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�� 2019, 38(1) 286-292 DOI: 10.3969/j.issn.1004-5589.2019.01.028 ISSN: 1004-5589 CN: 22-1111/P

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	Article by Xie X

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1. �ຣʡ��һ��Ժ, �� 810001;
2. �人��ѧ��ѧԺ, �人 430079

ժҪ�� ȹ��ˮ��ֲ��ǶȽϵ͵��MODIS��ݷ��ݵı��ȹ��GLDAS��ݷ��ˮ��2014-2016��ˮ��ʱ�ձ仯��Աȷ��ˮ�ͽ�ˮ��Ĺ�ϵ��ˮ��ˮ��17~19 mm��Χ�ڲ��仯��Ϊ��ơ��Ķ��ϲ��ˮ��Խϸߣ��ı��ˮ��Խϵͣ��ˮ��ˮ��Ա仯��Ҫԭ��

�ؼ���� MODIS GLDAS ��ȹ�� ˮ �� ˮ��

Soil water inversion in Huangshui River basin based on MODIS and GLDAS data

SUN Mao-jun¹, LI Xia¹, LI Xiao-gang¹, XIE Xiao-wei²

1. 1st Institute of Surveying and Mapping Qinghai Province, Xining 810001, China;
2. School of Geodesy and Geomatics, Wuhan University, Wuhan 430079, China

Abstract: Soil water inversion with apparent thermal inertia is suitable for areas with low vegetation coverage. The temporal and spatial variations of soil water in Huangshui River basin from 2014 to 2016 were retrieved by using GLDAS data and apparent thermal inertia from MODIS data, and the relationship between soil water and precipitation was compared and analyzed. The results show that the surface soil water in Huangshui River basin fluctuates from 17 mm to 19 mm, and its overall change shows an increasing trend. The surface soil water storage in the southeastern part of the basin is relatively high, while that in the northwestern part is relatively low. Precipitation is the main reason for the periodic change of surface soil water.

Keywords: MODIS GLDAS apparent thermal inertia soil water inversion Huangshui River

