DONG Guotao,FAN Dong,YANG Shengtian,et al.Analysis on the Applicability of GPM and TRMM Precipitation Data in the Yellow River Basin[J].Research of Soil and Water Conservation,2018,25(03):81-87.
GPM与TRMM降雨数据在黄河流域适用性分析
- Title:
- Analysis on the Applicability of GPM and TRMM Precipitation Data in the Yellow River Basin
- Keywords:
- GPM; TRMM; precipitation; applicability analyses; Yellow River Basin
- 分类号:
- P468.0+24
- 摘要:
- GPM(Global Precipitation Measurement)是继TRMM(Tropical Rainfall Measuring Mission)之后的新一代全球卫星降水测量计划。GPM扩展了TRMM传感载荷,提升了降水观测能力。以GPM和TRMM重合期(2014年3月-2015年4月)数据为对象,利用黄河流域内76个气象站点的降雨实测数据,探讨了两种卫星降水数据在黄河流域的适用性,并分析了流域内两种卫星降水数据误差的时空分布。结果表明:年尺度上,GPM与TRMM卫星数据与实测降水量的决定系数分别为0.78,0.86,总体一致性较好,但分别存在2.46%与2.19%的相对高估。季节尺度上,春、秋两季数据精度高,夏季卫星降水数据相对于实测降水量存在较大的绝对误差,冬季则相对误差较大。月尺度上,除7月、8月外卫星降水数据均大于实测降水量,相对误差最大值出现在12月,绝对误差最大值出现在9月。单站点验证结果表明GPM与TRMM卫星降水数据在流域北部的陶乐、惠农、临河等区域数据精度偏低,而在广大的流域中南部区域卫星降水数据与实测降水量有较高的一致性。
- Abstract:
- Precipitation is a fundamental component of the global water cycle, a key parameter of ecology, hydrology and meteorology. Knowing when, where and how precipitation occurres is crucial for understanding how weather and climate impact both our environment and Earth water and energy cycles, including effects on agriculture, fresh water availability, and responses to natural disasters, and it is extraordinarily important for sustaining life on our planet during climate change. Accurate precipitation measurement of estimation is vital to water resource management, weather prediction, disaster monitoring, controlling, and so on. In addition, the availability of high-quality precipitation data is a prerequisite for conducting meaningful climatic, atmospheric and hydrological models. The Global Precipitation Measurement (GPM) Mission, lunched February 27th, 2014 by a joint effort of America National Aeronautics and Space Administration (NASA) and the Japan Aerospace Exploration Agency (JAXA), is an international satellite mission that provides the next-generation global observations of rain and snow. Based on the Tropical Rainfall Measuring Mission (TRMM), the GPM to unify precipitation measurements form constellation of research and operational sensors to provide a new generation precipitation products, GPM was designed to set a new standard for measurement of precipitation and snowfall, measure light rain, and provide quantitative estimates of microphysical properties of precipitation particles. A critical evaluation of these newly released precipitation data sets is very important for both the end users and data developers. In this study, the quality of the GPM and TRMM precipitation product from March 2014 to April 2015 were evaluated in Yellow River Basin with rain gauges from 76 meteorological stations. The main findings of this study are as follows. There was a significant correlation between GPM/TRMM products and the observed data. However, the satellite data might be a little bit overestimated by 2.46 percent and 2.19 percent, respectively. Compared with the observed data, the satellite products contained large absolute error in summer and relative error in winter, yet the computed accuracy is relatively high in spring and autumn. On the scale of months, the satellite precipitation data are greater than the measured values except the August and September, among them, the largest relative error appears in December, whereas the maximum absolute error appears in September. The single-site verification results show that the TRMM and GPM precipitation products have a poor accuracy around the site of Taole, Huinong and Linhe in the north of Yellow River Basin. However, the satellite data and the observation data have highly consistency in the south-central of Yellow River Basin and the precipitation data from satellite is applicable in this region. As the early validation and comparison of the GPM IMERG and TRMM 3B43 V7 monthly products, it will provide useful references and feedbacks for the development of IMERG algorithms and promote the research and application of GPM data over Yellow River Basin and beyond.
参考文献/References:
[1] 齐文文,张百平,庞宇,等.基于TRMM数据的青藏高原降水的空间和季节分布特征[J].地理科学,2013,33(8):999-1005.
[2] 曾红伟,李丽娟.澜沧江及周边流域TRMM3B43数据精度检验[J].地理学报,2011,66(7):994-1004.
[3] 江善虎,任立良,雍斌,等. TRMM卫星降水数据在洣水流域径流模拟中的应用[J].水科学进展,2014,25(5):641-649.
[4] 刘俊峰,陈仁升,卿文武,等.基于TRMM降水数据的山区降水垂直分布特征[J].水科学进展,2011,22(4):447-454.
[5] 卢新玉,魏鸣,王秀琴,等. TRMM 3B43降水产品在新疆地区的适用性研究[J].国土资源遥感,2016,28(3):166-173.
