Contribution of the Sagres site (Portugal) to the upgrade...
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Contribution of the Sagres site (Portugal) to the upgrade and validation of the algorithms for the MERIS 4 th Reprocessing John Icely* 1, 2 , Sónia Cristina 2,3 ,Sergei Danchenko 2,3 , Bruno Fragoso 1,2,3 , Priscila Goela 2,3 , Gerald Moore 4 , Alice Newton 2,5 In collaboration with Tamito Kajiyama 2 , Carolina Sá 6 , Carolina Beltrán, Vanda Brotas 6 * E-mail: [email protected] 1 Sagremarisco Lda., Vila do Bispo, Portugal; 2 Center for Marine and Environmental Reseach (CIMA), University of Algarve, Faro, Portugal; 5 Facultad de Ciencias del Mar y Ambientales, University of Cadiz, Spain; 4 Bio-Optika, UK; 5 NILU-IMPEC, Norway; 6 MARE-Marine Sciences and Environmental Research Centre, Faculdade de Ciências, Universidade de Lisboa, Portugal. European Space Agency Living Planet Symposium, Prague, Czech Republic , 9-13 May 2016 Rationale References Data and Methods Results European Space Agency “Technical Assistance for the Validation of MERIS Marine Products at Portuguese and Oceanic and Coastal Sites” ESA contract number (21464/708/I-OL - CALL ID 1048228); “MERIS Validation and Algorithm 4th reprocessing – MERIS Validation Team (MVT) “ (CONTRACT NO: ARG/003-D25/1406/SAGREMARISCO) Sónia Cristina and Priscila Costa Goela are funded by PhD grants from the Portuguese FCT(SFRH/BD/78354/2011 and SFRH/BD/78356/2011, respectively); Alice Newton is funded by EU FP7 project DEVOTES (grant no. 308392), and John Icely is funded by EU FP7 AQUA-USER (grant no. 607325), and Horizon 2020 AquaSpace (grant no. 633476). Acknowledgements Remarks Standard and Regional API 1 and API 2 algorithms The matchup analysis for the Standard and Regional API 1 and API 2 algorithms shows: for API1 a tendency for overestimation of MER API1 and MLP(R rs MER ) and MLP(R rs SITU ) with respect to TChla REF ; for API2 a tendency for underestimation of the MER API2 and slightly overestimation of the regional products with respect to TChla REF ABS and TChla REF HPLC ; an increased accuracy of the regional data product with respect to standard deliverables for API1 and API 2; a wide applicability range of the regional algorithm for API1 and API2 along the Portuguese coast; The inter-comparison analysis of pigment concentration measurements proposed was successfully conducted. Results are encouraging, but there is space for improvement, namely: SGM : consider the inclusion of internal standard and an extended period for acetone extraction; FCUL : test extraction with acetone and consider measuring standard mixes in between samples. A new HPLC has now been set up, limits of detection and quantification have to be evaluated and compared to the old instrument. The match-up analysis from Sagres for the MERIS sensor provides a useful resource for the validation of products from the Ocean Land Colour Instrument on the recently launched Sentinel-3A satellite. y = 0.6899x + 0.3903 R² = 0.93064 y = 0.4369x + 0.6013 R² = 0.81444 0 1 2 3 4 5 6 7 8 0 2 4 6 8 10 Chl a (ug/L) Chla DHI (ug/L) Field samples TChl a SGM FCUL Linear (SGM) Linear (FCUL) y = 0.7287x + 0.2033 R² = 0.81738 0 1 2 3 4 5 6 7 0 1 2 3 4 5 6 7 8 FCUL Chla (ug/L) SGM Chla (ug/L) Field samples TChl a Sagres data has been used to produce a regional total chlorophyll a product (TChla) using an inversion scheme based on Multi-Layer Perceptron (MLP) neural nets, where the regional results are expressed as MLP(R rs SITU ) and MLP(R rs MER ), and where the quantities in parentheses indicate MLP inputs from the Medium Resolution Imaging Spectrometer (MERIS) and in situ remote sensing reflectance (R rs ). Additionally, an inter-comparison has been implemented for the