�ո�� 2018-12-06 �޻�� 2019-01-10 ��淢��

DOI: 10.3969/j.issn.1004-5589.2019.01.028

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[1] Brocca L,Melone F,Moramarco T,et al. Soil moisture temporal stability over experimental areas in Central Italy[J]. Geoderma,2009,148(3):364-374.
[2] Wang T J,Singh K,Bardossy A. On the use of the critical event concept for quantifying soil moisture dynamics[J]. Geoderma,2019,335:27-34.
[3] �̹�ӡ. ��MODIS��ݵĵر��¶ȡ��ȹ��о��ˮ�֡��Ƚ��Ӧ��:��ʿѧλ��[D]. ��:�й��ѧԺ�о��Ժ,2006. CAI Guo-yin. MODIS data based thermal inertia and land surface temperature modeling and their applications in determination of soil moisture and heat exchange:doctor's degree thesis[D]. Beijing:Graduate University of Chinese Academy of Sciences,2006.
[4] ��Զ,��. ��MODIS��ݵ�μ��ˮ�ַ��[J]. ң��Ϣ,2008(1):66-73. TONG Zhao-yuan,ZHANG Wan-chang. Retrieval of soil moisture in Weihe River basin based on MODIS data[J]. Remote Sensing Information,2008(1):66-73.
[5] Yan S H,Zhang N,Chen N C,et al. Using reflected signal power from the BeiDou geostationary satellites to estimate soil moisture[J]. Remote Sensing Letters,2019,10(1):1-10.
[6] Price J C. Using spatial context in satellite data to infer regional scale evapotranspiration[J]. IEEE Transactions on Geoscience and Remote Sensing,1990,28(5):940-948.
[7] Tramutoli V,Pierluigi C,Marella M,et al. Hydrological implications of remotely sensed thermal inertia[C]//Owe M,Brubaker K,Ritchie J,et al. Remote Sensing and Hydrology 2000(Conference on Remote Sensing and Hydrology 2000. Santa Fe,New Mexico,USA. 2000). London:IAHS Publication,2001:207-211.
[8] ��ʻ�. ��ˮ��ȹ��ģ�ͼ��Ӧ��[J]. ��ѧͨ��,1991,36(12):924-927. ZHANG Ren-hua. Thermal inertia model of soil moisture and its application[J]. Scientific Bulletin,1991,36(12):924-927.
[9] ��,��,��,��.��ȱˮָ��μ��ɺ��[J]. �ɺ��о�,2014,31(1):118-124. WANG Yu-juan,WANG Shu-dong,ZENG Hong-juan,et al. Drought characteristic in the Weihe River basin based on water shortage index of crops[J]. Arid Zone Research,2014,31(1):118-124.
[10] Moran M S,Clarke T R,Inoue Y,et al. Estimating crop water deficit using the relation between surface-air temperature and spectral vegetation index[J]. Remote Sensing of Environment,1994,49(3):246-263.
[11] Sandholt I,Rasmussen K,Andersen J. A simple interpretation of the surface temperature/vegetation index space for assessment of surface moisture[J]. Remote Sensing of Environment,2002,79(2):213-224.
[12] ��,��,��С��. ��ֲ��¶�ָ��ڸɺ��е�Ӧ��[J]. �人��ѧѧ��(��Ϣ��ѧ��),2001,26(5):412-418. WANG Peng-xin,GONG Jian-ya,LI Xiao-wen. Vegetation-temperature condition index and its application for drought monitoring[J]. Geomatics and Information Science of Wuhan University,2001,26(5):412-418.
[13] Oh Y,Sarabandi K,Ulaby F T. An empirical model and an inversion technique for radar scattering from bare soil surfaces[J]. IEEE Transactions on Geoscience and Remote Sensing,1992,30(2):370-381.
[14] Sabburg J M. Evaluation of an Australian ERS-1 SAR scene pertaining to soil moisture measurement[C]//IEEE Proceedings of IGARSS 94(IEEE International Geoscience and Remote Sensing Symposium. Pasadena,California,USA. 1994). Piscataway,New Jersey,USA:IEEE,1994:1424-1426.
[15] ��,��,��,��. ֲ��ǵر��΢��ң�з��ˮ��㷨�о�[J]. �ȴ��,2007,27(5):411-415. LIU Wan-xia,WANG Juan,LIU Kai,et al. Algorithms for active microwave remote sensing retrieval of soil moisture from vegetation covered surface[J]. Tropical Geography,2007,27(5):411-415.
[16] ��. ��ظ�ԭ��΢��ң��Ϸ��ˮ�ֵ��о�:˶ʿѧλ��[D]. ��:�׶�ʦ��ѧ,2011. LI Qin. Inversion of soil moisture by active and passive microwave remote sensing in Qinghai-Tibet Plateau:master's degree thesis[D]. Beijing:Capital Normal University,2011.
[17] ��. ��MODIS��ݵ��ˮʪ�ȷ��о�:�Իƺ��޵��Ϊ��:˶ʿѧλ��[D]. ��̨:³��ѧ,2014. LIU Hao. Inversion of soil water and moisture based on MODIS data:a case study of the Yellow River Delta:master's degree thesis[D]. Yantai:Ludong University,2014.
[18] лСΰ,��ž�,��,��. ��GRACE��¸ʽ��ԭ��ˮ��仯[J]. ��ͨ��,2018(1):133-137. XIE Xiao-wei,XU Cai-jun,GONG Zheng,et al. Inversion of groundwater reserve change in Shaanxi-Gansu-Shanxi Plateau by GRACE[J]. Surveying and Mapping Bulletin,2018(1):133-137.
[19] ��,��,��ĺ�,��. ��GLDAS��TVDI��߶ȷ��ˮ��[J]. ��ʦ��ѧѧ��(��Ȼ��ѧ��),2016,52(3):265-270. WU Pan,FENG Yu-qing,LIANG Si-hai,et al. Inversion of soil water content based on GLDAS and TVDI downscaling[J]. Journal of Beijing Normal University(Natural Science Edition),2016,52(3):265-270.
[20] ��. ��ڸĽ��ȹ�ͨ��ģ��ˮ��ݼ��о�[J]. ˮ��ල,2018,143(3):109-111,225. ZHANG Li. Research on soil water inversion technology based on improved thermal inertia flux model[J]. Technical Supervision of Water Conservancy,2018,143(3):109-111,225.

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