地球科学进展

地球科学进展 ›› 2014, Vol. 29 ›› Issue (9): 1075 -1084. doi: 10.11867/j.issn.1001-8166.2014.09.1075

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基于水文模型的蒸散发数据同化实验研究
尹剑 1( ), 占车生 2, 顾洪亮 1, 王飞宇 2   
  1. 1. 安庆师范学院资源环境学院,安徽 安庆 246011
    2. 中国科学院地理科学与资源研究所,北京 100101
  • 收稿日期:2014-05-20 修回日期:2014-08-06 出版日期:2014-09-10
  • 基金资助:
    国家自然科学基金项目“基于水文模型的流域蒸散发数据同化适应性研究”(编号:41401042)和“一种高效的流域蒸散过程模拟方法及其不确定性研究”(编号:41271003)资助

A Case Study of Evapotranspiration Data Assimilation Based on Hydrological Model

Jian Yin 1( ), Chesheng Zhan 2, Hongliang Gu 1, Feiyu Wang 2   

  1. 1. School of Resources and Environment,Anqing Normal University,Anqing 246011,China
    2. Institute of Geographic Science and Natural Resource Research,CAS,Beijing 100101,China
  • Received:2014-05-20 Revised:2014-08-06 Online:2014-09-10 Published:2014-09-10
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流域蒸散发定量估算一直是水科学领域的研究前沿,水文模型和遥感反演是当前估算区域蒸散发的常用手段。研究通过数据同化,集成水文模型和遥感模型的优势,耦合遥感蒸散发到水文模型中以实现多源数据下的蒸散发数据同化。选择北京市沙河流域为研究区,分布式时变增益水文模型作为模型算子,基于集合卡尔曼滤波同化算法,利用双层遥感模型模拟的蒸散发同化水文模型,并基于地面通量站观测的日蒸散发进行验证。结果表明,同化结果与观测数据相比平均绝对百分比误差较同化前减少,精度进一步提升,且当遥感观测输入频繁时精度改善明显。研究证明基于水文模型的蒸散发数据同化系统,是一种可实现输出精度更高和时序连续的区域蒸散发的新型模式。该成果将进一步丰富创新蒸散发估算的学科内容,为准确理解区域水循环规律提供科学依据。

关键词: 蒸散发, 遥感反演, 水文模型, 集合卡尔曼滤波, 数据同化

The quantitative estimation of watershed Evapotranspiration (ET) has been an international frontier in water sciences for a long time. Hydrological models and remote sensing ET models are usually used to estimate regional ET at different spacetime scales, but these two methods are obviously insufficient to obtain precise and continuous regional ET. The hydrological models have the capability to simulate time-continuous daily or monthly ET processes, but the accuracy is not high compared with remote sensing ET models. The applicability of remote sensing ET models based on surface energy balance is restricted by the lack of high frequency and high resolution thermal data. A compromise between these two methodologies is represented by improving the optimization of hydrological models on the basis of a new ET series, which are produced by Data Assimilation (DA) scheme combining sparse remote estimates into the hydrological model. This study aimed to integrate the advantages of the two models to simulate the daily ET processes in Shahe River basin, Beijing. For this progect, the distributed hydrological model was fist constructed and the daily hydrological processes of 19992007 simulated. Then, the Ensemble Kalman Filter (EnKF) was used to assimilate the ET series calculated by remote sensing retrieval into the hydrological model to adjust the simulation. The results show that the ET estimation accuracy is improved after the data assimilation, and the MAPE between the DSMbased ETs and LASbased ETs in the study area is reduced. The integrated method is proved better, and improves the hydrology modeling accuracy. Therefore, the project successfully develops a new land surface ET mode with the advantages of hydrological model and remote sensing ET model, and the study founds the new method could simulate regional ET with high accuracy and continuous time series. The new land surface ET model not only follows the surface energy balance, but also meets the regional water balance, and has more perfect water thermal coupling mechanism. The study will further enrich the content of ET estimation disciplines, and provide a scientific basis for better understanding of the laws of regional water cycle.

Key words: Evapotranspiration, Remote sensing retrieval, Hydrological model, Ensemble Kalman filter, Data assimilation.

中图分类号: 

图1 研究区示意图需要彩色印刷
Fig.1 Map of the study area
表1 研究收集的数据信息
Table 1 The data list for the study
数据类型 数据名称 年份 备注
遥感影像 Landsat TM 1999—2007 美国地质调查局(USGS: http://glovis.usgs.gov),30 m分辨率
DEM 沙河流域DEM 2005 中科院资源环境科学数据中心,30 m分辨率
土地利用 沙河流域土地利用图 2005 中科院资源环境科学数据中心,1:10万
土壤类型 沙河流域土壤类型图 2000 中科院资源环境科学数据中心,1:100万
雨量数据 流域站点日降雨量 1990—2007 北京水文总站,十三陵等6站日降雨量
流量数据 流域站点日流量 1990—2007 北京水文总站,沙河闸站日流量
水位数据 流域站点日水位 1990—2007 北京水文总站,沙河闸等主要监测断面
水库管理资料 流域内水库调度方案 1990—2007 北京水科所,王家园、响潭、十三陵、沙河水库等
气象数据 北京站气象数据 1990—2007 常规观测,昌平、海淀气象站等
实测ET 水热通量观测数据 2002—2007 沙河流域下游小汤山地面通量观测站
图2 流域蒸散同化技术路线图
Fig.2 The schematic framework of watershed evapotranspiration data assimilation
图3 DTVGM模拟流域月蒸散量(1999—2007年)
Fig.3 The monthly ET simulated by DTVGM with out data assimilation (1999-2007)
图4 不同方式获得的区域日蒸散发比较
Fig.4 The ET of typical day by different method
图5 1999—2007年沙河流域逐日流域平均蒸散发(5日移动均线)
Fig.5 Average daily ET processes in the Shahe river basin in 1999-2007 (5 days moving average curve)
图6 日蒸散发的DTVGM模拟和同化结果比较(2002年、2007年)
Fig. 6 The comparation of ET in typical days through DTVGM and data assimilation (2002, 2007)
表2 DTVGM模拟、数据同化输出与ET-Watch模型估算的年蒸散发比较
Table 2 The Comparation of yearly ET simulated by DTVGM, DA and ET-Watch
年份 同化前年ET(mm) 模拟相对误差(%) 同化后年ET(mm) 同化相对误差(%) ET-Watch结果(mm)
2002 452.18 12.74 564.78 1.90 575.50
2003 454.78 -4.52 450.56 -3.42 435.12
2004 543.82 -12.09 506.31 -4.18 485.15
2005 501.09 10.85 520.25 8.04 562.05
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