DUNE: A Machine Learning Deep UNet++ based Ensemble Approach to Monthly, Seasonal and Annual Climate Forecasting

arXiv - PHYS - Atmospheric and Oceanic Physics Pub Date : 2024-08-12 DOI:arxiv-2408.06262

Pratik Shukla, Milton Halem

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Abstract

Capitalizing on the recent availability of ERA5 monthly averaged long-term data records of mean atmospheric and climate fields based on high-resolution reanalysis, deep-learning architectures offer an alternative to physics-based daily numerical weather predictions for subseasonal to seasonal (S2S) and annual means. A novel Deep UNet++-based Ensemble (DUNE) neural architecture is introduced, employing multi-encoder-decoder structures with residual blocks. When initialized from a prior month or year, this architecture produced the first AI-based global monthly, seasonal, or annual mean forecast of 2-meter temperatures (T2m) and sea surface temperatures (SST). ERA5 monthly mean data is used as input for T2m over land, SST over oceans, and solar radiation at the top of the atmosphere for each month of 40 years to train the model. Validation forecasts are performed for an additional two years, followed by five years of forecast evaluations to account for natural annual variability. AI-trained inference forecast weights generate forecasts in seconds, enabling ensemble seasonal forecasts. Root Mean Squared Error (RMSE), Anomaly Correlation Coefficient (ACC), and Heidke Skill Score (HSS) statistics are presented globally and over specific regions. These forecasts outperform persistence, climatology, and multiple linear regression for all domains. DUNE forecasts demonstrate comparable statistical accuracy to NOAA's operational monthly and seasonal probabilistic outlook forecasts over the US but at significantly higher resolutions. RMSE and ACC error statistics for other recent AI-based daily forecasts also show superior performance for DUNE-based forecasts. The DUNE model's application to an ensemble data assimilation cycle shows comparable forecast accuracy with a single high-resolution model, potentially eliminating the need for retraining on extrapolated datasets.

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DUNE：基于机器学习深度 UNet++ 的月度、季节和年度气候预测集合方法

利用最近获得的基于高分辨率分析的ERA5月平均大气和气候平均场的长期数据记录，深度学习架构为基于物理的每日数值天气预报提供了一种替代方法，可以预测亚季节到季节（S2S）和年平均值。当从上月或上年初始化时，该架构产生了首个基于人工智能的全球月度、季节或年度平均 2 米气温（T2m）和海面温度（SST）预报。ERA5月平均数据被用作陆地T2m、海洋SST和大气顶部太阳辐射在40年中每月的输入，以训练模型。再进行两年的验证预测，然后进行五年的预测评估，以考虑自然年变率。人工智能训练的推断预报权重在几秒钟内生成预报，从而实现了集合季节预报。全球和特定地区的均方根误差（RMSE）、异常相关系数（ACC）和海德克技能分数（HSS）统计结果均有展示。这些预测在所有领域都优于持久性、气候学和多元线性回归。DUNE预报的统计精度与美国国家海洋和大气管理局（NOAA）的月度和季节性概率展望预报相当，但分辨率要高得多。最近其他基于人工智能的每日预报的均方根误差（RMSE）和均方根误差（ACC）统计也显示，基于DUNE的预报性能更优越。DUNE 模式在集合数据同化循环中的应用表明，其预报精度可与单个高分辨率模式相媲美，从而消除了对外推法数据集进行再训练的需要。

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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