Remote Sensing of Shallow Coastal Benthic Substrates: In situ Spectra and Mapping of Eelgrass (Zostera marina) in the Gulf Islands National Park Reserve of Canada

Eelgrass (Zostera marina) is a keystone component of inter- and sub-tidal ecosystems. However, anthropogenic pressures have caused its populations to decline worldwide. Delineation and continuous monitoring of eelgrass distribution is an integral part of understanding these pressures and providing effective coastal ecosystem management. A proposed tool for such spatial monitoring is remote imagery, which can cost- and time-effectively cover large and inaccessible areas frequently. However, to effectively apply this technology, an understanding is required of the spectral behavior of eelgrass and its associated substrates. In this study, in situ hyperspectral measurements were used to define key spectral variables that provide the greatest spectral separation between Z. marina and associated submerged substrates. For eelgrass classification of an in situ above water reflectance dataset, the selected variables were: slope 500–530 nm, first derivatives (R’) at 566 nm, 580 nm, and 602 nm, yielding 98% overall accuracy. When the in situ reflectance dataset was water-corrected, the selected variables were: 566:600 and 566:710, yielding 97% overall accuracy. The depth constraint for eelgrass identification with the field spectrometer was 5.0 to 6.0 m on average, with a range of 3.0 to 15.0 m depending on the characteristics of the water column. A case study involving benthic classification of hyperspectral airborne imagery showed the major advantage of the variable selection was meeting the sample size requirements of the more statistically complex Maximum Likelihood classifier. Results of this classifier yielded eelgrass classification accuracy of over 85%. The depth limit of eelgrass spectral detection for the AISA sensor was 5.5 m.

[1]  Fred W. Glover,et al.  A user's guide to tabu search , 1993, Ann. Oper. Res..

[2]  Menghua Wang,et al.  Effects of ocean surface reflectance variation with solar elevation on normalized water-leaving radiance. , 2006, Applied optics.

[3]  R. Macdonald,et al.  Effects of local and global change on an inland sea: the Strait of Georgia, British Columbia, Canada , 2009 .

[4]  B. Efron Nonparametric estimates of standard error: The jackknife, the bootstrap and other methods , 1981 .

[5]  Veronique Carrere,et al.  Spectrometric constraint in analysis of benthic diatom biomass using monospecific cultures , 2003 .

[6]  Peter J. Mumby,et al.  Mapping marine environments with IKONOS imagery: enhanced spatial resolution can deliver greater thematic accuracy , 2002 .

[7]  A. Gitelson,et al.  Non-destructive determination of chlorophyll content of leaves of a green and an aurea mutant of tobacco by reflectance measurements , 1996 .

[8]  Steven G. Ackleson,et al.  Remote sensing of submerged aquatic vegetation in lower chesapeake bay: A comparison of Landsat MSS to TM imagery , 1987 .

[9]  G. Borstad,et al.  An Assessment and Classification of a Multispectral Bandset for the Remote Sensing of Intertidal Seaweeds , 1992 .

[10]  Vittorio E. Brando,et al.  Retrospective seagrass change detection in a shallow coastal tidal Australian lake , 2005 .

[11]  N. Marbà,et al.  Seagrass ( Posidonia oceanica) vertical growth as an early indicator of fish farm-derived stress , 2006 .

[12]  S. Tassan Modified Lyzenga's method for macroalgae detection in water with non-uniform composition , 1996 .

[13]  John A. Richards,et al.  Remote Sensing Digital Image Analysis: An Introduction , 1999 .

[14]  Carlos M. Duarte,et al.  Seagrass Biomass And Production: A Reassessment , 1999 .

[15]  Andrew D. Richardson,et al.  Spectral reflectance of the seagrasses: Thalassia testudinum, Halodule wrightii, Syringodium filiforme and five marine algae , 2007 .

[16]  Robert A. Leathers,et al.  Ocean color remote sensing of seagrass and bathymetry in the Bahamas Banks by high‐resolution airborne imagery , 2003 .

[17]  Hyun Jung Cho,et al.  Test of Multi-spectral Vegetation Index for Floating and Canopy-forming Submerged Vegetation , 2008, International journal of environmental research and public health.

[18]  Samantha J. Lavender,et al.  Sun Glint Correction of High and Low Spatial Resolution Images of Aquatic Scenes: a Review of Methods for Visible and Near-Infrared Wavelengths , 2009, Remote. Sens..

[19]  N. Marbà,et al.  Benthic input rates predict seagrass (Posidonia oceanica) fish farm-induced decline. , 2008, Marine pollution bulletin.

[20]  Eric J. Hochberg,et al.  Capabilities of remote sensors to classify coral, algae, and sand as pure and mixed spectra , 2003 .

