TRMM 3B43降水数据在云南地区的降尺度适用性评价

doi:10.3969/j.issn.1000-6362.2020.09.004

摘要/Abstract

摘要： 借助云南省2009?2018年25个气象站点逐月降水量分析TRMM 3B43降水数据特征，利用相关系数（R）、偏离率（BIAS）、均方根误差（RMSE）和平均绝对误差对TRMM 3B43月降水数据和各站点进行适用性分析，并探讨该数据与海拔、坡度、坡向之间的关系，最后将TRMM 3B43月降水数据降尺度至季、年尺度，并对其进行适用性评价，为复杂地形地区开展区域降水研究、水文预报等提供可靠降水产品数据。结果表明：（1）TRMM 3B43降水数据与实测降水数据变化趋势基本一致，降水量均表现为西多东少、南多北少，且大致随海拔高度呈阶梯式分布；（2）TRMM 3B43月降水量与实测降水量具有极显著相关性，R高达0.9392，BIAS接近0，且TRMM 3B43降水数据在25个站点R值均超过0.735，大多数站点的偏离度和误差较小，其整体精度较高；（3）TRMM 3B43数据精度受坡度的影响比海拔、坡向大，但多数站点在不同海拔高度、坡度和坡向的精度均较高，适用性较强，尤其是海拔位于1000-2000m、坡度小于4°、坡向位于160°-240°的站点数据适用性更强；（4）降时间尺度后的TRMM 3B43数据相关系数稍有降低，误差变大，尤其是在冬季和年尺度适用性稍差。TRMM 3B43月降水数据在云南地区具有较高的精度，可为地面降水数据提供有效补充。

关键词: TRMM 3B43, 降水数据, 适用性评价, 地形因子, 云南地区

Abstract: Precipitation exerts an important role in the exchange of matter and energy in the global water cycle, affecting soil moisture, vegetation growth, and surface runoff. By employing existing station data, the spatial distribution of precipitation obtained by the meteorological observation method was obtained by interpolation. However, the interpolation results of a small number of meteorological stations are challenging to accurately analyze the spatial variation characteristics of actual precipitation. Launched on 28 November 1997, the Tropical Rainfall Measuring Mission (TRMM) was jointly developed by the United States National Aeronautics and Space Administration (NASA) and the Japan Aerospace Exploration Agency (JAXA), thus providing long time series and covering most regions of the world with precipitation rate data. Nevertheless, TRMM was obtained by indirect precipitation measurement. Meanwhile, there were related errors and uncertainties. As a result, TRMM accuracy evaluation was the primary work of regional precipitation research. The terrain of Yunnan Province is complex, and the altitude difference is large. In addition, it is affected by the southwest monsoon and southeast monsoon. Complex factors such as the uneven distribution of precipitation may affect the detection capabilities of TRMM satellites. However, the current evaluation of the applicability of TRMM data in Yunnan Province is only a simple analysis of the coefficient of determination. Besides, the research on the factors affecting the accuracy of TRMM precipitation data and errors such as deviation rate is still lacking. In the present study, the accuracy of TRMM 3B43 precipitation data was evaluated in Yunnan, where the terrain was complex, aiming to provide reliable precipitation product data for regional precipitation research and hydrological forecasting. Monthly precipitation from 25 meteorological stations in Yunnan province from 2009 to 2018 provided by the China Meteorological Data Service Center was used to analyze the characteristics of TRMM 3B43 precipitation data. The correlation coefficient(R), BIAS, root mean square error (RMSE) and mean absolute error (MAE) were used to analyze the applicability between TRMM 3B43 monthly precipitation data and meteorological station data. Then, the relationship between the TRMM 3B43 precipitation data corresponding to each station and the elevation, slope, and aspect was discussed in this study. Finally, the data was downscaled to the seasonal and annual scales. At the same time, its applicability was evaluated. Some results the current study showed that: (1) the mean difference between TRMM 3B43 precipitation data and measured precipitation data was small, especially at Luxi station, where the difference was only 0.02mm. The TRMM 3B43 precipitation data was basically in consistence with the measured precipitation data, showing that there were more in the west and south and less in the east and north. It was roughly distributed step by step with the altitude. However, the difference in the spatial distribution of precipitation caused by the difference in altitude and latitude of each station also revealed the difference between TRMM 3B43 and the measured precipitation. Therefore, it is of much necessity to evaluate its applicability before using TRMM data.(2) With an R as high as 0.9392, BIAS close to zero, RMSE as low as 32.9776mm, and MAE as low as 20.5730mm, TRMM 3B43 displayed an extremely significant correlation between monthly precipitation and measured precipitation. In the range of TRMM 3B43 monthly precipitation less than 250mm, the accuracy of the fitting was relatively higher. The TRMM 3B43 precipitation data exceeded 0.735 at 25 stations, which passed the significance test at the 0.01 level, and the deviation and error of most stations were small with high overall accuracy. However, due to the different geographical locations of the stations, the deviation and error of the data presented certain differences. (3) The accuracy of TRMM 3B43 data was more affected by the slope than the altitude and aspect. The correlation coefficients of slope and R, RMSE and MAE were 0.8167, 0.7071 and 0.6865 respectively, showing strong quadratic function relationship characteristics. Except for the TRMM 3B43 precipitation data at Gongshan station and Weixi station, the accuracy of most stations at different altitudes, slopes and aspect was higher, having stronger applicability. Particularly, the data applicability was stronger for sites located at an altitude of 1000-2000m, slope less than 4°, and slope direction of 160°-240°. (4) The correlation coefficient of TRMM 3B43 data after time downscaling was slightly reduced. The error was slightly larger, especially in the winter and the annual scale slightly remained less suitable. With the largest error in summer, the RMSE and MAE of the TRMM 3B43 precipitation in Yunnan Province and the measured precipitation in each season were both less than 97mm and 78mm, respectively. The transmissibility of errors caused the RMSE and MAE of the annual scale TRMM data to become larger, and the applicability was the worst compared to other time scales. Therefore, the TRMM 3B43 monthly precipitation data had high accuracy in Yunnan region, which could thus provide effective supplement to the surface precipitation data.