determination of algal pigments by High Pressure Liquid Chromatography (HPLC) to guarantee consistency and comparability of Chla databases for validation of satellite products for the Portuguese coast at two laboratories involved in ocean colour validation activities in Portugal. The overall aim has been to: quantify single laboratory uncertainties; quantify differences between the two laboratories, considering both HPLC methods and extraction procedures. Further sampling has continued at Sagres since 2012 to validate the bio-optical models for the MERIS 4th reprocessing, with focus on the applicability of the OC4Me algorithm for Sagres waters [2]. Recent and historical (data set collected between 2008 and 2012 [3]) in situ data will be reprocessed as soon as the MERIS 4 th reprocessing protocol is available to update the bio-optical characterization of Portuguese waters at the Sagres site. Most of the historical data has now been published in peer reviewed journals [1,4-6]. Reference Quantities Tested Quantaties Algal Pigment Index 1 (API 1) in situ TChla (TChla REF ) MERIS Standard API1 (MER API1 ) Regional MLPs MLP(R rs MER ) MLP(R rs SITU ) [TChla] = [MVChla] + [DVChla] + [Chlidea] + [Pheopba] + [Pheopta] Determined by High-Performance Liquid Chromatography (HPLC) using methodology from [7]. Determined through a polynomial regression based on multiple band ratios of MERIS normalized water-leaving reflectances (ρ w ) [8]. Computed using inversion schemes based on Multi-Layer Perceptron (MLP) neural nets. The applicability range of the regional algorithm was evaluated through a novel detection scheme [9]. Different sets of center wavelengths (413, 443, 490, 510, 560 and 665 nm) were tested to derive the regional TChla concentrations from space derived values for R rs . Algal Pigment Index 2 (API 2) in situ TChla (TChla REF HPLC ) MERIS Standard API2 (MER API2 ) Regional MLPs MLP(R rs MER ) MLP(R rs SITU ) [TChla] = [MVChla] + [DVChla] + [Chlidea] + [Pheopba] + [Pheopta] Determined by High-Performance Liquid Chromatography (HPLC) using methodology from [7]. This standard product is estimated with two neural nets NN. The first NN computes bottom-of-the-atmosphere (BOA) R rs values by removing the atmospheric radiometric contribution. The second NN utilizes the BOA R rs to derive the coefficient of absorption of phytoplankton pigments at 442 nm (a ph (442)). The final API2 product is then computed as: MER API2 = A.a ph (442) B ; using the same regression coefficients as the in situ a ph. The regional MLP for retrieving the data product equivalent to API2 has been trained with the in situ data collected at the Sagres site (instructions for independent implementation by users are provided as supplemental material http://ocportugal.org/sites/default/files/api2Sg r.pdf). In both cases, R rs at 490, 510 and 560 nm were selected as input channels, in agreement with the reference study [5, 6]. in situ a ph (TChla REF ABS ) The API2 in situ equivalent algal pigment index, TChla REF ABS , was estimated, converting a ph (442) into API2. API2=A.a ph (442) B ; with power-law regression coefficients A=21.0 and B=1.04 derived from field measurements in the German Bight and Norwegian waters [10]. More details about the determination are in [11]. Matchup Analysis: Radiometric measurements and water samples: collected between 2008 and 2012 (Stations A, B and C) off Sagres (Fig. 1); Standard API1 and API 2 data: delivered by MERIS orbiting sensor (Table 1); Equivalent quantities: regional inversion scheme using as input both MERIS and in situ R rs values (respectively R rs MER and R rs SITU , Table 1). Extraction procedure: MERIS Level 2 products and the criteria for the matchup selection are the same as