In-Orbit Calibration of FengYun-3C Microwave Radiation Imager: Characterization of Backlobe Intrusion for the Hot-Load Reflector

In-Orbit Calibration of FengYun-3C Microwave Radiation Imager: Characterization of Backlobe Intrusion for the Hot-Load Reflector

This study presents a correction algorithm to remove the backlobe intrusion from the hot-load reflector of microwave radiation imager (MWRI) on-board China FengYun-3C (FY-3C) meteorological satellite. Discontinuities in the radiometric gain of MWRI, due to inaccurate backlobe spillover of the hot-lo...

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Bibliographic Details
Main Authors: Xinxin Xie, Wanting Meng, Kesong Dong, Songyan Gu, Xue Li
Format: Article
Language:English
Published: IEEE 2021-01-01
Series:IEEE Journal of Selected Topics in Applied Earth Observations and Remote Sensing
Subjects:
Backlobe spillover
calibration
FengYun-3C (FY-3C)
microwave radiation imager (MWRI)
microwave radiometer
Online Access:https://ieeexplore.ieee.org/document/9416844/
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spelling doaj-29bf988f23e841eaa93e39b94a12789d2021-07-14T23:00:06ZengIEEEIEEE Journal of Selected Topics in Applied Earth Observations and Remote Sensing2151-15352021-01-01146686669310.1109/JSTARS.2021.30759699416844In-Orbit Calibration of FengYun-3C Microwave Radiation Imager: Characterization of Backlobe Intrusion for the Hot-Load ReflectorXinxin Xie0https://orcid.org/0000-0002-4475-6673Wanting Meng1Kesong Dong2https://orcid.org/0000-0003-1152-0389Songyan Gu3https://orcid.org/0000-0001-9732-3241Xue Li4School of Atmospheric Sciences of Sun Yat-Sen University, the Key Laboratory of Tropical Atmosphere-Ocean System of Ministry of Education, Zhuhai, ChinaShanghai Spaceflight Institute of TT&C and Telecommunication, Shanghai, ChinaShanghai Spaceflight Institute of TT&C and Telecommunication, Shanghai, ChinaNational Satellite Meteorology Center, Beijing, ChinaShanghai Spaceflight Institute of TT&C and Telecommunication, Shanghai, ChinaThis study presents a correction algorithm to remove the backlobe intrusion from the hot-load reflector of microwave radiation imager (MWRI) on-board China FengYun-3C (FY-3C) meteorological satellite. Discontinuities in the radiometric gain of MWRI, due to inaccurate backlobe spillover of the hot-load reflector, have been diagnosed. A physical correction method, relating the radiometric gain difference between two distinct backlobe scenes to the spillover of the hot-load reflector, is thus established to estimate the in-orbit spillover factor of the MWRI hot-load reflector. Meanwhile, it is found that brightness temperature (TB) at each 1° × 1° grid could not address the backlobe pattern appropriately, leading to abrupt changes in the radiometric gain occurring near the coastlines. To better represent the backlobe spillover, the effective backlobe TB is now averaged over a 4° × 4° area from advanced microwave scanning radiometer-observed TBs, which is now in a finer resolution of 0.25° × 0.25°. With the adjusted spillover for the hot-load reflector, anomalous behaviors of the radiometric gain are mitigated effectively and the improvement at the coastlines is pronounced, inducing TB variation up to 2 K in magnitude at the 10.65 GHz channel. Although the algorithm presented in this study is only restricted to channel frequencies up to 23.8 GHz due to its accuracy limitation, it could tackle similar issues for those microwave radiometers not capable of in-orbit backlobe maneuvers and receiving the radiances inevitably from the outer edge of the hot-load or cold-sky reflectors.https://ieeexplore.ieee.org/document/9416844/Backlobe spillovercalibrationFengYun-3C (FY-3C)microwave radiation imager (MWRI)microwave radiometer
collection DOAJ
language English
format Article
sources DOAJ
