Atmospheric correction of geostationary satellite ocean color data under high solar zenith angles in open oceans

With a revisit time of 1 h, spatial resolution of 500 m, and high radiometric sensitivity, the Geostationary Ocean Color Imager (GOCI) is widely used to monitor diurnal dynamics of oceanic phenomena. However, atmospheric correction (AC) of GOCI data with high solar zenith angle (>70°) is still a...

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Published in:Remote Sensing of Environment
Main Authors: Li, Hao, He, Xianqiang, Bai, Yan, Shanmugam, Palanisamy, Park, Young-Je, Liu, Jia, Zhu, Qiankun, Gong, Fang, Wang, Difeng, Huang, Haiqing
Format: Report
Language:English
Published: Elsevier Inc. 2020
Subjects:
Ocean color remote sensing
Geostationary satellite
Atmospheric correction
High solar zenith angle
Neural network
Aerosol Robotic Network
Online Access:http://ir.opt.ac.cn/handle/181661/93625
https://doi.org/10.1016/j.rse.2020.112022
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spelling ftchinacadscopt:oai:ir.opt.ac.cn:181661/93625 2023-05-15T13:07:01+02:00 Atmospheric correction of geostationary satellite ocean color data under high solar zenith angles in open oceans Li, Hao He, Xianqiang Bai, Yan Shanmugam, Palanisamy Park, Young-Je Liu, Jia Zhu, Qiankun Gong, Fang Wang, Difeng Huang, Haiqing 2020-11 http://ir.opt.ac.cn/handle/181661/93625 https://doi.org/10.1016/j.rse.2020.112022 英语 eng Elsevier Inc. Remote Sensing of Environment http://ir.opt.ac.cn/handle/181661/93625 doi:10.1016/j.rse.2020.112022 cn.org.cspace.api.content.CopyrightPolicy@99be3 Ocean color remote sensing Geostationary satellite Atmospheric correction High solar zenith angle Neural network 期刊论文 2020 ftchinacadscopt https://doi.org/10.1016/j.rse.2020.112022 2020-10-30T01:04:48Z With a revisit time of 1 h, spatial resolution of 500 m, and high radiometric sensitivity, the Geostationary Ocean Color Imager (GOCI) is widely used to monitor diurnal dynamics of oceanic phenomena. However, atmospheric correction (AC) of GOCI data with high solar zenith angle (>70°) is still a challenge for traditional algorithms. Here, we propose a novel neural network (NN) AC algorithm for GOCI data under high solar zenith angles. Unlike traditional NN AC algorithms trained by radiative transfer-simulated dataset, our new AC algorithm was trained by a large number of matchups between GOCI-observed Rayleigh-corrected radiance in the morning and evening and GOCI-retrieved high-quality noontime remote-sensing reflectance (Rrs). When validated using hourly GOCI data, the new NN AC algorithm yielded diurnally stable Rrs in open ocean waters from the morning to evening. Furthermore, when validated by in-situ data from three Aerosol Robotic Network-Ocean Color (AERONET-OC) stations (Socheongcho, Gageocho and Ieodo), the GOCI-retrieved Rrs at visible bands obtained using the new AC algorithm agreed well with the in-situ values, even under high solar zenith angles. Practical application of the new algorithm was further examined using diurnal GOCI observation data acquired in clear open ocean waters. Results showed that the new algorithm successfully retrieved Rrs for the morning and evening GOCI data. Moreover, the amount of Rrs data retrieved by the new algorithm was much higher than that retrieved by the standard AC algorithm in SeaDAS. Our proposed NN AC algorithm can not only be applied to process GOCI data acquired in the morning and evening, but also has the potential to be applied to process polar-orbiting satellite ocean color data at high-latitude ocean that also include satellite observation with high solar zenith angles. © 2020 Elsevier Inc. Report Aerosol Robotic Network Xi'an Institute of Optics and Precision Mechanics: OPT OpenIR (Chinese Academy of Sciences, CAS) Remote Sensing of Environment 249 112022
institution Open Polar
collection Xi'an Institute of Optics and Precision Mechanics: OPT OpenIR (Chinese Academy of Sciences, CAS)
op_collection_id ftchinacadscopt
language English
topic Ocean color remote sensing
Geostationary satellite
