Espresso: A Global Deep Learning Model to Estimate Precipitation from Satellite Observations

Léa Berthomier, Laurent Perier
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引用次数: 1

Abstract

Estimating precipitation is of critical importance to climate systems and decision-making processes. This paper presents Espresso, a deep learning model designed for estimating precipitation from satellite observations on a global scale. Conventional methods, like ground-based radars, are limited in terms of spatial coverage. Satellite observations, on the other hand, allow global coverage. Combined with deep learning methods, these observations offer the opportunity to address the challenge of estimating precipitation on a global scale. This research paper presents the development of a deep learning model using geostationary satellite data as input and generating instantaneous rainfall rates, calibrated using data from the Global Precipitation Measurement Core Observatory (GPMCO). The performance impact of various input data configurations on Espresso was investigated. These configurations include a sequence of four images from geostationary satellites and the optimal selection of channels. Additional descriptive features were explored to enhance the model’s robustness for global applications. When evaluated against the GPMCO test set, Espresso demonstrated highly accurate precipitation estimation, especially within equatorial regions. A comparison against six other operational products using multiple metrics indicated its competitive performance. The model’s superior storm localization and intensity estimation were further confirmed through visual comparisons in case studies. Espresso has been incorporated as an operational product at Météo-France, delivering high-quality, real-time global precipitation estimates every 30 min.
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Espresso:一个从卫星观测估计降水的全球深度学习模型
估算降水对气候系统和决策过程至关重要。本文介绍了Espresso,这是一个深度学习模型,旨在从全球范围的卫星观测中估计降水。传统的方法,如地面雷达,在空间覆盖方面是有限的。另一方面,卫星观测可以覆盖全球。与深度学习方法相结合,这些观测结果为解决在全球范围内估计降水的挑战提供了机会。本文介绍了一种深度学习模型的开发,该模型使用地球静止卫星数据作为输入,并使用全球降水测量核心观测站(GPMCO)的数据进行校准,生成瞬时降雨率。研究了不同输入数据配置对Espresso性能的影响。这些配置包括来自地球静止卫星的四幅图像序列和信道的最佳选择。研究了其他描述性特征,以增强模型对全局应用的鲁棒性。当对GPMCO测试集进行评估时,Espresso显示出高度准确的降水估计,特别是在赤道地区。使用多个指标与其他六种运营产品进行比较,表明其具有竞争力。通过实例的目视比较,进一步证实了该模式在风暴定位和强度估计方面的优越性。Espresso已被纳入msamtsamo - france的运营产品,每30分钟提供高质量的实时全球降水估计。
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