Abstract
Coastal and inland waters represent a diverse set of resources that support natural habitats and provide valuable ecosystem services to the human population. Monitoring the quality of these waters is essential to maintaining the resources they provide, and long-term monitoring may offer a better understanding of the relationship between human development and the health of these resource producers. The implementation of conventional monitoring is typically time-intensive and limited in geographic scale. Alternatively, the use of airborne and spaceborne remote sensors provides a synoptic view of water quality with better spatial coverage to more accurately identify dynamic and unique parameters. Concentrations of optically active constituents (OACs) such as suspended sediments and the phytoplankton pigment chlorophylla (CHLa), act as proxies for water quality and can be detected by optical sensors. Traditional remote sensing techniques were developed using multispectral sensors, and employ band ratio algorithms that seek to predict the concentrations of OACs in relation to water quality. In complex coastal waters, overlapping spectral signatures of OACs often confound these algorithms and reduce their predictive capacity. The objective of this study was to develop a dataset to test the predictive capabilities of partial least-squares regression, a multivariate statistical method, for hyperspectral remote sensing and in situ CHLa concentrations. This paper presents the model performance for a dataset developed in Long Bay, a ~160 km arcuate bay that spans the border between North and South Carolina. The model uses multivariate-based statistical modeling to capitalize on the spectral advantage gained by hyperspectral sensors when observing such waters. Following this approach, a multivariate-based monitoring tool for the prediction of CHLa concentrations is presented with a partial least-squares regression (PLSR) method using hyperspectral and laboratory-analyzed field data. The PLSR model was used based on its ability to identify wavelengths that are more sensitive to CHLa relative to other OACs. The model was able to explain 80% of the observed CHLa variability in Long Bay with root mean square error (RMSE) = 2.03 µg/L. This enhanced mode of water quality monitoring has potential to deliver insights to point-sources and problem areas that may contribute to a decline in the water quality of valuable inland and coastal systems.
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References
Ali KA, Ortiz JD (2014) Multivariate approach for chlorophyll-a and suspended matter retrievals in Case II type waters using hyperspectral data. Hydrolog Sci J 61:200–213. doi:10.1080/02626667.2014.964242
Ali KA, Witter DL, Ortiz JD (2013) Multivariate approach to estimate colour producing agents in Case 2 waters using first-derivative spectrophotometer data. Geocarto Int 29:102–127. doi:10.1080/10106049.2012.743601
Arar EJ, Collins GB (1997) Method 445.0: in vitro determination of chlorophyll a and pheophytin a in marine and freshwater algae by fluorescence. United States Environmental Protection Agency, Washington DC, 22 p
Avery GB, Willey JD, Kieber RJ, Shank GC, Whitehead RF (2003) Flux and bioavailability of Cape Fear River. Global Biogeochem Cy 17(2):1042. doi:10.1029/2002GB001964
Carder KL, Chen FR, Cannizzaro JP, Campbell JW, Mitchell BG (2004) Performance of the MODIS semi-analytical ocean color algorithm for chlorophyll-a. Adv Space Res 33:1152–1159
Carder KL, Chen FR, Lee ZP, Hawes SK, Kamykowski D (1999) Semianalytic moderate-resolution imaging spectrometer algorithms for chlorophyll a and absorption with bio-optical domains based on nitrate-depletion temperatures. J Geophys Res 104(C3):5403–5421
Cho MA, Skidmore A, Corsi F, Wieren, SE, Sobhan I (2007) Estimation of green grass/herb biomass from airborne hyperspectral imagery using spectral indices and partial least squares regression. Int J Appl Earth Obs 9:414–424
Darecki M, Stramski AD (2004) An evaluation of MODIS and SeaWiFS bio-optical algorithms in the Baltic Sea. Remote Sens Environ 89:326–350
Dierssen HM (2010) Perspectives on empirical approaches for ocean color remote sensing of chlorophyll in a changing climate. Proc Natl Acad Sci 107(40):17073–17078
Gitelson AA, Gao B, Li R, Berdnikov S, Saprygin V (2011) Estimation of chlorophyll-a concentration in productive turbid waters using a Hyperspectral Imager for the Coastal Ocean—the Azov Sea case study. Environ Res Lett 6:024023. doi:10.1088/1748-9326/6/2/024023
