Multispectral and hyperspectral sensor data of the bio-optical parameters with a high spatial resolution are important for monitoring and mapping of the coastal ecosystems and estuarine areas, such as the Kneiss Islands in the Gulf of Gabes. Sentinel 2 S2A and Hyperion Earth observing-1 (EO1) imaging sensors reflectance data have been used for water quality determination and mapping of turbidity TU and chlorophyll Chl-a in shallow waters. First, we applied a tidal swing area mask based on uncorrelated pixel via 2D scatter plot between 665 nm and 865 nm to eliminate the overestimation of the concentration of water quality parameters due to the effect of the bottom reflection. The processing for mapping and validating Chl-a, Turbidity S2A, and EO1 were performed using a relation between reflectance bands and in situ measurements. Therefore, we were able to validate the performance of the case 2 regional coast colour processor (C2RCC) as well as our region-adapted empirical optical remote sensing algorithms. Turbidity was mapped based on the reflectance of 550 nm band for EO1 (R 2 = 0.63) and 665 nm band for S2A (R 2 = 0.70). Chlorophyll was mapped based on (457/528 nm) reflectance ratio (R 2 = 0.57) for EO1 and (705/665 nm) reflectance ratio (R 2 = 0.72) for the S2A.
Satellite data are effectively used in the physical characterization of some complex ecosystems, such as the estuarine system of the Kneiss Islands in the Gulf of Gabes.
Multispectral and hyperspectral remote sensing of the bio-optical parameters can be important data for mapping, classification, and monitoring of the coastal ecosystems and estuarine areas [
Several authors have analysed surface water by applying algorithms or empirical relationships between water constituent and reflectance [
Inland, coastal and estuarian shallow water area is dependent on the dynamics of sediments originated by wave erosion, tidal currents, hydrological parameters, biological and chemical constituent of water. For that this region presents a complex optical proprieties of case 2 waters, they are influenced by turbidity TU, Total suspended sediments TSS, dissolved matter, organic matter, microorganism, inorganic particulates matter from minerals [
Monitoring of water quality from remote sensing data depends on the spectral characteristic of water. So, to have the real optical properties of the water in shallow water, it is important to apply the atmospheric correction and to remove the effects of the bottom reflection.
Several atmospheric correction algorithms have been created and used for case 2 waters. ACOLITE developed to Landsat 8 OLI and S2A (MSI) in two steps: 1) A Rayleigh correction for scattering by air molecules, using a LookUp Tablegenerated using 6SV. 2) An aerosol correction based on the assumption of black SWIR bands over water caused by the extremely high pure-water absorption, and an exponential spectrum for multiple scattering aerosol reflectance [
Case 2 Regional Coast Colour processor C2RCC is developed for optically complex Case 2 waters, which use a large database of simulated water leaving radiance and TOA radiances. It is based on neural network technology and has been trained in extreme ranges of scattering and absorption properties [
Sen2cor available in the Sentinel 2 toolbox more adapted to extract L2 products and classify image often used continental area [
Polynomial based algorithm applied to MERIS POLYMER was developed for MERIS data to remove the influence of sun glint and retrieve ocean color parameters and spectrum of water leaving radiance, [
The objectives of this study are to assess the performances of both hyperspectral Hyperion data EO1 and Sentinel 2A data to retrieve Chl-a and TU validated by in situ observations of these two parameters in estuarine Kneiss archipelago.
The Kneiss Islands lie in Skhira bay in the Gulf of Gabes in the southeastern coast of Tunisia at Khaouala village. This archipelago is located about 3.5 Km off the continent with an area of about 5850 ha.
that threw itself into the sea and is remodeled by the littoral drift (according to the configuration of the coast and the direction of the prevailing winds). Sediments accumulate in this area due to the existence of the high depths of the Gulf of Gabes [
The Sentinel 2 is a wide-swath, high-resolution, multi-spectral imaging mission. Sentinel 2 multispectral imagery (MSI) data, characterized by a high spatial resolution (20 m, 10 m), 13 spectral bands, and a 12 bits radiometric resolution, appear as an appropriate tool to map and retrieve information in shallow water regions [
The Earth Observing 1 (EO1) satellite has three imaging sensors: the multispectral Advanced Land imager (ALI), the hyperspectral Hyperion sensor, and the Atmospheric Corrector (AC). ALI is a new, more compact, and slightly enhanced version of the legacy TM. The short-lived AC was a moderate resolution hyperspectral sensor. Hyperion is a hyperspectral imager capable of resolving 220 spectral bands (from 0.4 to 2.5 micron) with a 30 m ground resolution. The instrument images a 7.5 km by 100 km surface area. Since the launch of EO1 in late 2000, Hyperion is the only source of space-borne hyperspectral imaging data at a fine resolution and is used for mapping water quality in estuarine and coastal regions [
EO1/Hyperion satellite imagery of January 22, 2009 (only image available for the study area) was downloaded from NASA Website (https://earthexplorer.usgs.gov). Among the 242 bands of EO1, only 39 bands (457 µm b11 to 874 µm b52) were retained. All other bands were dropped because they either do not contain a data record or they are of poor spectral quality due to the presence of streaks.
