Downscaling Taiwan precipitation with a residual deep learning approach

IF 4 3区 地球科学 Q1 GEOSCIENCES, MULTIDISCIPLINARY Geoscience Letters Pub Date : 2024-05-09 DOI:10.1186/s40562-024-00340-y
Li-Huan Hsu, Chou-Chun Chiang, Kuan-Ling Lin, Hsin-Hung Lin, Jung-Lien Chu, Yi-Chiang Yu, Chin-Shyurng Fahn
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Abstract

In response to the growing demand for high-resolution rainfall data to support disaster prevention in Taiwan, this study presents an innovative approach for downscaling precipitation data. We employed a hierarchical architecture of Multi-Scale Residual Networks (MSRN) to downscale rainfall from a coarse 0.25-degree resolution to a fine 0.0125-degree resolution, representing a substantial challenge due to a resolution increase of over 20 times. Our results demonstrate that the hierarchical MSRN outperforms both the one-step MSRN and linear interpolation methods when reconstructing high-resolution daily rainfall. It surpasses the linear interpolation method by 15.1 and 9.1% in terms of mean absolute error and root mean square error, respectively. Furthermore, the hierarchical MSRN excels in accurately reproducing high-resolution rainfall for various rainfall thresholds, displaying minimal biases. The threat score (TS) highlights the hierarchical MSRN's capability to replicate extreme rainfall events, achieving TS scores exceeding 0.54 and 0.46 at rainfall thresholds of 350 and 500 mm per day, outperforming alternative methods. This method is also applied to an operational global model, the ECMWF’s daily rainfall forecasts over Taiwan. The evaluation results indicate that our approach is effective at improving rainfall forecasts for thresholds greater than 100 mm per day, with more significant improvement for the 1- to 3-day lead forecast. This approach also offers a realistic visual representation of fine-grained rainfall distribution, showing promise for making significant contributions to disaster preparedness and weather forecasting in Taiwan.
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利用残差深度学习方法对台湾降水量进行降尺度处理
为满足台湾对高分辨率降雨数据日益增长的需求,以支持防灾工作,本研究提出了一种降雨数据降尺度的创新方法。我们采用了多尺度残差网络(MSRN)的分层结构,将降雨从 0.25 度的粗分辨率降到 0.0125 度的细分辨率,由于分辨率提高了 20 多倍,这是一项巨大的挑战。我们的研究结果表明,在重建高分辨率日降雨量时,分层 MSRN 优于一步 MSRN 和线性插值方法。就平均绝对误差和均方根误差而言,它分别比线性插值法高出 15.1% 和 9.1%。此外,分层 MSRN 在精确再现各种降雨阈值的高分辨率降雨量方面表现出色,偏差极小。威胁得分(TS)突出显示了分层 MSRN 复制极端降雨事件的能力,在降雨量阈值为每天 350 毫米和 500 毫米时,威胁得分分别超过 0.54 和 0.46,优于其他方法。该方法还应用于全球运行模式,即 ECMWF 对台湾的日降雨量预报。评估结果表明,我们的方法能有效改善日降雨量阈值大于 100 毫米的降雨预报,对 1 至 3 天的提前预报有更显著的改善。该方法还提供了精细降雨分布的逼真视觉呈现,有望为台湾的灾害防备和天气预报做出重大贡献。
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来源期刊
Geoscience Letters
Geoscience Letters Earth and Planetary Sciences-General Earth and Planetary Sciences
CiteScore
4.90
自引率
2.50%
发文量
42
审稿时长
25 weeks
期刊介绍: Geoscience Letters is the official journal of the Asia Oceania Geosciences Society, and a fully open access journal published under the SpringerOpen brand. The journal publishes original, innovative and timely research letter articles and concise reviews on studies of the Earth and its environment, the planetary and space sciences. Contributions reflect the eight scientific sections of the AOGS: Atmospheric Sciences, Biogeosciences, Hydrological Sciences, Interdisciplinary Geosciences, Ocean Sciences, Planetary Sciences, Solar and Terrestrial Sciences, and Solid Earth Sciences. Geoscience Letters focuses on cutting-edge fundamental and applied research in the broad field of the geosciences, including the applications of geoscience research to societal problems. This journal is Open Access, providing rapid electronic publication of high-quality, peer-reviewed scientific contributions.
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