Validation and Evaluation of Ocean Calibration Accuracy of FY-3G Precipitation Measurement Radar

Yuan Mei; Yin Honggang; Shang Jian; Jiang Baisen; Yang Runfeng; Gu Songyan; Zhang Peng

doi:10.11898/1001-7313.20240502

应用气象学报 (Sep 2024)

Validation and Evaluation of Ocean Calibration Accuracy of FY-3G Precipitation Measurement Radar

Yuan Mei,
Yin Honggang,
Shang Jian,
Jiang Baisen,
Yang Runfeng,
Gu Songyan,
Zhang Peng

Affiliations

Yuan Mei: National Satellite Meteorological Center/National Center for Space Weather, Beijing 100081
Yin Honggang: National Satellite Meteorological Center/National Center for Space Weather, Beijing 100081
Shang Jian: National Satellite Meteorological Center/National Center for Space Weather, Beijing 100081
Jiang Baisen: Beijing Research Institute of Telemetry, Beijing 100076
Yang Runfeng: Beijing Research Institute of Telemetry, Beijing 100076
Gu Songyan: National Satellite Meteorological Center/National Center for Space Weather, Beijing 100081
Zhang Peng: Meteorological Observation Center, CMA, Beijing 100081

DOI: https://doi.org/10.11898/1001-7313.20240502
Journal volume & issue: Vol. 35, no. 5
pp. 526 – 537

Abstract

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FY-3G precipitation satellite launched in April 2023 is the first dedicated precipitation measurement satellite in China. The dual-frequency precipitation measurement radar (PMR) is the core instrument on the satellite. Because the backscattering performance of the vast ocean area is relatively stable, the calibration accuracy of the on-orbit radar can be tested by studying the backscattering cross-section of the sea surface. FY-3G PMR level 1 data in July 2023 and GPM DPR (global precipitation measurement, dual-frequency precipitation radar) level 2A data are used to analyze the mean value and mean square error of the global sea surface backscattering cross section under no-rain conditions to evaluate the radar performance. At the same time, the theoretical model of ocean surface backscattering is studied to simulate the sea surface backscattering cross-section under the condition of no rain, and the sea surface backscattering cross-section is compared with the actual radar measurement, so as to realize the preliminary evaluation of FY-3G PMR calibration accuracy. Furthermore, the accuracy of FY-3G PMR calibration is evaluated by the ocean calibration test results of GPM DPR data. Test results of ocean calibration accuracy show that when the incidence angle of FY-3G PMR Ku-band is less than 15°, the deviation between the observed value and the model simulation value is small. The deviation of FY-3G PMR ranges from 1.65 to 2.73 dB, while the standard deviation ranges from 0.74 to 1.82 dB. The deviation of FY-3G PMR Ka-band at an 18° incidence is less than 0.27 dB, and the standard deviation of the deviation is 3.49 dB. The calibration deviation of FY-3G PMR and GPM DPR is relatively constant, with the difference is primarily attributed to the backscattering statistical characteristics of the data itself. The stability of the backscattering data of FY-3G PMR Ku- and Ka-band sea surfaces at each incidence angle is comparable to that of GPM DPR. Gas attenuation is not considered at the moment. In the future, the impact of gas attenuation on the Ku- and Ka-band ocean calibration accuracy validation will be further evaluated, and the systematic deviation of FY-3G PMR will be corrected.

Published in 应用气象学报

ISSN: 1001-7313 (Print)
Publisher: Editorial Office of Journal of Applied Meteorological Science
Country of publisher: China
LCC subjects: Science: Physics: Meteorology. Climatology
Website: http://qikan.camscma.cn/indexen.htm

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