[6] 朱国锋,蒲焘,张涛,等. TRMM降水数据在横断山区的精度[J].地理科学,2013,33(9):1125-1131.
[7] 杨云川,程根伟,范继辉,等.卫星降雨数据在高山峡谷地区的代表性与可靠性[J].水科学进展,2013,24(1):24-33.
[8] 黄勇,陈生,冯妍,等.中国大陆TMPA降水产品气候态的评估[J].气象,2015,41(3):353-363.
[9] 刘少华,严登华,王浩,等.中国大陆流域分区TRMM降水质量评价[J].水科学进展,2016,27(5):639-651.
[10] 骆三,苗峻峰,牛涛,等. TRMM测雨产品3B42与台站资料在中国区域的对比分析[J].气象,2011,37(9):1081-1090.
[11] 赵传成,丁永建,叶柏生,等.天山山区降水量的空间分布及其估算方法[J].水科学进展,2011,22(3):315-322.
[12] 赵军,刘原峰,朱国锋,等.热带测雨卫星数据在黑河流域的精度及应用[J].水土保持通报,2016,36(3):309-315.
[13] 王超,赵传燕. TRMM多卫星资料在黑河上游降水时空特征研究中的应用[J].自然资源学报,2013,28(5):862-872.
[14] 吴雪娇,杨梅学,吴洪波,等. TRMM多卫星降水数据在黑河流域的验证与应用[J].冰川冻土,2013,35(2):310-319.
[15] 吕洋,杨胜天,蔡明勇,等. TRMM卫星降水数据在雅鲁藏布江流域的适用性分析[J].自然资源学报,2013,28(8):1414-1425.
[16] 曲伟,路京选,宋文龙,等. TRMM遥感降水数据在伊洛瓦底江流域的精度检验和校正方法研究[J].地球科学进展,2014,29(11):1262-1270.
[17] 张涛,李宝林,何元庆,等.基于TRMM订正数据的横断山区降水时空分布特征[J].自然资源学报,2015,30(2):260-270.
[18] 李相虎,张奇,邵敏.基于TRMM数据的鄱阳湖流域降雨时空分布特征及其精度评价[J].地理科学进展,2012,31(9):1164-1170.
[19] 胡庆芳,杨大文,王银堂,等.赣江流域TRMM降水数据的误差特征与成因[J].水科学进展,2013,24(6):794-800.
[20] 唐国强,李哲,薛显武,等.赣江流域TRMM遥感降水对地面站点观测的可替代性[J].水科学进展,2015,26(3):340-346.
[21] 嵇涛,杨华,刘睿,等. TRMM卫星降水数据在川渝地区的适用性分析[J].地理科学进展,2014,33(10):1375-1386.
[22] 孙乐强,郝振纯,王加虎,等. TMPA卫星降水数据的评估与校正[J].水利学报,2014,46(10):1135-1146.
[23] 李琼,杨梅学,万国宁,等. TRMM 3B43降水数据在黄河源区的适用性评价[J].冰川冻土,2016,38(3):620-633.
[24] 刘小婵,赵建军,张洪岩,等. TRMM降水数据在东北地区的精度验证与应用[J].自然资源学报,2015,30(6):1047-1056.
[25] 罗布坚参,翟盘茂,假拉,等.西藏高原测站降水与TRMM估测降水一致性评估[J].气象,2015,41(9):1119-1125.
[26] 沈彬,李新功.塔里木河流域TRMM降水数据精度评估[J].干旱区地理,2015,38(4):703-712.
[27] 蔡晓慧,邹松兵,陆志翔,等. TRMM月降水产品在西北内陆河流域的适应性定量分析[J].兰州大学学报:自然科学版,2013,49(3):291-298.
[28] 李威,蒋平,赵卫权,等. TRMM卫星降水数据在喀斯特山区的适用性分析:以贵州省为例[J].水土保持研究,2016,23(1):97-102.
[29] Li N, Tang G, Zhao P, et al. Statistical assessment and hydrological utility of the latest multi-satellite precipitation analysis IMERG in Ganjiang River basin[J]. Atmospheric Research, 2017,183(25):212-223.
[30] Tang G, Ma Y, Long D, et al. Evaluation of GPM day-1 IMERG and TMPA version-7 legacy products over Mainland China at multiple spatiotemporal scales[J]. Journal of Hydrology, 2016,533(21):152-167.
[31] Guo H, Chen S, Bao A, et al. Early assessment of integrated multi-satellite retrievals for global precipitation measurement over China[J]. Atmospheric Research, 2016,52(12):121-133.
[32] Siuki S K, Saghafiana B, Moazami S. Comprehensive evaluation of 3-hourly TRMM and half-hourly GPM-IMERG satellite precipitation products[J]. International Journal of Remote Sensing, 2017,38(2):558-571.
