An Improved Temperature and Emissivity Separation Algorithm for the Advanced Himawari Imager

This study proposes an improved temperature and emissivity separation (TES) algorithm for simultaneously retrieving the land surface temperature and emissivity (LST&E) from the Advanced Himawari Imager (AHI) data, including a modified water vapor scaling (WVS) method and a calibrated empirical r...

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Bibliographic Details
Published inIEEE transactions on geoscience and remote sensing Vol. 58; no. 10; pp. 7105 - 7124
Main Authors Zhou, Shugui, Cheng, Jie
Format Journal Article
LanguageEnglish
Published New York IEEE 01.10.2020
The Institute of Electrical and Electronics Engineers, Inc. (IEEE)
Subjects
Advanced Himawari Imager (AHI)
Algorithms
Bias
Emissivity
Evaluation
Himawari-8
In situ measurement
Inland waters
Lakes
Land surface
land surface emissivity (LSE)
Land surface temperature
land surface temperature (LST)
MODIS
Ocean temperature
Radiance
Scaling
Sea surface
Separation
Spatial distribution
Surface temperature
Surface topography
Temperature
temperature and emissivity separation (TES)
Temperature sensors
thermal infrared (TIR)
Water vapor
Water vapour
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Summary:This study proposes an improved temperature and emissivity separation (TES) algorithm for simultaneously retrieving the land surface temperature and emissivity (LST&E) from the Advanced Himawari Imager (AHI) data, including a modified water vapor scaling (WVS) method and a calibrated empirical relationship over vegetated surfaces. The modified WVS algorithm is comparable to the original WVS algorithm in deriving the LST&E but expands the application scope of the original WVS algorithm. The calibrated empirical relationship improved the LST&E and retrieval accuracy over vegetated surfaces by up to 0.165 K and 0.004, respectively. Comprehensive validation and evaluation are conducted in this study. In situ measurements from three networks are collected for the temperature-based validation. The bias and RMSE are 0.19 and 2.93 K in the daytime, and −0.43 and 1.95 K in the nighttime, respectively. Radiance-based LST validation shows that the bias and RMSE are 0.25 and 1.88 K, respectively. In addition, the AHI LST is evaluated using the MYD11 LST over large inland lakes, and the bias and RMSE are 0.25 and 1.12 K, respectively. The AHI LST is also compared to the MYD21 LST. The spatial distributions of the two LSTs are similar, and the LST differences are mostly within 4 K. The bias of the AHI LST ranges from −0.57 to 0.36 K, and the RMSE ranges from 1.7 to 2.64 K. The retrieved AHI LSE is compared with the latest MYD21 LSE. The biases and RMSEs are smaller than 0.005 and 0.014, respectively, for the three AHI bands. The improved TES algorithm is proven to be capable of obtaining accurate LST and LSE from AHI data.
ISSN:0196-2892
1558-0644
DOI:10.1109/TGRS.2020.2979846