在数据有限的流域通过全球天气数据同化提高水文模拟的可靠性

IF 3.9 3区 环境科学与生态学 Q1 ENGINEERING, CIVIL Stochastic Environmental Research and Risk Assessment Pub Date : 2024-06-25 DOI:10.1007/s00477-024-02758-4
Mahalingam Jayaprathiga, A. N. Rohith, Raj Cibin, K. P. Sudheer
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引用次数: 0

摘要

水文模型对水资源规划和管理至关重要。模拟的精度和可靠性在很大程度上取决于输入数据的可获得性和质量。特别是在发展中国家,建模的主要挑战是缺乏精细的时空输入数据,尤其是降水数据。近年来,越来越多地使用遥感天气数据。然而,由于间接测量的性质,与地面观测数据相比,遥感数据存在偏差,可能会影响模拟的水平衡。针对这些局限性,我们探索了数据同化技术,利用有限的地面观测数据改进全球降水测量产品(IMERG)的降水量。我们采用了多种同化方法,包括线性缩放校正因子法(CF)和功率变换函数法(PF)。同化后的 IMERG 降水量由最有效的方法确定,并将其用于生态水文模型,由此产生的河水流量模拟结果与观测到的流量数据进行了验证。研究结果表明,同化降水增强了 CF 和 PF 方法以及条件合并降水的月流量统计。一组水文模拟结果优于基于原始 IMERG 降水量的模拟结果。此外,在数据有限的流域,水文模拟还与观测到的测站降水数据和广泛使用的气候预测系统再分析数据集进行了比较。利用同化 IMERG 数据集进行的模拟(NSE=0.52)与基于观测降水的模拟(NSE=0.61)相当,明显优于基于 CFSR 的模拟(NSE=-0.2)。这些结果凸显了在数据有限的流域利用同化遥感数据进行水文模拟的潜力,从而提高模拟的准确性和可靠性。
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Enhancing the reliability of hydrological simulations through global weather data assimilation in watersheds with limited data

Hydrological models are critical for water resources planning and management. The precision and reliability of the simulations hinge greatly on the accessibility and quality of available input data. Particularly in developing nations, the major challenge in modeling is the scarcity of fine-scale spatiotemporal input data, specifically precipitation. Remotely sensed weather data has been increasingly used in recent years. However, they possess bias compared to ground observations due to the nature of indirect measurement and may affect the simulated water balance. To address these limitations, we explored data assimilation techniques to improve the Global Precipitation Measurement product (IMERG) precipitation using limited ground observations. Multiple assimilation methods are applied by incorporating Linear scaling Correction Factor (CF) and Power Transformation Function methods (PF). The assimilated IMERG precipitation from the most effective method identified, is utilized in an eco-hydrological model, and the resulting stream flow simulations are validated against observed flow data. The findings indicate that assimilated precipitation enhances the monthly flow statistics in both CF and PF methods and also in conditional merged precipitation. An ensemble of hydrological simulations, outperformed those based on raw IMERG precipitation. Additionally, the hydrological simulations are compared with observed gauge precipitation data and the widely used Climate Forecast System Reanalysis (CFSR) dataset in data-limited watersheds. The simulations utilizing the assimilated IMERG dataset (NSE = 0.52) are comparable to gauge precipitation-based simulations (NSE = 0.61) and significantly superior to CFSR-based simulations (NSE=-0.2). These results highlight the potential of utilizing assimilated remote sensing data for hydrological modeling in data-limited watersheds, leading to improved simulation accuracy and reliability.

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来源期刊
CiteScore
7.10
自引率
9.50%
发文量
189
审稿时长
3.8 months
期刊介绍: Stochastic Environmental Research and Risk Assessment (SERRA) will publish research papers, reviews and technical notes on stochastic and probabilistic approaches to environmental sciences and engineering, including interactions of earth and atmospheric environments with people and ecosystems. The basic idea is to bring together research papers on stochastic modelling in various fields of environmental sciences and to provide an interdisciplinary forum for the exchange of ideas, for communicating on issues that cut across disciplinary barriers, and for the dissemination of stochastic techniques used in different fields to the community of interested researchers. Original contributions will be considered dealing with modelling (theoretical and computational), measurements and instrumentation in one or more of the following topical areas: - Spatiotemporal analysis and mapping of natural processes. - Enviroinformatics. - Environmental risk assessment, reliability analysis and decision making. - Surface and subsurface hydrology and hydraulics. - Multiphase porous media domains and contaminant transport modelling. - Hazardous waste site characterization. - Stochastic turbulence and random hydrodynamic fields. - Chaotic and fractal systems. - Random waves and seafloor morphology. - Stochastic atmospheric and climate processes. - Air pollution and quality assessment research. - Modern geostatistics. - Mechanisms of pollutant formation, emission, exposure and absorption. - Physical, chemical and biological analysis of human exposure from single and multiple media and routes; control and protection. - Bioinformatics. - Probabilistic methods in ecology and population biology. - Epidemiological investigations. - Models using stochastic differential equations stochastic or partial differential equations. - Hazardous waste site characterization.
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