those presented in [5]. Table 1. Reference and tested quantities used in this study. Fig. 2. Comparison between standard MER API1 and equivalent products computed with regional algorithms: (a) MLP(R rs MER ); (b) MLP(R rs SITU ); (c) with the TChla REF ( red, green and blue dots represent Stations A, B and C, respectively). There is an overestimation of the MER API1 , MLP(R rs MER ) and MLP(R rs SITU ) with respect to TChla REF (Fig. 2). Tested products are less accurate at Station A near the coast, whereas improve in Stations B and C. Possible causes for the reduced quality of data products at Station A: MER API1 and MLP(R rs MER ): adjacency effects and limits of the aerosol models, Fig. 2(a-b); MLP( R rs SITU ): increased complexity of seawater optical properties, Fig. 2(c); Fig. 4. Region of applicability of the MLP(R rs MER ) for API1 and API2. (a) (b) (c) There is an underestimation of the MER API2 (especially at higher concentrations) Fig. 3(a,d) and slightly overestimation of the regional products Fig. 3(b,c,e,f) with respect to TChla REF ABS and TChla REF HPLC . In general, the matchup analysis with TChla revealed higher uncertainties for MER API2 , MLP(R rs MER ) and MLP(R rs SITU ), as detailed in Fig. 3 (d-f). The best agreement between data sets was obtained with MLP(R rs SITU ) with respect to TChla REF ABS and TChla REF HPLC Fig. 3 (c-f). Novelty Index Applicability Range The green shading is where most of the R rs spectra are within the MLP(R rs MER ) applicability range–cf. Fig. 4. The regional MLP developed for retrieving the API1 and API2 show good applicability in the Atlantic off the Iberian Peninsula. Matchup Analysis Fig. 3. Comparison between MERIS API2 and results obtained by applying the regional MLP for the Sagres region (red, green and blue dots represent Stations A, B and C, respectively). Novelty Index Applicability Range: A novelty detection scheme [9,12] was used to verify the regional MLP algorithms for API1 and API2 applicability range. The adopted applicability range is based on a novelty index η presented in published works [6, 9]. Intercalibration Exercise Data and Methods Results Inter-comparison between the HPLC methods used by Sagremarisco (SGM) and MARE (FCUL) Laboratories was conducted to guarantee consistency and comparability of Chla databases. 12 batches of samples were collected at three different locations (Fig.5). In addition, two different mixtures of standard pigments were analyzed in each laboratory. Table 3. Summarized results for the intercalibration exercise. Mixture of Standards Natural Samples Precision Accuracy Precision Accuracy Coefficient of variation <3% for all the analysed pigments for DHI and SGM. For FCUL, coefficient of variation <3% for higher concentration mixture, higher uncertainties (<20%) for lower concentration mix. Considering equally the laboratories for the reference: Absolute Percent Difference (APD) <9 % for DHI, on average across all pigments. APD for SGM and FCUL ~10% higher on average than DHI Considering the DHI measurements as reference: FCUL presented better results on average (APD <19%); SGM had higher differences: although presenting APD<16% for Tchla, the APD across all samples was ~36%, mainly due to discrepancies in TChlc, Car and diadinox. Coefficients of variation reaching a maximum of 15% for all pigments and methods (except for Diatox, Perid., and Zeax. for the FCUL method.) Considering equally the laboratories for the reference: APD between 8 and 19%, with average similar values for both sized filters for DHI and FCUL, with SGM having better results for the larger sized filters. Considering the DHI measurements as reference: APD >25% for both SGM and FCUL. Laboratory HPLC Method Stationary phase