Key words: TRMM 3B43, Precipitation data, Applicability evaluation, Topographic factor, Yunnan Province

中图分类号:

玉院和，王金亮. TRMM 3B43降水数据在云南地区的降尺度适用性评价[J]. 中国农业气象, 2020, 41(09): 575-586.

YU Yuan-he, WANG Jin-liang. Applicability Evaluation of TRMM 3B43 Precipitation Data for Downscaling in Yunnan Province[J]. Chinese Journal of Agrometeorology, 2020, 41(09): 575-586.

参考文献 30

[1]	Cao Y,Zhang W,Wang W.Evaluation of TRMM 3B43 data over the Yangtze River Delta of China[J].Scientific Reports, 2018,8(1):5290.
[2]	郑杰,闾利,冯文兰,等.基于TRMM 3B43数据的川西高原月降水量空间降尺度模拟[J].中国农业气象,2016, 37(2): 245-254. Zheng J,Lv L,Feng W L,et al.Spatial downscaling mimulation of monthly precipitation based on TRMM 3B43 data in the Western Sichuan Plateau[J].Chinese Journal of Agrometeorology, 2016,37(2):245-254.(in Chinese)
[3]	李豪,雷苑.复杂地形下TRMM降水数据的降尺度研究:以四川省为例[J].中国农业气象,2019,40(10):607-619. Li H,Lei Y.Spatial dwnscaling of TRMM precipitation data in areas of complex terrain:a case study in Sichuan Province[J]. Chinese Journal of Agrometeorology,2019,40(10):607-619.(in Chinese)
[4]	玉院和,王金亮,李晓鹏.基于MODIS数据的滇中地区干旱监测[J].灌溉排水学报,2018,37(11):91-98. Yu Y H,Wang J L,Li X P.Monitoring the occurrence of drought in Central Yunnan Province based on MODIS data[J]. Journal Irrigation Drainage,2018,37(11):91-98.(in Chinese)
[5]	Zhou Z,Guo B,Su Y,et al.Multidimensional evaluation of the TRMM 3B43V7 satellite-based precipitation product in mainland China from 1998-2016[J].Peer J,2020,8:e8615.
[6]	Yu Y H,Wang J L,Cheng F,et al.Soil moisture by remote sensing retrieval in the tropic of cancer of Yunnan Province [J].Polish Journal of Environmental Studies,2020,29(2):1981- 1993.
[7]	童德明,白雲,张莎,等.干旱严重程度指数(DSI)在山东省干旱遥感监测中的适用性[J].中国农业气象,2020,41(2): 102-112. Tong D M,Bai Y,Zhang S,et al.Applicability of drought severity index(DSI) in remote sensing monitoring of drought in Shandong Province[J].Chinese Journal of Agrometeorology, 2020,41(2):102-112.(in Chinese)
[8]	张冬冬,鲁帆,严登华,等.云南省干旱时空演变规律及季节连旱的概率特征分析[J].应用基础与工程科学学报,2014, 22(4):705-717. Zhang D D,Lu F,Yan D H,et al.Spatio-temporal analysis of droughts and the characteristic of continuous seasonal droughts probability in Yunnan Province[J].Journal of Hydraulic Engineering,2014,22(4):705-717.(in Chinese)
[9]	刘小刚,冷险险,孙光照,等.基于1961-2100年SPI和SPEI的云南省干旱特征评估[J].农业机械学报,2018,49(12): 236-245. Liu X G,Leng X X,Sun G Z,et al.Assessment of drought characteristics in Yunnan Province based on SPI and SPEI from 1961 to 2100[J].Transactions of the Chinese Society for Agricultural Machinery,2018,49(12):236-245.(in Chinese)