In this study, we processed and analyzed a Sentinel 2A (S2 MSI level 1C) image acquired on May 21, 2017. The data were downloaded from the Sentinel Scientific Data Hub (https://scihub.copernicus.eu/). Sentinel application platform
(SNAP) version 6.0 on Windows (64 bits) was downloaded (https://step.esa.int/main/download/snap-download/). It is a typical architecture for all Sentinel Toolboxes and is being jointly developed by Brockmann Consult, Array Systems Computing, and C-S.
Estuarine Kneiss Islands areas falling under sub-arid climate are challenging environments for remote sensing assessments due to various land Sebkhas, soil, tidal area, shallow waters, seagrasses, slikke, schore to name a few. Water samples were collected on October 8, 2009, May 21, 2017 between 10 a.m. and 12 p.m. from the sites; turbidity TU (NTU), chlorophyll Chl-a (µg/L), and total suspended matter (TSM) (µg/L). A summary is given in
Preprocessing, processing, and validation of the in-situ data were carried out on the EO1 and S2A data.
The corrections depend on three atmospheric parameters: the ozone content, the water vapor, and the optical thickness at 550 nm. Only the first parameter was extracted from the climatology provided by 6s. The water vapor content was provided by the NOAA/NCEP-DOE (https://psl.noaa.gov/) reanalysis. The optical thickness was inferred from the Hyperion measurements at the sea of Gabes and by reversal of the 6s model. The 6SV 2.1 version was downloaded from http://6s.ltdri.org site.
| Locations | TU (NTU) min, max | TSM (µg/L) min, max | CHL-a (µg/L) min, max | Date | Number of stations |
|---|---|---|---|---|---|
| Kneiss-Skhira | 0.2, 5.5 | 0.7, 6.1 | <0.5, 4.7 | 08/10/09 | 18 |
| Kneiss islands | 2.22, 37.8 | 0.62, 2.64 | 21/05/2017 | 10 |
Based on the concept that the wavelengths are the vehicles of the information we have try to visualize all the bands and eliminates the one which presents a bad radiometric recording especially for the EO1 data or we have to keep 39 bands of the 242 available. In the second step, we applied the pretreatments and the masks; continent and shallow water to minimize the effect of the bottom reflection in certain areas. Finally, the adopted approach to TU and CHL-a product validation is by “match-up” validation, comparing the data value for all wavelengths pixel with an in situ measurement from a location within that pixel and acquired almost simultaneously. In order to make all scatter plot possible and extract a better regression between them, processing and interpretation approach are illustrated in
A false RGB (711 nm, 620 nm, and 528 nm) Color composition and continental mask of the Hyperion data cube is shown in
Four samples of different water color and depth were chosen on the image for extracting the spectral profile. Samples were taken and materialized by decreasing order of depth. Sampling 1 was located in the deepest part of the study area at tidal channels (depth of 50 cm), and sample 4 was located in shallow water (depth of 30 cm). The spectral responses of these different depths clearly show that a shallow waters mask coinciding with areas of swaying tide must be applied at the time of the satellite overpass.
In order to estimate Chl-a from EO1, we adopted the ratio between blue to green bands. This ratio is based on the in situ measurements that were made in the Gulf of Gabes [
Therefore, we accepted the blue to green ratio to extract Chl-a concentration. Rrs is the remote sensing reflectance defined by:
Rrs = L w 0 + / E d 0 +
where L w 0 + and E d 0 + are respectively the water-leaving radiance and the downward irradiance just above the sea surface. The equation is given as:
Chl-a = 0.00 5 [ Rrs457 Rrs528 ] (1)
The turbidity estimation algorithms via satellite data have often been carried out according to the types of coastal or oceanic water and to the range of turbidity [
TU = 0. 218 ( Rrs55 0 ) + 11 . 248 (2)
For a detailed mapping of Kneiss Archipelago, we used S2A sentinel data at 10 m and 20 m spatial resolution. These data were registered on the same day as that of the in situ samplings (May 21, 2017). The preprocessing was carried out by the SNAP software. We’ve tested The L2 C2RCC SNAP toolbox product, particularly, Rhow 400 - 1200 nm; (atmospherically corrected angular dependent water leaving reflectance Rhow = Rrsπ diffuse attenuation coefficients m−1), conc_tsm (total suspended matter dry concentration gm−3) and conc_chl (chlorophyll-a concentration µg/l).
