应用FY-3 MERSI数据反演地表温度

doi:10.11924/j.issn.1000-6850.casb15020047

中国农学通报 ›› 2015, Vol. 31 ›› Issue (22): 223-229.doi: 10.11924/j.issn.1000-6850.casb15020047

• 资源环境生态土壤气象 • 上一篇下一篇

应用FY-3 MERSI数据反演地表温度

李琳琳¹,李国春²,王莹¹,张琪¹,张晓月¹,赵梓淇³,赵刚⁴,宋晓巍⁵

(¹辽宁省气象科学研究所,沈阳 110161；²沈阳农业大学,沈阳 110866；³沈阳大气科学研究所,沈阳 110161；⁴葫芦岛绥中县气象局,辽宁葫芦岛 125200；⁵沈阳市气象局,沈阳 110168）

收稿日期:2015-02-06 修回日期:2015-07-06 接受日期:2015-05-22 出版日期:2015-08-20 发布日期:2015-08-20
通讯作者: 李琳琳
基金资助:
农业气象灾害精细化预报及风险评估研究“辽宁省科技厅农业攻关及成果产业化项目”(2014210003)。

Retrieval of Land Surface Temperature from FY-3 MERSI Data

Li Linlin¹, Li Guochun², Wang Ying¹, Zhang Qi¹, Zhang Xiaoyue¹, Zhao Ziqi³, Zhao Gang⁴, Song Xiaowei⁵

(¹Liaoning Province Public Meteorological Service Center, Shenyang 110161;²Shenyang Agricultural University, Shenyang 110866;³Shenyang Institute of Atmospheric Environment, Shenyang 110161;⁴Suizhong Meteorological Bureau of Huludao County, Huludao Liaoning 125200;⁵Shenyang Meteorological Administration, Shenyang 110168)

Received:2015-02-06 Revised:2015-07-06 Accepted:2015-05-22 Online:2015-08-20 Published:2015-08-20

摘要/Abstract

摘要： 地表温度是反映土壤—植被—大气系统能量流动与物质交换的重要参数，是地球观测类卫星数据反演地面参数的主要内容之一。气象卫星为快速获取大范围辐射面瞬时温度提供了重要手段，其中FY-3 MERSI在保留了极轨气象卫星高时间分辨率观测的基础上，其远红外波段空间分辨率提高到了250 m，提高了温度反演的空间精度。应用FY-3 MERSI第5通道长波辐射观测数据，并结合1 km分辨率高光谱数据，获取反演地温所需的2个重要参数——大气水汽含量及地表比辐射率，实现了地表温度反演。反演算法利用两通道比值法得到大气透过率，并计算出大气水汽含量；应用NDVI阈值方法获得地表比辐射率；根据FY3 MERSI通道特点改进和构造了各参数反演算法；并利用热红外通道数据，使用单通道算法反演地表温度。通过对辽宁地区3个时次的地表温度反演，并与MODIS分裂窗地表温度算法进行了比较分析。结果表明温度精度达到了预期水平，空间精度有显著提高。

关键词: 薏苡, 薏苡, 生物学特性, 氮含量, 钾含量

Abstract: Land surface temperature (LST), one of the most important ground parameter that can be retrieved from earth observation satellite data, is of great importance in studying energy flow and material exchange in soil-vegetation-atmosphere system. To acquire instantaneous LST of large area, radiation surface sensors carried by meteorological satellite platforms are often used. On board FY-3 satellite which was launched by China in 2008, MERSI is one of the sensors that can be used to get large area of LST with significant enhancement of spatial resolution to 250 m in far infrared band and leads to a higher LST spatial precision. In this paper, far infrared data of MERSI band 5 together with other MERSI hyper-spectral 1 km band data were used to calculate atmospheric transmissivity and land surface emissivity (LSE)—2 important parameters in LST retrieval. The LST retrieval algorithms were as follows. Atmospheric transmissivity which could be used to obtain water vapor content via radiation transmission model was calculated using two-channel ratio weighted method; surface emissivity was obtained via NDVI threshold method; parameters used in retrieving algorithms were improved to better suite FY-3 MERS; mono-window algorithm was used to retrieve LST. Two LST retrieving experiments were carried out in Liaoning provincial area. The retrieved products were compared with that retrieved from MODIS data using split-windows algorithm. The results demonstrate that temperature precision can reach the desired accuracy, and the spatial precision can be improved significantly.

李琳琳,李国春,王莹,张琪,张晓月,赵梓淇,赵刚,宋晓巍. 应用FY-3 MERSI数据反演地表温度[J]. 中国农学通报, 2015, 31(22): 223-229.

Li Linlin,Li Guochun,Wang Ying,Zhang Qi,Zhang Xiaoyue,Zhao Ziqi,Zhao Gang and Song Xiaowei. Retrieval of Land Surface Temperature from FY-3 MERSI Data[J]. Chinese Agricultural Science Bulletin, 2015, 31(22): 223-229.

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应用FY-3 MERSI数据反演地表温度

Retrieval of Land Surface Temperature from FY-3 MERSI Data

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