[10]	任菊章,黄中艳,郑建萌.基于相对湿润度指数的云南干旱气候变化特征[J].中国农业气象,2014,35(5):567-574. Ren J Z,Huang Z Y,Zheng J M.Analysis on drought climate change in Yunnan based on relative moisture index[J]. Chinese Journal of Agrometeorology,2014,35(5):567-574.(in Chinese)
[11]	王昊,姜超,王鹤松,等.中国西南部区域雨季极端降水指数时空变化特征[J].中国农业气象,2019,40(1):1-14. Wang H,Jiang C,Wang H S,et al.Spatial and temporal variation of extreme precipitation indices in southwestern China in the rainy season[J].Chinese Journal of Agrometeorology, 2019,40(1):1-14.(in Chinese)
[12]	杨东,刘雯,朱靖轩,等.TRMM降水数据在洞庭湖流域的精度评估和应用[J].水土保持研究,2019,26(3):279-284. Yang D,Liu W,Zhu J X,et al.Accuracy evaluation and application of the TRMM precipitation data in Dongting Lake Basin[J].Research of Soil and Water Conservation, 2019,26(3):279-284.(in Chinese)
[13]	Gumindoga W,Rientjes T,Haile A T,et al.Performance evaluation of CMORPH satellite precipitation product in the Zambezi Basin[J].International Journal of Remote Sensing, 2019,40(20):7730-7749.
[14]	Yan Y,Wu H,Gu G,et al.Climatology and interannual variability of floods during the TRMM Era (1998-2013) [J].Journal of Climate,2020,33(8):3289-3305.
[15]	Maghsood F F,Hashemi H,Hosseini S H,et al.Ground validation of GPM IMERG precipitation products over Iran[J].Remote Sensing,2020,12(1):48.
[16]	孟庆博,刘艳丽,刘冀,等.TRMM卫星降水产品在尼洋河流域的适用性定量分析[J].水资源与水工程学报,2019, 30(1):89-96. Meng Q B,Liu Y L,Liu J,et al.Quantitative analysis on the applicability of TRMM satellite precipitation products in the Niyang River Basin[J].Journal of Water Resources & Water Engineering,2019,30(1):89-96.(in Chinese)
[17]	黄桂平,曹艳萍.TRMM卫星3B43降水数据在黄河流域的精度分析[J].遥感技术与应用,2019,34(5):1111-1120. Huang G P,Cao Y P.Accuracy analysis of TRMM 3B43 precipitation data in the Yellow River Basin[J].Remote Sensing Technology and Applicatior,2019,34(5):1111- 1120.(in Chinese)
[18]	程立真,杨梅学,王学佳,等.TRMM 3B42降水产品在洮河中上游的精度评估分析[J].高原气象,2020,39(1):185-195. Cheng L Z,Yang M X,Wang X J,et al.Analysis of the accuracy of TRMM 3B42 rainfall data in the upper and middle reaches of Taohe River[J].Plateau Meteorology,2020, 39(1):185-195.(in Chinese)
[19]	杨星星,杨云川,邓思敏,等.广西TRMM降雨产品多时间尺度精度评估[J].热带气象学报,2019,35(4):567-576. Yang X X,Yang Y C,Deng S M,et al.Accuracy assessment of TRMM rainfall data in Guangxi at multiple time scales[J].Journal of Tropical Meteorology,2019,35(4): 567-576.(in Chinese)
[20]	杨荣芳,曹根华,张婧.TRMM 3B43卫星降水数据在京津冀地区的适用性研究[J].冰川冻土,2019,41(3):689-696. Yang R F,Cao G H,Zhang J.Research of TRMM3 B43 satellite precipitation data applicability in Beijing-Tianjin- Hebei Region[J].Journal of Glaciology and Geocryology, 2019,41(3):689-696.(in Chinese)
