Korean J. Remote Sens. 2023; 39(6): 1553-1563
Published online: December 31, 2023
https://doi.org/10.7780/kjrs.2023.39.6.2.4
© Korean Society of Remote Sensing
이은경 1)·배수정 1)·안재현 2)·이경상 2)*
1) 한국해양과학기술원 해양위성센터 기술원(Research Specialist, Korea Ocean Satellite Center, Korea Institute of Ocean Science and Technology, Busan, Republic of Korea) 2) 한국해양과학기술원 해양위성센터 선임연구원(Senior Researcher, Korea Ocean Satellite Center, Korea Institute of Ocean Science and Technology, Busan, Republic of Korea)
The Geostationary Ocean Color Imager-II (GOCI-II) is a satellite designed for ocean color observation, covering the Northeast Asian region and the entire disk of the Earth. It commenced operations in 2020, succeeding its predecessor, GOCI, which had been active for the previous decade. In this study, we aimed to enhance the atmospheric correction algorithm, a critical step in producing satellite-based ocean color data, by performing cross-calibration on the GOCI-II near-infrared (NIR) band using the GOCI NIR band. To achieve this, we conducted a cross-calibration study on the top-ofatmosphere (TOA) radiance of the NIR band and derived a vicarious calibration gain for two NIR bands (745 and 865 nm). As a result of applying this gain, the offset of two sensors decreased and the ratio approached 1. It shows that consistency of two sensors was improved. Also, the Rayleigh-corrected reflectance at 745 nm and 865 nm increased by 5.62% and 9.52%, respectively. This alteration had implications for the ratio of Rayleigh-corrected reflectance at these wavelengths, potentially impacting the atmospheric correction results across all spectral bands, particularly during the aerosol reflectance correction process within the atmospheric correction algorithm. Due to the limited overlapping operational period of GOCI and GOCI-II satellites, we only used data from March 2021. Nevertheless, we anticipate further enhancements through ongoing cross-calibration research with other satellites in the future. Additionally, it is essential to apply the vicarious calibration gain derived for the NIR band in this study to perform vicarious calibration for the visible channels and assess its impact on the accuracy of the ocean color products.
Keywords GOCI-II, Ocean color, Vicarious calibration, Cross-calibration, Atmospheric correction
Korean J. Remote Sens. 2023; 39(6): 1553-1563
Published online December 31, 2023 https://doi.org/10.7780/kjrs.2023.39.6.2.4
Copyright © Korean Society of Remote Sensing.
이은경 1)·배수정 1)·안재현 2)·이경상 2)*
1) 한국해양과학기술원 해양위성센터 기술원(Research Specialist, Korea Ocean Satellite Center, Korea Institute of Ocean Science and Technology, Busan, Republic of Korea) 2) 한국해양과학기술원 해양위성센터 선임연구원(Senior Researcher, Korea Ocean Satellite Center, Korea Institute of Ocean Science and Technology, Busan, Republic of Korea)
이은경 1)·배수정 1)·안재현 2)·이경상 2)*
The Geostationary Ocean Color Imager-II (GOCI-II) is a satellite designed for ocean color observation, covering the Northeast Asian region and the entire disk of the Earth. It commenced operations in 2020, succeeding its predecessor, GOCI, which had been active for the previous decade. In this study, we aimed to enhance the atmospheric correction algorithm, a critical step in producing satellite-based ocean color data, by performing cross-calibration on the GOCI-II near-infrared (NIR) band using the GOCI NIR band. To achieve this, we conducted a cross-calibration study on the top-ofatmosphere (TOA) radiance of the NIR band and derived a vicarious calibration gain for two NIR bands (745 and 865 nm). As a result of applying this gain, the offset of two sensors decreased and the ratio approached 1. It shows that consistency of two sensors was improved. Also, the Rayleigh-corrected reflectance at 745 nm and 865 nm increased by 5.62% and 9.52%, respectively. This alteration had implications for the ratio of Rayleigh-corrected reflectance at these wavelengths, potentially impacting the atmospheric correction results across all spectral bands, particularly during the aerosol reflectance correction process within the atmospheric correction algorithm. Due to the limited overlapping operational period of GOCI and GOCI-II satellites, we only used data from March 2021. Nevertheless, we anticipate further enhancements through ongoing cross-calibration research with other satellites in the future. Additionally, it is essential to apply the vicarious calibration gain derived for the NIR band in this study to perform vicarious calibration for the visible channels and assess its impact on the accuracy of the ocean color products.
Keywords: GOCI-II, Ocean color, Vicarious calibration, Cross-calibration, Atmospheric correction
Joo-Hyung Ryu, Donguk Lee, Minju Kim
Korean J. Remote Sens. 2024; 40(5): 727-739