Column Detector and Monitoring WL P s L c D c T c Manufacturer and model WL (nm) FCUL Zapata et al. (2000) C8 3.5 150 4.6 25 Shimadzu SPD- M10A VP-DAD 430, 448, 454 SGM Wright & Jeffrey (1997) C18 3 150 4.6 25 Agilent 1200 436, 450 DHI Van Heukelem & Thomas (2001) C8 3.5 150 4.6 60 Shimadzu SPD- M10A VP-DAD 222*, 450, and 665 Differences retrieved for SGM and FCUL, considering only TChl a: An underestimation was observed for both methods compared to DHI (slightly more accentuated for FCUL with higher Chl concentrations) (Fig.6). Fig. 6. Linear correlation analysis for TChl a determined by DHI, SGM and FCUL (left) and SGM and FCUL (right). Fig. 5. Geographic location where the samples were collected. [1] Goela, P.C., Icely, J., Cristina, S., Newton, A., Moore, G., Cordeiro, C., 2013. Specific absorption coefficient of phytoplankton off the Southwest coast of the Iberian Peninsula: A contribution to algorithm development for ocean colour remote sensing. Continental Shelf Research, v. 52, pp. 119-132. DOI: 10.1016/j.csr.2012.11.009 ISSN: 0278-4343 [2] https://earth.eo.esa.int/ocs/envisat/meris/documentation [3] Icely, J., Cristina, S., Goela, P., Moore, G., Danchenko, S., Zacarias, M., Newton, A., 2013. Summary of the project outputs between 2008-2012 for Technical Assistance for the Validation of MERIS Marine Products at Portuguese Oceanic and Coastal Site. Final Report, Annex A 81 pp., Data - Tables 102 pp., Annex B - Dissemination and Education 6pp. and copies of posters & publications. [4] Goela, P.C., Danchenko,S. Icely, J., Lubian, L.M., Cristina, S., Newton, A., 2014. Using CHEMTAX to evaluate seasonal and interannual dynamics of the phytoplankton community off the South-west coast of Portugal. Estuarine, Coastal and Shelf Science, v. 151, pp. 112-123. DOI: 10.1016/j.ecss.2014.10.001 ISSN: 0272-7714 [5] Cristina, S., Moore, G. F., Goela, P.R.F.C., Icely, J.D., Newton, A., 2014. In situ validation of MERIS marine reflectance off the southwest Iberian Peninsula: assessment of vicarious adjustment and corrections for near-land adjacency. International Journal of Remote Sensing, 35(6), 2347-2377. [6] Cristina, S., D'Alimonte, D., Goela, P.G., Kakiyama, T., Icely, J., Moore, G., Fragoso, B.D.D., Newton, A., 2016. Standard and Regional Bio-optical Algorithms for Chlorophyll a Estimates in the Atlantic off the Southwestern Iberian Peninsula. Geoscience and Remote Sensing Letters, IEEE, DOI: 10.1109/LGRS.2016.2529182. [7] Wright S., Jeffrey, S. 1997. Phytoplankton Pigments in Oceanography. UNESCO, Paris, ch. High-resolution hplc system for chlorophylls and carotenoids of marine phytoplankton, . 327–341. [8] Morel ,A., Antoine, D. 2007. Pigment index retrieval in case 1 waters. Laboratoire d’Océanographie de Villefranche, Algorithm Theoretical Basis Document PO-TN-MEL-GS-0005. [9 ]D’Alimonte, D.,Zibordi, G., Kajiyama, T., Berthon, J.-F. 2014. Comparison between MERIS and regional high-level products in European seas. Remote Sensing of Environment, vol. 140, 378 – 395. [10] Doerffer R., Schiller, H. 2007. The MERIS Case 2 water algorithm. International Journal of Remote Sensing, 28, 3-4, 517–535. [11] Goela, P.G., D'Alimonte, D., Cristina, S., Kakiyama, T., Icely, J., Moore, G., Fragoso, B. and Newton, A., 2016. Algal Pigment Index 2 in the Atlantic off the Southwest Iberian Peninsula: comparison of standard and regional algorithms, Ocean Science (in prep). [12] Bishop, C. M.1994. Novelty Detection and Neural Network Validation. IEE Proc. Vision and Image & Sig. Proc.,141, 217–222. Table 2. HPLC Methods used in the intercalibration exercise. Figure 1. Sagres study site with sampling stations A, B and C , source: [1].
Transcript of Contribution of the Sagres site (Portugal) to the upgrade...