[21]	Mahbod M,Veronesi F,Shirvani A.An evaluative study of TRMM precipitation estimates over multi-day scales in a semi-arid region,Iran[J].International Journal of Remote Sensing,2019,40(11):4143-4174.
[22]	Shukla A K,Ojha C S P,Singh R P,et al.Evaluation of TRMM precipitation dataset over Himalayan Catchment:the upper Ganga Basin,India[J].Water,2019,11(3):613.
[23]	张月圆,李运刚,季漩,等.红河流域TRMM卫星降水数据精度评价[J].水资源与水工程学报,2017,28(2):1-8. Zhang Y Y,Li Y G,Ji X,et al.Accuracy evaluation of TRMM satellite precipitation product over the Red River basin[J]. Journal of Water Resources & Water Engineering, 2017,28(2):1-8.(in Chinese)
[24]	吴建峰,林淑贞,李威,等.贵州高原地带TRMM 3B42卫星降水数据的精度评价[J].水文,2018,38(4):87-91. Wu J F,Lin S Z,Li W,et al.Evaluation of TRMM 3B42 satellite precipitation data accuracy of Guizhou Plateau[J]. Journal of China Hydrology,2018,38(4):87-91.(in Chinese)
[25]	吴建峰,陈阿林,嵇涛,等.TRMM降水数据在复杂山地的精度评估:以重庆市为例[J].水土保持通报,2014,34 (4): 201-207. Wu J F,Chen A L,Ji T,et al.Accuracy evaluation of Tropical Rainfall Measuring Mission precipitation data in complex mountainous areas:taking Chongqing City as an example[J].Bulletin of Soil and Water Conservation,2014,34(4): 201-207.(in Chinese)
[26]	冯海涛,于国荣,杨具瑞.基于TRMM 3B43 V7数据的云南降水与干旱监测及精度评价[J].水资源与水工程学报, 2014,25(4):89-96. Feng H T,Yu G R,Yang J R.Precipitation and drought monitoring based on TRMM 3B43 V7data and precision evaluation in Yunnan[J].Journal of Water Resources & Water Engineering,2014,25(4):89-96.(in Chinese)
[27]	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. Li Q,Yang M X,Wang G N,et al.Analysis of the accuracy of TRMM 3B43 precipitation data in the Source Region of the Yellow River[J].Journal of Glaciology and Geocryology, 2016,38(3):620-633.(in Chinese)
[28]	黄国如,陈晓丽.北江飞来峡流域TRMM卫星降雨数据适应性研究[J].南水北调与水利科技,2019(4):27-36. Huang G R,Chen X L.Adaptability of TRMM satellite rainfall data in Feilaixia Catchment of Beijiang River Basin[J].South-to-North Water Transfers and Water Science &.Technology,2019(4):27-36.(in Chinese)
[29]	徐东,邹进,陆颖,等.TRMM卫星降水数据在怒江流域的适用性分析[J].水土保持研究,2019,26(1):240-244. Xu D,Zou J,Lu Y,et al.Evaluation on applicability of TRMM satellite precipitation product in the Nujiang River Basin [J].Research of Soil and Water Conservation,2019,26(1): 240-244.(in Chinese)
[30]	周秋文,李芳.TRMM降雨数据在喀斯特地区的适用性分析:以贵州省为例[J].水资源与水工程学报,2018, 29(2): 76-83. Zhou Q W,Li F.Applicability analysis of the TRMM precipitation data in Karst region:a case study in Guizhou Province,China[J].Journal of Water Resources & Water Engineering,2018,29(2):76-83.(in Chinese)