能导致预测违反物理原理或忽略变量之间的依赖关系，这可能会对下游应用程序和后处理模型的可信度造成问题，特别是当它们基于新的机器学习方法时。基于物理信息机器学习的最新进展，我们建议通过以解析方程的形式整合气象专业知识，在基于深度学习的后处理模型中实现物理一致性。应用于瑞士地表天气的后处理，我们发现约束神经网络来执行热力学状态方程可以在不影响性能的情况下产生物理上一致的温度和湿度预测。当数据稀缺时，我们的方法尤其有利，我们的研究结果表明，将领域专业知识纳入后处理模型可以在满足特定应用需求的同时优化天气预报信息。

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Artificial intelligence for the earth systems

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