Contribution of the Sagres site (Portugal) to the upgrade and validation of the algorithms for the MERIS 4th Reprocessing John Icely*1, 2, Sónia Cristina2,3,Sergei Danchenko2,3, Bruno Fragoso1,2,3 , Priscila Goela2,3, Gerald Moore4 , Alice Newton2,5
In collaboration with Tamito Kajiyama2, Carolina Sá6, Carolina Beltrán, Vanda Brotas6
*E-mail: [email protected]
1Sagremarisco Lda., Vila do Bispo, Portugal; 2Center for Marine and Environmental Reseach (CIMA), University of Algarve, Faro, Portugal; 5Facultad de Ciencias del Mar y Ambientales,University of Cadiz, Spain; 4Bio-Optika, UK; 5NILU-IMPEC, Norway; 6MARE-Marine Sciences and Environmental Research Centre, Faculdade de Ciências, Universidade de Lisboa, Portugal.
European Space Agency Living Planet Symposium, Prague, Czech Republic , 9-13 May 2016
Rationale
References
Data and Methods Results
European Space Agency “Technical Assistance for the Validation of MERIS Marine Products at Portuguese and Oceanic and Coastal Sites” ESA contract number (21464/708/I-OL - CALL ID 1048228); “MERIS Validation and Algorithm 4th reprocessing – MERIS Validation Team (MVT) “ (CONTRACT NO: ARG/003-D25/1406/SAGREMARISCO)Sónia Cristina and Priscila Costa Goela are funded by PhD grants from the Portuguese FCT(SFRH/BD/78354/2011 and SFRH/BD/78356/2011, respectively); Alice Newton is funded by EU FP7 project DEVOTES (grant no. 308392), and John Icely is funded by EU FP7 AQUA-USER (grant no. 607325), and Horizon 2020 AquaSpace (grant no. 633476).
Acknowledgements
Rem
ark
s
Standard and Regional API 1 and API 2 algorithms
The matchup analysis for the Standard and Regional API 1 and API 2 algorithms shows:for API1 a tendency for overestimation of MERAPI1 and MLP(Rrs
MER) and MLP(RrsSITU) with respect to TChlaREF;
for API2 a tendency for underestimation of the MERAPI2 and slightly overestimation of the regional products with respect to TChlaREFABS and TChlaREF
HPLC;an increased accuracy of the regional data product with respect to standard deliverables for API1 and API 2;a wide applicability range of the regional algorithm for API1 and API2 along the Portuguese coast;
The inter-comparison analysis of pigment concentration measurements proposed was successfully conducted. Results are encouraging, but there is space forimprovement, namely:
SGM: consider the inclusion of internal standard and an extended period for acetone extraction;FCUL: test extraction with acetone and consider measuring standard mixes in between samples. A new HPLC has now been set up, limits of detection and
quantification have to be evaluated and compared to the old instrument.
The match-up analysis from Sagres for the MERIS sensor provides a useful resource for the validation of products from theOcean Land Colour Instrument on the recently launched Sentinel-3A satellite.
y=0.6899x+0.3903R²=0.93064
y=0.4369x+0.6013R²=0.814440
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2
3
4
5
6
7
8
0 2 4 6 8 10
Chla(ug/L)
ChlaDHI(ug/L)
FieldsamplesTChla
SGM
FCUL
Linear(SGM)
Linear(FCUL)
y=0.7287x+0.2033R²=0.81738
0
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2
3
4
5
6
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0 1 2 3 4 5 6 7 8
FCULChla(ug/L)
SGMChla(ug/L)
FieldsamplesTChla
Sagres data has been used to produce a regional total chlorophyll a product (TChla) using an inversion scheme based on Multi-Layer Perceptron(MLP) neural nets, where the regional results are expressed as MLP(Rrs
SITU) and MLP(RrsMER), and where the quantities in parentheses indicate MLP
inputs from the Medium Resolution Imaging Spectrometer (MERIS) and in situ remote sensing reflectance (Rrs). Additionally, an inter-comparison hasbeen implemented for the determination of algal pigments by High Pressure Liquid Chromatography (HPLC) to guarantee consistency andcomparability of Chla databases for validation of satellite products for the Portuguese coast at two laboratories involved in ocean colour validationactivities in Portugal. The overall aim has been to: quantify single laboratory uncertainties; quantify differences between the two laboratories,considering both HPLC methods and extraction procedures.Further sampling has continued at Sagres since 2012 to validate the bio-optical models for the MERIS 4th reprocessing, with focus on the applicabilityof the OC4Me algorithm for Sagres waters [2]. Recent and historical (data set collected between 2008 and 2012 [3]) in situ data will be reprocessed assoon as the MERIS 4th reprocessing protocol is available to update the bio-optical characterization of Portuguese waters at the Sagres site. Most of thehistorical data has now been published in peer reviewed journals [1,4-6].