author Xinxin Xie
Wanting Meng
Kesong Dong
Songyan Gu
Xue Li
spellingShingle Xinxin Xie
Wanting Meng
Kesong Dong
Songyan Gu
Xue Li
In-Orbit Calibration of FengYun-3C Microwave Radiation Imager: Characterization of Backlobe Intrusion for the Hot-Load Reflector
IEEE Journal of Selected Topics in Applied Earth Observations and Remote Sensing
Backlobe spillover
calibration
FengYun-3C (FY-3C)
microwave radiation imager (MWRI)
microwave radiometer
author_facet Xinxin Xie
Wanting Meng
Kesong Dong
Songyan Gu
Xue Li
author_sort Xinxin Xie
title In-Orbit Calibration of FengYun-3C Microwave Radiation Imager: Characterization of Backlobe Intrusion for the Hot-Load Reflector
title_short In-Orbit Calibration of FengYun-3C Microwave Radiation Imager: Characterization of Backlobe Intrusion for the Hot-Load Reflector
title_full In-Orbit Calibration of FengYun-3C Microwave Radiation Imager: Characterization of Backlobe Intrusion for the Hot-Load Reflector
title_fullStr In-Orbit Calibration of FengYun-3C Microwave Radiation Imager: Characterization of Backlobe Intrusion for the Hot-Load Reflector
title_full_unstemmed In-Orbit Calibration of FengYun-3C Microwave Radiation Imager: Characterization of Backlobe Intrusion for the Hot-Load Reflector
title_sort in-orbit calibration of fengyun-3c microwave radiation imager: characterization of backlobe intrusion for the hot-load reflector
publisher IEEE
series IEEE Journal of Selected Topics in Applied Earth Observations and Remote Sensing
issn 2151-1535
publishDate 2021-01-01
description This study presents a correction algorithm to remove the backlobe intrusion from the hot-load reflector of microwave radiation imager (MWRI) on-board China FengYun-3C (FY-3C) meteorological satellite. Discontinuities in the radiometric gain of MWRI, due to inaccurate backlobe spillover of the hot-load reflector, have been diagnosed. A physical correction method, relating the radiometric gain difference between two distinct backlobe scenes to the spillover of the hot-load reflector, is thus established to estimate the in-orbit spillover factor of the MWRI hot-load reflector. Meanwhile, it is found that brightness temperature (TB) at each 1° × 1° grid could not address the backlobe pattern appropriately, leading to abrupt changes in the radiometric gain occurring near the coastlines. To better represent the backlobe spillover, the effective backlobe TB is now averaged over a 4° × 4° area from advanced microwave scanning radiometer-observed TBs, which is now in a finer resolution of 0.25° × 0.25°. With the adjusted spillover for the hot-load reflector, anomalous behaviors of the radiometric gain are mitigated effectively and the improvement at the coastlines is pronounced, inducing TB variation up to 2 K in magnitude at the 10.65 GHz channel. Although the algorithm presented in this study is only restricted to channel frequencies up to 23.8 GHz due to its accuracy limitation, it could tackle similar issues for those microwave radiometers not capable of in-orbit backlobe maneuvers and receiving the radiances inevitably from the outer edge of the hot-load or cold-sky reflectors.
topic Backlobe spillover
calibration
FengYun-3C (FY-3C)
microwave radiation imager (MWRI)
microwave radiometer
url https://ieeexplore.ieee.org/document/9416844/
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AT wantingmeng inorbitcalibrationoffengyun3cmicrowaveradiationimagercharacterizationofbacklobeintrusionforthehotloadreflector
AT kesongdong inorbitcalibrationoffengyun3cmicrowaveradiationimagercharacterizationofbacklobeintrusionforthehotloadreflector
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AT xueli inorbitcalibrationoffengyun3cmicrowaveradiationimagercharacterizationofbacklobeintrusionforthehotloadreflector
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