[21]  Robert A. Leathers,et al.  Optical remote sensing of benthic habitats and bathymetry in coastal environments at Lee Stocking Island, Bahamas: A comparative spectral classification approach , 2003 .

[22]  H. Claustre,et al.  Optical properties of the “clearest” natural waters , 2007 .

[23]  D. Schneider,et al.  Fractal measures of habitat structure: maximum densities of juvenile cod occur at intermediate eelgrass complexity , 2010 .

[24]  M. Kemp,et al.  Potential climate-change impacts on the Chesapeake Bay , 2008 .

[25]  Paul J. Harrison,et al.  Review of the Biological Oceanography of the Strait of Georgia: Pelagic Environment , 1983 .

[26]  Georg Martin,et al.  Feasibility of hyperspectral remote sensing for mapping benthic macroalgal cover in turbid coastal waters—a Baltic Sea case study , 2006 .

[27]  Lorenzo Bruzzone,et al.  Classification of Hyperspectral Images With Regularized Linear Discriminant Analysis , 2009, IEEE Transactions on Geoscience and Remote Sensing.

[28]  Chris Roelfsema,et al.  A physics based retrieval and quality assessment of bathymetry from suboptimal hyperspectral data , 2009 .

[29]  J. Borg,et al.  Wanted dead or alive: high diversity of macroinvertebrates associated with living and ‘dead’ Posidonia oceanica matte , 2006 .

[30]  Samuel J. Purkis,et al.  A "Reef-Up" approach to classifying coral habitats from IKONOS imagery , 2005, IEEE Transactions on Geoscience and Remote Sensing.

[31]  K. Bjorndal,et al.  Historical Overfishing and the Recent Collapse of Coastal Ecosystems , 2001, Science.

[32]  S R Phinn,et al.  Mapping water quality and substrate cover in optically complex coastal and reef waters: an integrated approach. , 2005, Marine pollution bulletin.

[33]  Jiaguo Qi,et al.  Identifying optimal spectral bands from in situ measurements of Great Lakes coastal wetlands using second-derivative analysis , 2005 .

[34]  A. Gitelson,et al.  Quantitative remote sensing methods for real-time monitoring of inland waters quality , 1993 .

[35]  John A. Richards,et al.  Remote Sensing Digital Image Analysis , 1986 .

[36]  C. Mobley,et al.  Estimation of the remote-sensing reflectance from above-surface measurements. , 1999, Applied optics.

[37]  A. Mccomb,et al.  Effect of boat moorings on seagrass beds near Perth, Western Australia , 1989 .

[38]  John D. Hedley,et al.  A remote sensing method for resolving depth and subpixel composition of aquatic benthos , 2003 .

[39]  Arnold G. Dekker,et al.  A methodology for retrieval of environmental noise equivalent spectra applied to four Hyperion scenes of the same tropical coral reef , 2004 .

[40]  S. Adams Feeding Ecology of Eelgrass Fish Communities , 1976 .

[41]  C. Duarte The future of seagrass meadows , 2002, Environmental Conservation.

[42]  S. Fyfe,et al.  Spatial and temporal variation in spectral reflectance: Are seagrass species spectrally distinct? , 2003 .

[43]  D M Snodderly,et al.  The macular pigment. I. Absorbance spectra, localization, and discrimination from other yellow pigments in primate retinas. , 1984, Investigative ophthalmology & visual science.

[44]  M. S. Moran,et al.  Three methods for the absolute calibration of the NOAA AVHRR sensors in-flight , 1990 .

[45]  J. R. Morrison,et al.  Macroalgae and Eelgrass Mapping in Great Bay Estuary Using AISA Hyperspectral Imagery. , 2009 .

[46]  Lorraine Remer,et al.  Detection of forests using mid-IR reflectance: an application for aerosol studies , 1994, IEEE Trans. Geosci. Remote. Sens..

[47]  P. Jeremy Werdell,et al.  Remote assessment of benthic substrate composition in shallow waters using multispectral reflectance , 2003 .

[48]  K. Rowan,et al.  Photosynthetic Pigments of Algae , 2011 .

[49]  H. Gausman,et al.  Visible light reflectance, transmittance and absorptance of differently pigmented cotton leaves , 1983 .

[50]  Maycira Costa,et al.  Bio-optical algorithm evaluation for MODIS for western Canada coastal waters: An exploratory approach using in situ reflectance , 2009 .

[51]  P. Mumby,et al.  The cost-effectiveness of remote sensing for tropical coastal resources assessment and management , 1999 .

[52]  James B. Reeves,et al.  Multivariate analyses of visible/near infrared (VIS/NIR) absorbance spectra reveal underlying spectral differences among dried, ground conifer needle samples from different growth environments , 2003 .

[53]  S. Phinn,et al.  An integrated field and remote sensing approach for mapping Seagrass Cover, Moreton Bay, Australia , 2009 .