Reference Quantities Tested Quantaties
Algal Pigment Index 1 (API 1)
in situ TChla (TChlaREF) MERIS Standard API1 (MERAPI1)Regional MLPs
MLP(RrsMER) MLP(Rrs
SITU)
[TChla] = [MVChla] + [DVChla] +[Chlidea] + [Pheopba] + [Pheopta]Determined by High-PerformanceLiquid Chromatography (HPLC) usingmethodology from [7].
Determined through a polynomialregression based on multipleband ratios of MERIS normalizedwater-leaving reflectances (ρw) [8].
Computed using inversion schemes based onMulti-Layer Perceptron (MLP) neural nets. Theapplicability range of the regional algorithm wasevaluated through a novel detection scheme[9]. Different sets of center wavelengths (413,443, 490, 510, 560 and 665 nm) were tested toderive the regional TChla concentrations fromspace derived values for Rrs.
Algal Pigment Index 2 (API 2)
in situ TChla (TChlaREFHPLC) MERIS Standard API2 (MERAPI2)
Regional MLPs
MLP(RrsMER) MLP(Rrs
SITU)
[TChla] = [MVChla] + [DVChla] +[Chlidea] + [Pheopba] + [Pheopta]Determined by High-PerformanceLiquid Chromatography (HPLC) usingmethodology from [7]. This standard product is estimated with two
neural nets NN. The first NN computesbottom-of-the-atmosphere (BOA) Rrs valuesby removing the atmospheric radiometriccontribution. The second NN utilizes theBOA Rrs to derive the coefficient ofabsorption of phytoplankton pigments at442 nm (aph(442)). The final API2 product isthen computed as:
MERAPI2 = A.aph(442)B; using the same regression coefficients asthe in situ aph.
The regional MLP for retrieving the dataproduct equivalent to API2 has been trainedwith the in situ data collected at the Sagres site(instructions for independent implementationby users are provided as supplemental materialhttp://ocportugal.org/sites/default/files/api2Sgr.pdf).In both cases, Rrs at 490, 510 and 560 nm wereselected as input channels, in agreement withthe reference study [5, 6].
in situ aph (TChlaREFABS)
The API2 in situ equivalent algalpigment index, TChlaREF
ABS, wasestimated, converting aph(442) intoAPI2.
API2=A.aph(442)B; with power-law regressioncoefficients A=21.0 and B=1.04derived from field measurements inthe German Bight and Norwegianwaters [10]. More details about thedetermination are in [11].
Matchup Analysis:Radiometric measurements and water samples: collected between 2008 and
2012 (Stations A, B and C) off Sagres (Fig. 1);Standard API1 and API 2 data: delivered by MERIS orbiting sensor (Table 1);Equivalent quantities: regional inversion scheme using as input both MERIS and
in situ Rrs values (respectively RrsMER and Rrs
SITU, Table 1).Extraction procedure: MERIS Level 2 products and the criteria for the matchup
selection are the same as those presented in [5].
Table 1. Reference and tested quantities used in this study. Fig. 2. Comparison between standard MERAPI1 and equivalent productscomputed with regional algorithms: (a) MLP(Rrs
MER); (b) MLP(RrsSITU); (c) with the
TChlaREF (red, green and blue dots represent Stations A, B and C, respectively).