[33] Prakash S, Mitra A K, Aghakouchak A, et al. A preliminary assessment of GPM-based multi-satellite precipitation estimates over a monsoon dominated region[J]. Journal of Hydrology, 2016,221(13):116-132.
[34] Kim K, Park J, Baik J, et al. Evaluation of topographical and seasonal feature using GPM IMERG and TRMM3B42 over Far-East Asia[J]. Atmospheric Research, 2017,187(5):95-105.
[35] 周丹,张勃,安美玲,等.黄河流域不同时间尺度干旱对ENSO事件的响应[J].中国沙漠,2015,35(3):753-762.
[36] 徐宗学,张楠.黄河流域近50年降水变化趋势分析[J].地理研究,2006,23(1):27-34.
[37] 刘昌明,曾燕,邱新法.黄河流域气象水文学要素图集[M].郑州:黄河水利出版社,2004.
[38] 宋文龙,杨胜天,路京选,等.黄河中游大尺度植被冠层截留降水模拟与分析[J].地理学报,2014,69(1):80-89.
[39] 罗娅,杨胜天,刘晓燕,等.黄河河口镇-潼关区间1998-2010年土地利用变化特征[J].地理学报,2014,69(1):42-53.
[40] 王楠,李栋梁,张杰.黄河中上游季节内强降水的时间非均匀性特征及其对大气环流的响应[J].中国沙漠,2013,33(1):239-248.
[41] 唐国强,万玮,曾子悦,等.全球降水测量(GPM)计划及其最新进展综述[J].遥感技术与应用,2015,30(4):607-615.
相似文献/References:
[1]李慧,杨涛,何祺胜,等.新疆天山山区TRMM卫星降水数据的精度检验和校正方法研究[J].水土保持研究,2017,24(06):327.
LI Hui,YANG Tao,HE Qisheng,et al.Research on Accuracy Validation and Calibration Methods of TRMM in Tianshan Mountains of Xinjiang[J].Research of Soil and Water Conservation,2017,24(03):327.
[2]朱红雷,史晓亮,李英臣,等.基于SWAT模型的TRMM降水数据径流模拟适宜性评价[J].水土保持研究,2017,24(05):105.
ZHU Honglei,SHI Xiaoliang,LI Yingchen,et al.Evaluation of Runoff Simulation Using TRMM Precipitation Data Based on SWAT Model[J].Research of Soil and Water Conservation,2017,24(03):105.
[3]潘虹,邱新法,高婷,等.基于TRMM和NCEP-FNL数据的降水估算研究[J].水土保持研究,2014,21(02):116.
PAN Hong,QIU Xin-fa,GAO Ting,et al.Study on the Estimation of Precipitation with the Data of TRMM and NCEP-FNL[J].Research of Soil and Water Conservation,2014,21(03):116.
[4]靖娟利,罗福林,王永锋,等.1998-2017年滇黔桂岩溶区降水时空动态特征[J].水土保持研究,2019,26(05):158.
JING Juanli,LUO Fulin,WANG Yongfeng,et al.Spatial and Temporal Dynamics of Precipitation in Dian-Qian-Gui Karst Area from 1998 to 2017[J].Research of Soil and Water Conservation,2019,26(03):158.
[5]程 扬,郭 燕,齐鹏云,等.GPM IMERGE卫星遥感降水数据在巢湖流域的精度评价[J].水土保持研究,2020,27(05):188.
CHENG Yang,GUO Yan,QI Pengyun,et al.Analysis of Accuracy of GPM IMERGE Precipitation Data in Chaohu Basin[J].Research of Soil and Water Conservation,2020,27(03):188.
[6]薛 健,李宗省,李宗杰,等.基于TRMM数据的祁连山大气降水时空分布特征[J].水土保持研究,2021,28(01):204.
XUE Jian,LI Zongsheng,LI Zongjie,et al.Spatial and Temporal Distribution Characteristics of Precipitation in Qilian Mountains Based on TRMM Data[J].Research of Soil and Water Conservation,2021,28(03):204.
[7]刘益锋,汪小钦,吴思颖,等.GPM与TRMM卫星降雨数据在福建省的适用性对比分析[J].水土保持研究,2019,26(06):311.
LIU Yifeng,WANG Xiaoqin,WU Siying,et al.Comparative Analysis of Applicability of GPM and TRMM Satellite Precipitation Data in Fujian Province[J].Research of Soil and Water Conservation,2019,26(03):311.
备注/Memo
收稿日期:2017-06-08;改回日期:2017-08-08。
基金项目:国家重点研发计划项目(2016YFC0402400);国家自然科学基金(51779099,41301496);中央级公益性科研院所基本科研业务费专项资金(HKY-JBYW-2017-10)
作者简介:董国涛(1982-),男,山东青州人,博士,高级工程师,主要从事水文水资源遥感方面研究。E-mail:dongguotao@hky.yrcc.gov.cn
通讯作者:樊东(1992-),男,四川宜宾人,硕士研究生,研究方向为3S技术理论与应用。E-mail:fan_zhonghe@163.com