基于模型和再分析的欧洲降水和压力错配的深度学习

IF 2.6 Q2 WATER RESOURCES Frontiers in Water Pub Date : 2023-05-24 DOI:10.3389/frwa.2023.1178114
Kaveh Patakchi Yousefi, S. Kollet
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引用次数: 1

摘要

基于物理的数值天气预报和气候模式为大量最终用户提供有用的信息,如洪水预报员、水资源管理者和农民。然而,由于初始值和模式误差等引起的模式不确定性,模拟结果与原位或遥感观测的匹配精度不高。将基于模型的数据与观测数据合并,可以同时受益于模型结果和观测数据的信息内容,从而产生有希望的结果。机器学习(ML)和/或深度学习(DL)方法已被证明是缩小模型和观测之间差距的有用工具,因为它们具有表示非线性时空相关结构的能力。本研究的重点是使用UNet编码器-解码器卷积神经网络(cnn)从模型模拟中提取时空特征,以预测模拟结果与参考数据集之间的实际不匹配(误差)。这里,来自陆地系统模拟平台(TSMP)的欧洲气候模拟被用作CNN的输入。cosmos - rea6再分析数据作为参考。将所提出的合并框架应用于降水和地表压力的失配,分别代表较多和较少的混沌变量。合并后的数据在平均误差(~ 47%)、相关系数(~ 37%)和均方根误差(~22%)方面均有明显改善。为了突出基于dl的方法的性能,将结果与基线方法分位数映射获得的结果进行比较。所提出的基于dl的合并方法既可以在模拟期间在线修正模型预测输出,也可以在后处理步骤中用于下游影响应用,如洪水预报、水资源管理和农业。
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Deep learning of model- and reanalysis-based precipitation and pressure mismatches over Europe
Physically based numerical weather prediction and climate models provide useful information for a large number of end users, such as flood forecasters, water resource managers, and farmers. However, due to model uncertainties arising from, e.g., initial value and model errors, the simulation results do not match the in situ or remotely sensed observations to arbitrary accuracy. Merging model-based data with observations yield promising results benefiting simultaneously from the information content of the model results and observations. Machine learning (ML) and/or deep learning (DL) methods have been shown to be useful tools in closing the gap between models and observations due to the capacity in the representation of the non-linear space–time correlation structure. This study focused on using UNet encoder–decoder convolutional neural networks (CNNs) for extracting spatiotemporal features from model simulations for predicting the actual mismatches (errors) between the simulation results and a reference data set. Here, the climate simulations over Europe from the Terrestrial Systems Modeling Platform (TSMP) were used as input to the CNN. The COSMO-REA6 reanalysis data were used as a reference. The proposed merging framework was applied to mismatches in precipitation and surface pressure representing more and less chaotic variables, respectively. The merged data show a strong average improvement in mean error (~ 47%), correlation coefficient (~ 37%), and root mean square error (~22%). To highlight the performance of the DL-based method, the results were compared with the results obtained by a baseline method, quantile mapping. The proposed DL-based merging methodology can be used either during the simulation to correct model forecast output online or in a post-processing step, for downstream impact applications, such as flood forecasting, water resources management, and agriculture.
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来源期刊
Frontiers in Water
Frontiers in Water WATER RESOURCES-
CiteScore
4.00
自引率
6.90%
发文量
224
审稿时长
13 weeks
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