Evaluation of Atmospheric Correction Algorithms for Sentinel-2-MSI and Sentinel-3-OLCI in Highly Turbid Estuarine Waters

Renosh, Pannimpullath Remanan; Doxaran, David; Keukelaere, Liesbeth De; Gossn, Juan Ignacio

doi:10.3390/rs12081285

Cited by 68 publications

(32 citation statements)

References 73 publications

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“…Atmospheric correction in case-2 waters has not been solved yet. As a result, huge efforts have been made to develop atmospheric correction processors, covering a wide range of different methods [11][12][13]. However, the performance of the processors may differ depending on the scenario (sun and observation geometry, atmospheric, optical, and site-specific conditions), and there is no standardized approach yet, but atmospheric correction processors keep evolving as new approaches and more data become available.…”

Section: Introductionmentioning

confidence: 99%

Towards the Combination of C2RCC Processors for Improving Water Quality Retrieval in Inland and Coastal Areas

et al. 2022

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Sentinel-2 offers great potential for monitoring water quality in inland and coastal waters. However, atmospheric correction in these waters is challenging, and there is no standardized approach yet, but different methods coexist under constant development. The atmospheric correction Case 2 Regional Coast Colour (C2RCC) processor has been recently updated with the C2X-COMPLEX (C2XC). This study is one of the first attempts at exploring its performance, in comparison with C2RCC and C2X, in inland and coastal waters in the east of the Iberian Peninsula, in retrieving water surface reflectance and estimating chlorophyll-a ([Chl-a]), total suspended matter ([TSM]), and Secchi disk depth (ZSD). The relationship between in situ ZSD and Kd_z90max product (i.e., the depth of the water column from which 90% of the water-leaving irradiance is derived) of the C2RCC processors demonstrated the potential of this product for estimating water clarity (r > 0.75). However, [TSM] and [Chl-a] derived from the different processors with default calibration factors were not suitable within the targeted scenarios, requiring recalibration based on optical water types or a shift to dynamic algorithm blending approaches. This would benefit from switching between C2RCC and C2XC, which extends the potential for improving surface reflectance estimates to a wide range of scenarios and suggests a promising future for C2-Nets in operational monitoring of water quality.

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Section: Introductionmentioning

confidence: 99%

Towards the Combination of C2RCC Processors for Improving Water Quality Retrieval in Inland and Coastal Areas

et al. 2022

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“…This is linked to errors in the AC aerosol type and load [7]. There is a need to extend the validation of OLCI to optically complex, extreme absorbing and scattering waters, where the retrieval of L w can be even more problematic [8]. The high absorption, low scattering waters of semi-enclosed seas, such as the Baltic, Black and Yellow Seas, Arctic Ocean and coastal regions adjacent to the largest rivers such as the Amazon, are some of the most challenging regions to obtain accurate and reliable ocean colour data.…”

Section: Introductionmentioning

confidence: 99%

Consistency between Satellite Ocean Colour Products under High Coloured Dissolved Organic Matter Absorption in the Baltic Sea

et al. 2021

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Ocean colour (OC) remote sensing is an important tool for monitoring phytoplankton in the global ocean. In optically complex waters such as the Baltic Sea, relatively efficient light absorption by substances other than phytoplankton increases product uncertainty. Sentinel-3 OLCI-A, Suomi-NPP VIIRS and MODIS-Aqua OC radiometric products were assessed using Baltic Sea in situ remote sensing reflectance (Rrs) from ferry tracks (Alg@line) and at two Aerosol Robotic Network for Ocean Colour (AERONET-OC) sites from April 2016 to September 2018. A range of atmospheric correction (AC) processors for OLCI-A were evaluated. POLYMER performed best with <23 relative % difference at 443, 490 and 560 nm compared to in situ Rrs and 28% at 665 nm, suggesting that using this AC for deriving Chl a will be the most accurate. Suomi-VIIRS and MODIS-Aqua underestimated Rrs by 35, 29, 22 and 39% and 34, 22, 17 and 33% at 442, 486, 560 and 671 nm, respectively. The consistency between different AC processors for OLCI-A and MODIS-Aqua and VIIRS products was relatively poor. Applying the POLYMER AC to OLCI-A, MODIS-Aqua and VIIRS may produce the most accurate Rrs and Chl a products and OC time series for the Baltic Sea.

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“…9). This algorithm has been already validated in several areas with optical complex waters (Caballero et al, 2018(Caballero et al, , 2019Renosh et al, 2020), as in other studies about flagellates as Lingulodinium polyedra by Caballero et al (2020). Landsat satellites do not have bands in the red-edge spectral range (700-720 nm).…”

Section: Discussionmentioning

confidence: 81%

Using Copernicus Sentinel-2 and Sentinel-3 data to monitor harmful algal blooms in Southern Chile during the COVID-19 lockdown

Rodriguez-Benito¹,

Navarro

Caballero

2020

Marine Pollution Bulletin

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During the southern summer of 2020, large phytoplankton blooms were detected using satellite technology in Chile (western Patagonia), where intensive salmonid aquaculture is carried out. Some harvesting sites recorded massive fish mortalities, which were associated with the presence of the dinoflagellate species Cochlodinium sp. The bloom included other phytoplankton species, as Lepidodinium chlorophorum, which persistently changed the colour of the ocean to green. These blooms coincided with the government-managed emergency lockdown due to the COVID-19 pandemic. Local in situ sampling was slowed down. However, imagery from the Copernicus programme allowed operational monitoring. This study shows the benefits of both Sentinel-3 and Sentinel-2 satellites in terms of their spectral, spatial and temporal capabilities for improved algal bloom monitoring. These novel tools, which can foster optimal decision-making, are available for delivering early alerts in situations of natural catastrophes and blockages, such as those occurred during the global COVID-19 lockdown.

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Evaluation of Atmospheric Correction Algorithms for Sentinel-2-MSI and Sentinel-3-OLCI in Highly Turbid Estuarine Waters

Cited by 68 publications

References 73 publications

Towards the Combination of C2RCC Processors for Improving Water Quality Retrieval in Inland and Coastal Areas

Towards the Combination of C2RCC Processors for Improving Water Quality Retrieval in Inland and Coastal Areas

Consistency between Satellite Ocean Colour Products under High Coloured Dissolved Organic Matter Absorption in the Baltic Sea

Using Copernicus Sentinel-2 and Sentinel-3 data to monitor harmful algal blooms in Southern Chile during the COVID-19 lockdown

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