In addition, we have the possibility to add additional background information such as salinity, elevation, ozone, temperature, and air pressure [
Kneiss islands are a tidal area and several regions have very shallow water for that we apply a relationship between 665 nm and 865 nm that is limited to turbidity with reflectance increasing in TU up to ~20 NTU for Rrs (645) and up to ~1000 NTU for Rrs (859) [
A visualization of all the bands and S2A C2RCC product was carried out, also we tried to test and seek the best linear relationships and regressions between the wavelengths and the in situ measurements of Chl-a. The correspondence between Chl-a and water leaving reflectance of Rrs 490, 560, 665 and 705 is plotted in
The strongest correlation was detected between Chl-a/665 nm and Chl-a/705 nm with respective R2 = 0.67 and 0.68. A ratio of S2A 490 nm to 560 nm shows a moderate correlation with in situ Chl-a and presents a coefficient of determination (R2 = 0.32). However the best regression R2 = 0.72 correspond to ratio S2A 705 nm/665 nm. Therefore, NIR/Red ratio product C2RCC was selected to map Chl-a in the submerged zone of the estuarine system. by following equation (
Chl-a = ( [ Rrs7 0 5 / Rrs665 ] − 1 . 1 0 3 ) / 0. 1 0 72 (3)
A relationship between in situ data Chl-a and Conc_chl C2RCC product as a function of the measurement station (
Linear regression coefficients were computed to search for a better channel for estimating in situ TU data Figures 11(a)-(f). The water-leaving radiance reflectance for the 665 nm band showed the best regression coefficient with the in situ TU data with an R2 value of 0.70. Similar results were reported [
TU = ( Rrs665 − 0.0 14 ) / 0.0 13 (4)
despite the overestimation of values of TU. The following empirical relation (Equation (4)) was deduced for the quantification of turbidity in the Kneiss Islands from the Sentinel 2A data (
Kneiss Islands is a very complex study environment due to morphological, hydrodynamic, and biological particularities. Mainly because of the influence of semi-diurnal type tides with amplitudes reaching up to 2 m, we used two types of high-resolution sensors (30 m, 20 m, 10 m) for studying optical properties (Chl-a) and water quality (TU). In the absence of reflectance data at sea in Tunisia, we have developed an indirect method of extracting and validating Chl-a and TU satellite data. We used the reflectance or reflectance ratios at different wavelengths and compared a reduced set of in situ data for Chl-a and TU in µg/L, and NTU is obtained concurrently to the images (18 in 2009 and 10 in 2017). The best linear regressions for the calculation and mapping of Chl-a and TU from satellite data are summarized in
Several oceanographic studies, biogeochemical, fisheries features [
| Sensor | λ (nm) | Equation CHL-a (µg/L) | Regression Coefficient (R2) | Spatial resolution |
|---|---|---|---|---|
| EO1 | 457 - 528 | Chl-a = 0.005 [ Rrs457 Rrs528 ] | 0.57 | 30 m |
| Sentinel 2 | 705 - 665 | Chl-a = ( [ Rrs705 / Rrs665 ] − 1.103 ) / 0.1072 | 0.72 | 20 m |
| Sensor | λ (nm) | Equation TU (NTU) | Regression Coefficient (R2) | Spatial resolution |
|---|---|---|---|---|
| EO1 | 550 | TU = 0.218 (Rrs550) + 11.248 | 0.63 | 30 m |
| Sentinel 2 | 665 | TU = (Rrs665 − 0.014)/0.013 | 0.70 | 20 m |
spatial resolution of 10 m and 20 m gave us the best results for the study area for a slice of water greater than 50 cm with coefficients of determination greater than 0.68 for both TU and Chl-a. Indeed, the reflection of the seabed was identified by very high values of chlorophyll concentration and turbidity. The Chl-a and TU predicted in these areas using EO1 and S2A data clearly delimit the localities where we might have doubtful results. Moreover, we developed a region of interest via 2D scatter plot between 665 nm and 865 nm bands to identify and mask the position of pixels of tidal swing area before processing to eliminate the effect of background reflections at the moment of the satellite passage.
Despite the fineness of the spectral bands of EO1 (we could use only 39 bands among the available 220 bands), the reflectance has a very low radiometric quality, especially in aquatic environments. This can explain the lower coefficients of determination for the prediction of TU and Chl-a using the EO1 (R2 = 0.57 - 0.63).
This study was funded by GEOMAG Laboratory University of Manouba in collaboration with Applied Hydrosciences Unit at the Higher Institute of Sciences and Techniques of Water of Gabès ISSTEG and PRODIG lab as part of the project on the ecosystems of the Kneiss islands and Leben basin. We thank GreenLab for their professionalism, and Sentinel2 Scientific data Hub and NASA GSFS team distribution
This work has received financial support from the LabEx DynamiTe (ANR-11-LABX-0046), as part of the “Investissements d’Avenir” program.
The authors declare no conflicts of interest regarding the publication of this paper.
Katlane, R., Dupouy, C., El Kilani, B. and Berges, J.C. (2020) Estimation of Chlorophyll and Turbidity Using Sentinel 2A and EO1 Data in Kneiss Archipelago Gulf of Gabes, Tunisia. International Journal of Geosciences, 11, 708-728. https://doi.org/10.4236/ijg.2020.1110035