Estimation of secondary phytoplankton pigments from satellite observations using Self-Organizing Maps (SOMs)

This study presents a method for estimating secondary phytoplankton pigments from satellite ocean color observations. We first compiled a large training data set composed of 12,000 samples; each sample is composed of 10 in situ phytoplankton high-performance liquid chromatography (HPLC)-measured pig...

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Main Authors: El Hourany, R., Saab, M. A. A., Faour, G., Aumont, Olivier, Crepon, M., Thiria, S.
Format: Text
Language:English
Published: 2019
Subjects:
Southern Ocean
Online Access:http://www.documentation.ird.fr/hor/fdi:010075513
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record_format openpolar
spelling ftird:oai:ird.fr:fdi:010075513 2023-05-15T18:25:54+02:00 Estimation of secondary phytoplankton pigments from satellite observations using Self-Organizing Maps (SOMs) El Hourany, R. Saab, M. A. A. Faour, G. Aumont, Olivier Crepon, M. Thiria, S. 2019 http://www.documentation.ird.fr/hor/fdi:010075513 EN eng http://www.documentation.ird.fr/hor/fdi:010075513 oai:ird.fr:fdi:010075513 El Hourany R., Saab M. A. A., Faour G., Aumont Olivier, Crepon M., Thiria S. Estimation of secondary phytoplankton pigments from satellite observations using Self-Organizing Maps (SOMs). Journal of Geophysical Research : Oceans, 2019, 124 (2), p. 1357-1378. text 2019 ftird 2020-08-21T06:48:56Z This study presents a method for estimating secondary phytoplankton pigments from satellite ocean color observations. We first compiled a large training data set composed of 12,000 samples; each sample is composed of 10 in situ phytoplankton high-performance liquid chromatography (HPLC)-measured pigment concentrations, GlobColour products of chlorophyll-a concentration, and remote sensing reflectance (Rrs()) data at different wavelengths, in addition to advanced very high resolution radiometer sea surface temperature measurements. The resulting data set regroups a large variety of encountered situations between 1997 and 2014. The nonlinear relationship between the in situ and satellite components was identified using a self-organizing map, which is a neural network classifier. As a major result, the self-organizing map enabled reliable estimations of the concentration of chlorophyll-a and of nine different pigments from satellite observations. A cross-validation procedure showed that the estimations were robust for all pigments (R-2>0.75 and an average root-mean-square error=0.016mg/m(3)). A consistent association of several phytoplankton pigments indicating phytoplankton group specific dynamic was shown at a global scale. We also showed the uncertainties for the estimation of each pigment. Plain Language Summary The knowledge of phytoplankton variability is essential to the understanding of the marine ecosystem dynamics and its response to environmental changes. This paper presents a new approach to estimate phytoplankton pigment concentrations from satellite observations by using an artificial neural network, the so-called self-organizing map. This neural network was calibrated using a large data set of in situ pigment observations from oceanic cruises along with ocean color satellite data provided by the Globcolour project and advanced very high resolution radiometer sea surface temperature. This approach allows an accurate estimation of phytoplankton pigment concentrations and their related uncertainties. Moreover, the method allows to reproduce the spatio-temporal variability of pigment concentration and the dynamics of phytoplankton groups. A particular attention is given to the Southern Ocean whose phytoplankton communities are specific. Text Southern Ocean IRD (Institute de recherche pour le développement): Horizon Southern Ocean
institution Open Polar
collection IRD (Institute de recherche pour le développement): Horizon
op_collection_id ftird
language English
description This study presents a method for estimating secondary phytoplankton pigments from satellite ocean color observations. We first compiled a large training data set composed of 12,000 samples; each sample is composed of 10 in situ phytoplankton high-performance liquid chromatography (HPLC)-measured pigment concentrations, GlobColour products of chlorophyll-a concentration, and remote sensing reflectance (Rrs()) data at different wavelengths, in addition to advanced very high resolution radiometer sea surface temperature measurements. The resulting data set regroups a large variety of encountered situations between 1997 and 2014. The nonlinear relationship between the in situ and satellite components was identified using a self-organizing map, which is a neural network classifier. As a major result, the self-organizing map enabled reliable estimations of the concentration of chlorophyll-a and of nine different pigments from satellite observations. A cross-validation procedure showed that the estimations were robust for all pigments (R-2>0.75 and an average root-mean-square error=0.016mg/m(3)). A consistent association of several phytoplankton pigments indicating phytoplankton group specific dynamic was shown at a global scale. We also showed the uncertainties for the estimation of each pigment. Plain Language Summary The knowledge of phytoplankton variability is essential to the understanding of the marine ecosystem dynamics and its response to environmental changes. This paper presents a new approach to estimate phytoplankton pigment concentrations from satellite observations by using an artificial neural network, the so-called self-organizing map. This neural network was calibrated using a large data set of in situ pigment observations from oceanic cruises along with ocean color satellite data provided by the Globcolour project and advanced very high resolution radiometer sea surface temperature. This approach allows an accurate estimation of phytoplankton pigment concentrations and their related uncertainties. Moreover, the method allows to reproduce the spatio-temporal variability of pigment concentration and the dynamics of phytoplankton groups. A particular attention is given to the Southern Ocean whose phytoplankton communities are specific.
format Text
author El Hourany, R.
Saab, M. A. A.
Faour, G.
Aumont, Olivier
Crepon, M.
Thiria, S.
spellingShingle El Hourany, R.
Saab, M. A. A.
Faour, G.
Aumont, Olivier
Crepon, M.
Thiria, S.
Estimation of secondary phytoplankton pigments from satellite observations using Self-Organizing Maps (SOMs)
author_facet El Hourany, R.
Saab, M. A. A.
Faour, G.
Aumont, Olivier
Crepon, M.
Thiria, S.
author_sort El Hourany, R.
title Estimation of secondary phytoplankton pigments from satellite observations using Self-Organizing Maps (SOMs)
title_short Estimation of secondary phytoplankton pigments from satellite observations using Self-Organizing Maps (SOMs)
title_full Estimation of secondary phytoplankton pigments from satellite observations using Self-Organizing Maps (SOMs)
title_fullStr Estimation of secondary phytoplankton pigments from satellite observations using Self-Organizing Maps (SOMs)
title_full_unstemmed Estimation of secondary phytoplankton pigments from satellite observations using Self-Organizing Maps (SOMs)
title_sort estimation of secondary phytoplankton pigments from satellite observations using self-organizing maps (soms)
publishDate 2019
url http://www.documentation.ird.fr/hor/fdi:010075513
geographic Southern Ocean
geographic_facet Southern Ocean
genre Southern Ocean
genre_facet Southern Ocean
op_relation http://www.documentation.ird.fr/hor/fdi:010075513
oai:ird.fr:fdi:010075513
El Hourany R., Saab M. A. A., Faour G., Aumont Olivier, Crepon M., Thiria S. Estimation of secondary phytoplankton pigments from satellite observations using Self-Organizing Maps (SOMs). Journal of Geophysical Research : Oceans, 2019, 124 (2), p. 1357-1378.
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