There is an overestimation of the MERAPI1,MLP(Rrs
MER) and MLP(RrsSITU) with respect to
TChlaREF (Fig. 2). Tested products are lessaccurate at Station A near the coast,whereas improve in Stations B and C.
Possible causes for the reduced quality ofdata products at Station A:
MERAPI1 and MLP(RrsMER): adjacency effects
and limits of the aerosol models, Fig. 2(a-b);MLP(Rrs
SITU): increased complexity ofseawater optical properties, Fig. 2(c);
Fig. 4. Region of applicability of the MLP(RrsMER) for API1 and API2.
(a) (b) (c)There is an underestimation of the
MERAPI2 (especially at higher concentrations)Fig. 3(a,d) and slightly overestimation ofthe regional products Fig. 3(b,c,e,f) withrespect to TChlaREF
ABS and TChlaREFHPLC.
In general, the matchup analysis withTChla revealed higher uncertainties forMERAPI2, MLP(Rrs
MER) and MLP(RrsSITU), as
detailed in Fig. 3 (d-f).
The best agreement between data setswas obtained with MLP(Rrs
SITU) with respectto TChlaREF
ABS and TChlaREFHPLC Fig. 3 (c-f).
Novelty Index Applicability Range
The green shading is where most of the Rrs spectra arewithin the MLP(Rrs
MER) applicability range–cf. Fig. 4.
The regional MLP developed for retrieving the API1 andAPI2 show good applicability in the Atlantic off theIberian Peninsula.
Matchup Analysis
Fig. 3. Comparison between MERISAPI2 and results obtained by applying theregional MLP for the Sagres region (red, green and blue dots representStations A, B and C, respectively).
Novelty Index Applicability Range:A novelty detection scheme [9,12] was used to verify the regional MLP
algorithms for API1 and API2 applicability range. The adopted applicability rangeis based on a novelty index η presented in published works [6, 9].
Intercalibration ExerciseData and Methods Results
Inter-comparison between theHPLC methods used by Sagremarisco(SGM) and MARE (FCUL) Laboratorieswas conducted to guaranteeconsistency and comparability ofChla databases.
12 batches of samples werecollected at three different locations(Fig.5). In addition, two differentmixtures of standard pigments wereanalyzed in each laboratory.
Table 3. Summarized results for the intercalibration exercise.
Mixture of Standards Natural SamplesPrecision Accuracy Precision Accuracy
Coefficient of variation <3% for all the analysed pigments for DHI and SGM.
For FCUL, coefficient of variation <3% for higher concentration mixture, higher uncertainties (<20%) for lower concentration mix.
Considering equally the laboratories for the
reference: Absolute Percent Difference (APD) <9 % for DHI,
on average across all pigments. APD for SGM and FCUL ~10% higher on average
than DHI
Considering the DHI measurements as reference:
FCUL presented better results on average (APD<19%); SGM had higher differences: althoughpresenting APD<16% for Tchla, the APD across allsamples was ~36%, mainly due to discrepancies inTChlc, Car and diadinox.
Coefficients of variation reaching a maximum of
15% for all pigments and methods (except for
Diatox, Perid., and Zeax. for the FCUL method.)
Considering equally the laboratories for the reference:
APD between 8 and 19%, with average similar values for both
sized filters for DHI and FCUL, with SGM having better results
for the larger sized filters.
Considering the DHI measurements as reference:
APD >25% for both SGM and FCUL.
Laboratory HPLC MethodStationary
phase
Column Detector and Monitoring WL
Ps Lc Dc Tc
Manufacturer and model
WL (nm)
FCUL Zapata et al. (2000) C8 3.5 150 4.6 25Shimadzu SPD-M10A VP-DAD
430, 448, 454
SGMWright & Jeffrey
(1997)C18 3 150 4.6 25 Agilent 1200 436, 450
DHIVan Heukelem & Thomas (2001)
C8 3.5 150 4.6 60Shimadzu SPD-M10A VP-DAD
222*, 450, and 665
Differences retrieved for SGM and FCUL, considering only TChl a:
An underestimation was observed for both methods compared to DHI (slightly more accentuated for FCUL with higherChl concentrations) (Fig.6).