Atmospheric correction
High solar zenith angle
Neural network
spellingShingle Ocean color remote sensing
Geostationary satellite
Atmospheric correction
High solar zenith angle
Neural network
Li, Hao
He, Xianqiang
Bai, Yan
Shanmugam, Palanisamy
Park, Young-Je
Liu, Jia
Zhu, Qiankun
Gong, Fang
Wang, Difeng
Huang, Haiqing
Atmospheric correction of geostationary satellite ocean color data under high solar zenith angles in open oceans
topic_facet Ocean color remote sensing
Geostationary satellite
Atmospheric correction
High solar zenith angle
Neural network
description With a revisit time of 1 h, spatial resolution of 500 m, and high radiometric sensitivity, the Geostationary Ocean Color Imager (GOCI) is widely used to monitor diurnal dynamics of oceanic phenomena. However, atmospheric correction (AC) of GOCI data with high solar zenith angle (>70°) is still a challenge for traditional algorithms. Here, we propose a novel neural network (NN) AC algorithm for GOCI data under high solar zenith angles. Unlike traditional NN AC algorithms trained by radiative transfer-simulated dataset, our new AC algorithm was trained by a large number of matchups between GOCI-observed Rayleigh-corrected radiance in the morning and evening and GOCI-retrieved high-quality noontime remote-sensing reflectance (Rrs). When validated using hourly GOCI data, the new NN AC algorithm yielded diurnally stable Rrs in open ocean waters from the morning to evening. Furthermore, when validated by in-situ data from three Aerosol Robotic Network-Ocean Color (AERONET-OC) stations (Socheongcho, Gageocho and Ieodo), the GOCI-retrieved Rrs at visible bands obtained using the new AC algorithm agreed well with the in-situ values, even under high solar zenith angles. Practical application of the new algorithm was further examined using diurnal GOCI observation data acquired in clear open ocean waters. Results showed that the new algorithm successfully retrieved Rrs for the morning and evening GOCI data. Moreover, the amount of Rrs data retrieved by the new algorithm was much higher than that retrieved by the standard AC algorithm in SeaDAS. Our proposed NN AC algorithm can not only be applied to process GOCI data acquired in the morning and evening, but also has the potential to be applied to process polar-orbiting satellite ocean color data at high-latitude ocean that also include satellite observation with high solar zenith angles. © 2020 Elsevier Inc.
format Report
author Li, Hao
He, Xianqiang
Bai, Yan
Shanmugam, Palanisamy
Park, Young-Je
Liu, Jia
Zhu, Qiankun
Gong, Fang
Wang, Difeng
Huang, Haiqing
author_facet Li, Hao
He, Xianqiang
Bai, Yan
Shanmugam, Palanisamy
Park, Young-Je
Liu, Jia
Zhu, Qiankun
Gong, Fang
Wang, Difeng
Huang, Haiqing
author_sort Li, Hao
title Atmospheric correction of geostationary satellite ocean color data under high solar zenith angles in open oceans
title_short Atmospheric correction of geostationary satellite ocean color data under high solar zenith angles in open oceans
title_full Atmospheric correction of geostationary satellite ocean color data under high solar zenith angles in open oceans
title_fullStr Atmospheric correction of geostationary satellite ocean color data under high solar zenith angles in open oceans
title_full_unstemmed Atmospheric correction of geostationary satellite ocean color data under high solar zenith angles in open oceans
title_sort atmospheric correction of geostationary satellite ocean color data under high solar zenith angles in open oceans
publisher Elsevier Inc.
publishDate 2020
url http://ir.opt.ac.cn/handle/181661/93625
https://doi.org/10.1016/j.rse.2020.112022
genre Aerosol Robotic Network
genre_facet Aerosol Robotic Network
op_relation Remote Sensing of Environment
http://ir.opt.ac.cn/handle/181661/93625
doi:10.1016/j.rse.2020.112022
op_rights cn.org.cspace.api.content.CopyrightPolicy@99be3
op_doi https://doi.org/10.1016/j.rse.2020.112022
container_title Remote Sensing of Environment
container_volume 249
container_start_page 112022
_version_ 1766031242335092736

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