2021
DOI: 10.3390/ijgi10050313
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Mapping and Quantification of the Dwarf Eelgrass Zostera noltei Using a Random Forest Algorithm on a SPOT 7 Satellite Image

Abstract: The dwarf eelgrass Zostera noltei Hornemann (Z. noltei) is the most dominant seagrass in semi-enclosed coastal systems of the Atlantic coast of Morocco. The species is experiencing a worldwide decline and monitoring the extent of its meadows would be a useful approach to estimate the impacts of natural and anthropogenic stressors. Here, we aimed to map the Z. noltei meadows in the Merja Zerga coastal lagoon (Atlantic coast of Morocco) using remote sensing. We used a random forest algorithm combined with field … Show more

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Cited by 8 publications
(10 citation statements)
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“…Sentinel-2 data have been widely used to map different habitats and several studies have demonstrated their reliability in mapping and monitoring changes in marine biocenoses such as coral (Hedley et al 2012 ), mangrove (Pham et al 2019b , 2020 ) and seagrass beds Topouzelis et al 2016 ; Traganos and Reinartz 2018b ; Ha et al 2020 , 2021 ; Wicaksono et al 2021 ; Nur et al 2021 ; Ivajnšič et al 2022 ; Hartoni et al 2022 ). Many authors have used vegetation indices as the input for RF classification to map plant communities in terrestrial wetlands (Fletcher 2016 ) and coastal wetlands (Zoffoli et al 2020 ; Martínez Prentice et al 2021 ; Benmokhtar et al 2021 ), and compared to many machine learning algorithms and support vector machine techniques, the RF algorithm has produced promising results in terms of classifying seagrass (Zhang et al 2013 ; Traganos and Reinartz 2018b ; Ha et al 2020 ). For example, to monitor the dynamics of the Posidonia oceanica (L.) Delile meadows and Cymodocea nodosa (Ucria) Ascherson meadows in the Eastern Mediterranean, Traganos and Reinartz ( 2018a ) used the random forest algorithm and support vector machines for the RapidEye time series, after adjusting the atmospheric and analytical water column.…”
Section: Discussionmentioning
confidence: 99%
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“…Sentinel-2 data have been widely used to map different habitats and several studies have demonstrated their reliability in mapping and monitoring changes in marine biocenoses such as coral (Hedley et al 2012 ), mangrove (Pham et al 2019b , 2020 ) and seagrass beds Topouzelis et al 2016 ; Traganos and Reinartz 2018b ; Ha et al 2020 , 2021 ; Wicaksono et al 2021 ; Nur et al 2021 ; Ivajnšič et al 2022 ; Hartoni et al 2022 ). Many authors have used vegetation indices as the input for RF classification to map plant communities in terrestrial wetlands (Fletcher 2016 ) and coastal wetlands (Zoffoli et al 2020 ; Martínez Prentice et al 2021 ; Benmokhtar et al 2021 ), and compared to many machine learning algorithms and support vector machine techniques, the RF algorithm has produced promising results in terms of classifying seagrass (Zhang et al 2013 ; Traganos and Reinartz 2018b ; Ha et al 2020 ). For example, to monitor the dynamics of the Posidonia oceanica (L.) Delile meadows and Cymodocea nodosa (Ucria) Ascherson meadows in the Eastern Mediterranean, Traganos and Reinartz ( 2018a ) used the random forest algorithm and support vector machines for the RapidEye time series, after adjusting the atmospheric and analytical water column.…”
Section: Discussionmentioning
confidence: 99%
“…Quantitative information on density and biomass cannot be achieved using the classification results alone (Price et al 2022 ). The empirical relationship between field data and vegetation indices revealed by high hyperspectral or multispectral satellite imagery can provide biomass and density maps (Barillé et al 2010 ; Bargain et al 2013 ; Roelfsema et al 2014 ; Benmokhtar et al 2021 ), and the biomass of the Z. noltei beds in Merja Zerga lagoon was estimated using the quantitative experimental NDVI – Z. noltei biomass relationship created by Barillé et al ( 2010 ), whereby biomass = 610.61 (NDVI)^1.88 (n = 31, r2 = 0.97). The NDVI–biomass quantitative model applied to satellite image data is useful as a non-destructive method for estimating seagrass and microphytobenthos biomass (Zoffoli et al 2020 , 2021 ), and when we applied this method to the Sentinel-2 data, we found that Z. noltei biomass reached a maximum of 231 g DW/m² in 2020.…”
Section: Discussionmentioning
confidence: 99%
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