Gitelson AA, Dall’Olmo G, Moses W, Rundquist DC, Barrow T, Fisher TR, Gurlin D, Holz J (2008) A simple semi-analytical model for remote estimation of chlorophyll-a in turbid waters: validation. Remote Sens Environ 112:3582–3593
Gitelson AA, Schalles JF, Hladik CM (2007) Remote chlorophylla retrieval in turbid, productive estuaries: Chesapeake Bay case study. Remote Sens Environ 109:464–472
Gitelson AA, Viña A, Ciganda V, Rundquist DC, Arkebauer TJ (2005) Remote estimation of canopy chlorophyll content in crops. Geophys Res Lett 32(8):L08403. doi:10.1029/2005GL022688
Gitelson A (1992) The peak near 700 nm on radiance spectra of algae and water: relationships of its magnitude and position with chlorophyll concentration. Int J Remote Sens 13(17):3367–3373
Gordon HR, Morel AY (1983) Remote assessment of ocean color for interpretation of satellite visible imagery: a review. Springer-Verlag, Berlin, 114 p
Gordon HR, Wang M (1994) Retrieval of water-leaving radiance and aerosol optical thickness over the oceans with SeaWiFS: a preliminary algorithm. Appl Optics 33(3):443–452
Fan C, Warner RA (2014) Characterization of water reflectance spectra variability: implications for hyperspectral remote sensing in estuarine waters. Mar Sci 4(1):1–9
Hayes KC, Shuler AJ, White D (2008) An assessment of South Carolina waters. In: Proceedings of the 2008 South Carolina Water Resources Conference, Columbia, 14–15 October 2008
Hayes MO, Sexton WJ, Colquhoun DJ, Eckard TL (1993) Evolution of the Santee/Pee Dee delta complex, South Carolina, USA. In: Kay R (ed) Deltas of the world. American society of civil engineers, New York, pp 54–64
Kohavi R, Summerfield D, Dougherty J (1995) Data mining using MLC++ A machine learning library in C++. In: Mellish CS (ed) Proceedings of the fourteenth international joint conference on artificial intelligence, Morgan Kaufmann Publishers Inc, San Francisco, pp 1137–1143
Kutser T, Vahtmäe E, Paavel B, Kauer T (2013) Removing glint effects from field radiometry data measured in optically complex coastal and inland waters. Remote Sens Environ 133:85–89
Li L (2006) Partial least squares modeling to quantify lunar soil composition with hyperspectral reflectance measurements. J Geophys Res 111(E4):E04002. doi:10.1029/2005JE00259
Libes S, Kindelberger S (2010) Hypoxia in the nearshore coastal waters of South Carolina along the Grand Strand. In: Proceedings of the 2010 South Carolina Water Resources Conference, Columbia, 13–14 October 2010
McCoy C, Viso R, Peterson RN, Libes S, Lewis B, Ledoux J, Voulgaris G, Smith E, Sanger D (2011) Radon as an indicator of limited cross-shelf mixing of submarine groundwater discharge along an open ocean beach in the South Atlantic Bight during observed hypoxia. Cont Shelf Res 31:1306–1317
Mitchell BG, Kahru M (1998) Algorithms for SeaWiFS standard products developed with the CalCOFl bio-optical data set. Cal Coop Ocean Fish 39:133–147
Mobley CD (1999) Estimation of the remote-sensing reflectance from above-surface measurements. Appl Optics 38(36):7442–7455
Moore WS (1996) Large groundwater inputs to coastal waters revealed by 226Ra enrichments. Nature 380:612–614
Moore WS (1999) The subterranean estuary: a reaction zone of ground water and sea water. Mar Chem 65:111–125
Moore WS, Wilson AM (2005) Advective flow through the upper continental shelf driven by storms, buoyancy, and submarine groundwater discharge. Earth Planet Sc Lett 235:564–576
Moses WJ, Bowles JH, Corson MR (2015) Expected improvements in the quantitative remote sensing of optically complex waters with the use of an optically fast hyperspectral spectrometer — a modeling study. Sensors 15:6152–6173
Moses WJ, Gitelson AA, Berdnikov S, Povazhnyy V (2009) Estimation of chlorophyll-a concentration in case II waters using MODIS and MERIS data-successes and challenges. Environ Res Lett 4:045002. doi:10.1088/1748-9326/4/4/045005
Moses WJ, Gitelson AA, Berdnikov S, Saprygin V, Povazhnyim V (2012a) Operational MERIS-based NIR-red algorithms for estimating chlorophyll-a -concentrations in coastal waters- The Azov Sea case study. Remote Sens Environ 121:118–124
Moses WJ, Gitelson AA, Perk RL, Gurlin D, Rundquist DC, Leavitt BC, Barrow TM, Brakhage P (2012b) Estimation of chlorophyll-a concentration in turbid productive waters using airborne hyperspectral data. Water Res 46:993–1004
Nixon SW (1995) Coastal marine eutrophication: a definition, social causes and future concerns. Ophelia 41:199–219
O'Reilly JE, Maritorena, S, Mitchell BG, Siegel DA, Carder KL (1998) Ocean color chlorophyll algorithms for SEAWIFS. J Geophys Res 103(C11):24937–24953