Fig. 6. Linear correlation analysis for TChl a determined by DHI, SGM and FCUL (left) and SGM and FCUL (right).
Fig. 5. Geographic location where thesamples were collected.
[1] Goela, P.C., Icely, J., Cristina, S., Newton, A., Moore, G., Cordeiro, C., 2013. Specific absorption coefficient of phytoplankton off the Southwest coast of the Iberian Peninsula: A contribution to algorithm development for ocean colour remote sensing. Continental Shelf Research, v. 52, pp. 119-132. DOI: 10.1016/j.csr.2012.11.009 ISSN: 0278-4343[2] https://earth.eo.esa.int/ocs/envisat/meris/documentation [3] Icely, J., Cristina, S., Goela, P., Moore, G., Danchenko, S., Zacarias, M., Newton, A., 2013. Summary of the project outputs between 2008-2012 for Technical Assistance for the Validation of MERIS Marine Products at Portuguese Oceanic and Coastal Site. Final Report, Annex A 81 pp., Data - Tables 102 pp., Annex B - Dissemination and Education 6pp. and copies of posters & publications. [4] Goela, P.C., Danchenko,S. Icely, J., Lubian, L.M., Cristina, S., Newton, A., 2014. Using CHEMTAX to evaluate seasonal and interannual dynamics of the phytoplankton community off the South-west coast of Portugal. Estuarine, Coastal and Shelf Science, v. 151, pp. 112-123. DOI: 10.1016/j.ecss.2014.10.001 ISSN: 0272-7714 [5] Cristina, S., Moore, G. F., Goela, P.R.F.C., Icely, J.D., Newton, A., 2014. In situ validation of MERIS marine reflectance off the southwest Iberian Peninsula: assessment of vicarious adjustment and corrections for near-land adjacency. International Journal of Remote Sensing, 35(6), 2347-2377. [6] Cristina, S., D'Alimonte, D., Goela, P.G., Kakiyama, T., Icely, J., Moore, G., Fragoso, B.D.D., Newton, A., 2016. Standard and Regional Bio-optical Algorithms for Chlorophyll a Estimates in the Atlantic off the Southwestern Iberian Peninsula. Geoscience and Remote Sensing Letters, IEEE, DOI: 10.1109/LGRS.2016.2529182.[7] Wright S., Jeffrey, S. 1997. Phytoplankton Pigments in Oceanography. UNESCO, Paris, ch. High-resolution hplc system for chlorophylls and carotenoids of marine phytoplankton, . 327–341. [8] Morel ,A., Antoine, D. 2007. Pigment index retrieval in case 1 waters. Laboratoire d’Océanographie de Villefranche, Algorithm Theoretical Basis Document PO-TN-MEL-GS-0005. [9 ]D’Alimonte, D.,Zibordi, G., Kajiyama, T., Berthon, J.-F. 2014. Comparison between MERIS and regional high-level products in European seas. Remote Sensing of Environment, vol. 140, 378 – 395. [10] Doerffer R., Schiller, H. 2007. The MERIS Case 2 water algorithm. International Journal of Remote Sensing, 28, 3-4, 517–535. [11] Goela, P.G., D'Alimonte, D., Cristina, S., Kakiyama, T., Icely, J., Moore, G., Fragoso, B. and Newton, A., 2016. Algal Pigment Index 2 in the Atlantic off the Southwest Iberian Peninsula: comparison of standard and regional algorithms, Ocean Science (in prep).[12] Bishop, C. M.1994. Novelty Detection and Neural Network Validation. IEE Proc. Vision and Image & Sig. Proc.,141, 217–222.
Table 2. HPLC Methods used in the intercalibration exercise.
Figure 1. Sagres study site with sampling stations A, B and C , source: [1].