[54]  B Gentili,et al.  Determination of the fluorescence quantum yield by oceanic phytoplankton in their natural habitat. , 2000, Applied optics.

[55]  S. Gasparini,et al.  Assessment of Cryptophyceae ingestion by copepods using alloxanthin pigment: a caution , 2004 .

[56]  Katherine A. Call,et al.  Coral reef habitat discrimination using multivariate spectral analysis and satellite remote sensing , 2003 .

[57]  J. Liedtke,et al.  Practical remote sensing of suspended sediment concentration , 1995 .

[58]  T. Kutser,et al.  Spectral library of macroalgae and benthic substrates in Estonian coastal waters , 2006, Proceedings of the Estonian Academy of Sciences. Biology. Ecology.

[59]  Clement Atzberger,et al.  Satellite-based monitoring of tropical seagrass vegetation: current techniques and future developments , 2007, Hydrobiologia.

[60]  J. O'Neill Mapping of eelgrass (Zostera marina) at Sidney Spit, Gulf Islands National Park Reserve of Canada, using high spatial resolution remote imagery , 2010 .

[61]  C. Jordan Derivation of leaf-area index from quality of light on the forest floor , 1969 .

[62]  Vanina Pasqualini,et al.  Use of SPOT 5 for mapping seagrasses: An application to Posidonia oceanica , 2005 .

[63]  Charles H. Fletcher,et al.  Decorrelating remote sensing color bands from bathymetry in optically shallow waters , 2006, IEEE Transactions on Geoscience and Remote Sensing.

[64]  J. Burkholder,et al.  Seagrasses and eutrophication , 2007 .

[65]  André Morel,et al.  Diffuse reflectance of oceanic shallow waters: influence of water depth and bottom albedo , 1994 .

[66]  Chris Roelfsema,et al.  Mapping seagrass species, cover and biomass in shallow waters : An assessment of satellite multi-spectral and airborne hyper-spectral imaging systems in Moreton Bay (Australia) , 2008 .

[67]  R. Arnone,et al.  Deriving inherent optical properties from water color: a multiband quasi-analytical algorithm for optically deep waters. , 2002, Applied optics.

[68]  Frederick T. Short,et al.  Natural and human-induced disturbance of seagrasses , 1996, Environmental Conservation.

[69]  Chris Roelfsema,et al.  Monitoring toxic cyanobacteria Lyngbya majuscula (Gomont) in Moreton Bay, Australia by integrating satellite image data and field mapping , 2006 .

[70]  John D. Hedley,et al.  Technical note: Simple and robust removal of sun glint for mapping shallow‐water benthos , 2005 .

[71]  Richard J. Murphy,et al.  Estimation of surface chlorophyll‐a on an emersed mudflat using field spectrometry: accuracy of ratios and derivative‐based approaches , 2005 .

[72]  James W. Brown,et al.  Above-water radiometry in shallow coastal waters. , 2004, Applied optics.

[73]  N. Marbà,et al.  Fish farming enhances biomass and nutrient loss in Posidonia oceanica (L.) Delile. , 2009 .

[74]  C. Mobley Light and Water: Radiative Transfer in Natural Waters , 1994 .

[75]  Kendall L. Carder,et al.  Change detection in shallow coral reef environments using Landsat 7 ETM+ data , 2001 .

[76]  R. S. Alberte,et al.  Light adaptation and the role of autotrophic epiphytes in primary production of the temperate seagrass, Zostera marina L. , 1986 .

[77]  M. Fonseca,et al.  A preliminary evaluation of wave attenuation by four species of seagrass , 1992 .

[78]  Vittorio E. Brando,et al.  Satellite hyperspectral remote sensing for estimating estuarine and coastal water quality , 2003, IEEE Trans. Geosci. Remote. Sens..

[79]  K. Ruddick,et al.  Seaborne measurements of near infrared water‐leaving reflectance: The similarity spectrum for turbid waters , 2006 .

[80]  E. LeDrew,et al.  Remote sensing of aquatic coastal ecosystem processes , 2006 .

[81]  R. Zimmerman,et al.  Effects of epiphyte load on optical properties and photosynthetic potential of the seagrasses Thalassia testudinum Banks ex König and Zostera marina L. , 2003 .

[82]  Richard C. Zimmerman,et al.  A biooptical model of irradiance distribution and photosynthesis in seagrass canopies , 2003 .

[83]  R. Wetzel,et al.  Seasonal variations in eelgrass (Zostera marina L.) responses to nutrient enrichment and reduced light availability in experimental ecosystems , 2000 .

[84]  R. Congalton,et al.  Accuracy assessment: a user's perspective , 1986 .

[85]  H. Gordon,et al.  Normalized water-leaving radiance: revisiting the influence of surface roughness. , 2005, Applied optics.