O'Reilly JE, Maritorena S, Siegel D, O'Brien MO, Toole D, Mitchell BG, Kahru M, Chavez F, Strutton PG, Cota GF, Hooker SB, McClain C, Carder K, Muller-Karger F, Harding L, Magnuson A, Phinney D, Moore G, Aiken J, Arrigo KR, Letelier RM, Culver M (2000) Ocean color chlorophyll a algorithms for SeaWiFS, OC2, and OC4: version 4. In: Hooker SB, Firestone ER (eds) SeaWiFS postlaunch calibration and validation analyses. Goddard Space Flight Center, Greenbelt, pp 9–23
Robertson AL, Tedesco LL, Wilson J, Soyeux E (2009) Using partial least squares (PLS) method for estimating cyanobacterial pigments in eutrophic inland waters. In: Gao W, Jackson TJ (eds) Remote sensing and modeling of ecosystems for remote sensing and modeling of ecosystems for sustainability IV. San Diego, Proc of SPIE 7454
Ruddick KG, Gons HJ, Rijkeboer M, Tilstone G (2001) Optical remote sensing of chlorophyll a in case 2 waters by use of an adaptive two-band algorithm with optimal error properties. Appl Optics 40(21):3375–3585
Sanger D, DeVoe MR, Hernandez D (2010) Long Bay hypoxia study: a collaborative and multidisciplinary approach. In: Shifting shorelines: adapting to the future, The 22nd International Conference of The Coastal Society, Wilmington, USA, June 13–16 2010
Schalles JF (2006) Optical remote sensing techniques to estimate phytoplankton chlorophyll a concentrations in coastal waters with varying suspended matter and CDOM concentrations. In: Richardson LL, Ledrew EF (eds) Remote sensing of aquatic coastal ecosystem processes: science and management applications. Springer, Dordrecht, pp 27–79
Shanmugam P (2011) A new bio-optical algorithm for the remote sensing of algal blooms in complex ocean waters. J Geophys Res 116(C4):C04016. doi:10.1029/2010JC006796
Smith EM, Buck T, Lakish B (2010) Biological regulation in the formation of hypoxia. In: Proceedings of the 2010 South Carolina Water Resources Conference, Columbia, 13–14 October 2010
Stumpf RP, Arnone RA, Gould RW, Martinolich PM, Ransibrahmanakul V, Tester PA, Steward RG, Subramaniam A, Culver M, Pennock JR (2000) SeaWiFS ocean color data for U.S. Southeast coastal waters. In: Proceedings of the 6th International Conference on Remote Sensing for Marine and Coastal Environments, Veridian ERIM International, Ann Arbor, Michigan, 1–3 May 2000, pp 25–27
US EPA (2008) National coastal condition report III. United States Environmental Protection Agency, Washington DC, EPA/842-R-08-002
USGS (2013) USGS current conditions for South Carolina, National Water Information system. United States Geological Survey, US Department of the Interior. http://waterdata.usgs.gov/sc/nwis/uvAccessed 27 Aug 2013
Verity PG, Alber M, Bricker S (2006) Development of hypoxia in well-mixed subtroptical estuaries in the Southeastern USA. Estuar Coast 29(4):665–673
Viso R, McCoy C, Gayes P, Quafisi D (2010) Geological controls on submarine groundwater discharge in Long Bay, South Carolina (USA). Cont Shelf Res 30:335–341
Walker P (2009) Guidelines for post processing GER 1500 spectral data files using a FSF Excel template (version 03). National Environmental Research Council Field Spectroscopy Facility
Werdell PJ, Bailey SW, Franz BA, Harding LWJr, Feldman GC, McClain CR (2009) Regional and seasonal variability of chlorophyll-a in Chesapeake Bay as observed by SeaWiFS and MODIS-Aqua. Remote Sens Environ 113:1319–1330
Werner JC, Armstrong B, Sylvester CS, Voulgaris G, Nelson T, Schwab WC, Denny JF (2012) Storm-induced inner-continental shelf circulation and sediment transport: Long Bay, South Carolina. Cont Shelf Res 42:51–63
Wold H (1966) Estimation of principal components and related models by iterative least squares. In: Krishnaiaah PR (ed) Multivariate analysis. Academic Press, New York, pp 391–420
Wold S, Ruhe A, Wold H, Dunn WJIII (1984) The collinearity problem in linear regression-the partial least squares (PLS) approach to generalized inverses. SIAM J Sci Stat Comp 5(3):735–743
Wold S, Sjöströma M, Eriksson L (2001) PLS-regression: a basic tool of chemometrics. Chemometr Intell Lab 58(2):109–130
Yacobi YZ, Moses WJ, Kaganovsky S, Sulimani B, Leavitt BC, Gitelson AA (2011) NIR-red reflectance-based algorithms for chlorophyll-a estimation in mesotrophic inland and coastal waters: Lake Kinneret case study. Water Res 45:2428–2436
Yeniay O, Göktas A (2002) A comparison of partial least squares regression with other prediction methods. Hacet J Math Stat 31:99–111
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Ryan, K., Ali, K. Application of a partial least-squares regression model to retrieve chlorophyll-a concentrations in coastal waters using hyper-spectral data. Ocean Sci. J. 51, 209–221 (2016). https://doi.org/10.1007/s12601-016-0018-8
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DOI: https://doi.org/10.1007/s12601-016-0018-8