Remote Sensing of Seagrass Ecosystems: Use of Spaceborne and Airborne Sensors

Dekker, Arnold G.; Brando, Vittorio E.; Anstee, Janet; Fyfe, S. K.; Malthus, Tim J.; Karpouzli, Evanthia

doi:10.1007/978-1-4020-2983-7_15

Cited by 28 publications

(30 citation statements)

References 36 publications

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“…There has been an extensive amount of effort devoted to using remote sensing to understand seagrass dynamics at larger estuarine landscape scales, particularly in estuaries where other anthropogenic disturbances such as eutrophication are more likely to affect change (Kendrick et al 2000, Dekker et al 2007, Orth et al 2010b, Lyons et al 2013), but only recently have investigators addressed impacts of shellfish aquaculture on seagrass at this scale (Ward et al 2003, Carswell et al 2006, Barille et al 2010, Martin et al 2010, Bulmer et al 2012. Willapa Bay provides a unique opportunity to examine this interaction at the estuarine landscape scale because shellfish aquaculture within eelgrass was not restricted prior to 2007 when a new permit (US Nationwide Permit 48) was issued by the US Army Corps of Engineers (US ACOE) with protection for native eelgrass Z. marina.…”

Section: Open Pen Access Ccessmentioning

confidence: 99%

Effect of oyster aquaculture on seagrass Zostera marina at the estuarine landscape scale in Willapa Bay, Washington (USA)

Dumbauld¹,

McCoy²

2015

Aquacult. Environ. Interact.

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Section: Open Pen Access Ccessmentioning

confidence: 99%

Effect of oyster aquaculture on seagrass Zostera marina at the estuarine landscape scale in Willapa Bay, Washington (USA)

Dumbauld¹,

McCoy²

2015

Aquacult. Environ. Interact.

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“…Given the relatively low spectral response that reaches remote sensors from underwater subjects [11] and the objective of utilizing the image-based classifier across images, pre-processing of satellite data to adequately correct for atmospheric and water column variation was an important step of this study. The underlying motivation of working towards a mapping methodology that is easily implemented with a minimum of specialized equipment and software influenced the decisions on pre-processing techniques.…”

Section: Satellite Data Pre-processingmentioning

confidence: 99%

“…Continued study of coastal landscape dynamics with accurate, quantitative measurements of areal extent and density of seagrasses is needed to better understand the mosaic of their distribution (degree of patchiness, gap dynamics, habitat edge type, and connectivity) in conjunction with the temporal and spatial variability of hydrologic inputs to coastal areas [7]. Characterizing these dynamics from a synoptic, repeatable perspective with remotely sensed data [11] can strongly augment more accurate point measures of change derived in-situ [12].…”

Section: Introductionmentioning

confidence: 99%

“…The "quality" and relevance of classes derived from satellite data are variable across images [21] so that transferring pixel-based definitions of class spectra to other images has been considered impractical [11]. Constraining class definitions to the image in which training pixels are identified, however, limits the resulting multi-temporal analysis to dates where in-situ or other ground truth source is available for the selection of calibration data.…”

Section: Introductionmentioning

confidence: 99%

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Supervised Classification of Benthic Reflectance in Shallow Subtropical Waters Using a Generalized Pixel-Based Classifier across a Time Series

2015

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Abstract:We tested a supervised classification approach with Landsat 5 Thematic Mapper (TM) data for time-series mapping of seagrass in a subtropical lagoon. Seagrass meadows are an integral link between marine and inland ecosystems and are at risk from upstream processes such as runoff and erosion. Despite the prevalence of image-specific approaches, the classification accuracies we achieved show that pixel-based spectral classes may be generalized and applied to a time series of images that were not included in the classifier training. We employed in-situ data on seagrass abundance from 2007 to 2011 to train and validate a classification model. We created depth-invariant bands from TM bands 1, 2, and 3 to correct for variations in water column depth prior to building the classification model. In-situ data showed mean total seagrass cover remained relatively stable over the study area and period, with seagrass cover generally denser in the west than the east. Our approach achieved mapping accuracies (67% and 76% for two validation years) comparable with those attained using spectral libraries, but was simpler to implement. We produced a series of annual maps illustrating inter-annual variability in seagrass occurrence. Accuracies may be improved in future work by better addressing the spatial mismatch between pixel size of remotely sensed data and footprint of field data and by employing atmospheric correction techniques that normalize reflectances across images. OPEN ACCESSRemote Sens. 2015, 7 5099

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“…Very few papers, with the exception of large scale physical-biological oceanographic applications, published in scientific journals show a global uptake of the science and techniques of aquatic remote sensing into environmentally relevant monitoring and management applications. The majority of past reviews of remote sensing for coastal applications have focused on two areas: (1) improvements to technology, techniques and applications, with limited assessment of accuracy and true costs [1,3,[5][6][7][8][9][10][11] and (2) understanding light interactions in shallow water environments [6,12]. Both of these activities were essential to underpin the use of remote sensing for monitoring and managing coastal resources.…”

mentioning

confidence: 99%

Guest Editorial: Coastal Aquatic Remote Sensing Applications for Environmental Monitoring and Management

Brando

Phinn

2007

J. Appl. Remote Sens

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In all regions of the world, coastal aquatic environments are under increasing levels of environmental stress, due to the large number of people living immediately adjacent to them and using them as a resource. Information on the composition and condition of these water bodies and their benthic environments is a critical piece of knowledge infrastructure for development and application of coastal management practices [1][2][3]. Due to the large and dynamic nature of coastal aquatic environments, remote sensing offers a potential source for this information. However, if remote sensing is so useful and suitable data sets for mapping and monitoring coastal environments have been around since the Landsat era (1972) -why isn't it widely used in coastal resource management applications around the world?There are a number of potential answers to that question, related to suitability of technology, methods and the communication of true costs and capabilities of remote sensing based approaches. Bukata [4] offers the following reasons for the limited "operational" use of remote sensing for monitoring coastal environments:-Inadequate technology; -Inadequate science; -Inadequate or non-existent applications; -Inadequate communication of potential, results and products; -Lack of official standards for image products; -Cost of regular delivery is too high; -Satellite remote sensing is "suspect"; and -Society and/or organizational barriers exist. Very few papers, with the exception of large scale physical-biological oceanographic applications, published in scientific journals show a global uptake of the science and techniques of aquatic remote sensing into environmentally relevant monitoring and management applications. The majority of past reviews of remote sensing for coastal applications have focused on two areas: (1) improvements to technology, techniques and applications, with limited assessment of accuracy and true costs [1,3,[5][6][7][8][9][10][11] and (2) understanding light interactions in shallow water environments [6,12]. Both of these activities were essential to underpin the use of remote sensing for monitoring and managing coastal resources. We are now in a position where we can: collect suitable image data; apply robust models to transform the images to maps of biophysical parameters; collect field data to

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Remote Sensing of Seagrass Ecosystems: Use of Spaceborne and Airborne Sensors

Cited by 28 publications

References 36 publications

Effect of oyster aquaculture on seagrass Zostera marina at the estuarine landscape scale in Willapa Bay, Washington (USA)

Effect of oyster aquaculture on seagrass Zostera marina at the estuarine landscape scale in Willapa Bay, Washington (USA)

Supervised Classification of Benthic Reflectance in Shallow Subtropical Waters Using a Generalized Pixel-Based Classifier across a Time Series

Guest Editorial: Coastal Aquatic Remote Sensing Applications for Environmental Monitoring and Management

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