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  • ABoVE: Ecosystem Map, Great Slave Lake Area, Northwest Territories, Canada, 1997-2011

    https://cmr.earthdata.nasa.gov/search/concepts/C2143402730-ORNL_CLOUD.xml
    Description:

    This dataset provides an ecosystem type map at 12.5 meter pixel spacing and 0.2 ha minimum mapping unit for the area surrounding Great Slave Lake, Northwest Territories, Canada for the time period 1997 to 2011. The map includes nine classes for peatland, wetland, and upland areas derived from a Random Forest classification trained on multi-date, multi-sensor remote sensing images across the study extent, and using field data and high-resolution Worldview-2 image interpretation for training and validation. The nine classes are: Water, Marsh, Swamp, Open Fen, Treed Fen, Bog, Upland Deciduous, Upland Conifer, and Sparsely Vegetated. A tenth map class identifies areas of historical fires (prior to 2011) that are currently undergoing post-fire successional revegetation. This dataset provides an ecosystem type map of the area before the large fire season of 2014 to better understand the effects of fires in the area.

    Links: Temporal Extent: Spatial Extent:
    Minimum Bounding Rectangle: 58.51 -123.04 65.15 -109.46

    ORNL_CLOUD Short Name: Great_Slave_Lake_Ecosystem_Map_1695 Version ID: 1 Unique ID: C2143402730-ORNL_CLOUD

  • Adelie penguin occupancy survey of Murray Monolith, 2010

    https://cmr.earthdata.nasa.gov/search/concepts/C1384658088-AU_AADC.xml
    Description:

    Oblique hand-held photographs were taken of all Adelie penguin breeding colonies at Murray Monolith from a fixed wing aircraft on 10 December 2010. These photographs were geo-referenced to a Worldview 2 satellite image of both monoliths taken on 26 January 2011 and the colony boundaries in the geo-referenced photos were digitised as shapefiles. Some sections of the digitised Murray Monolith colonies near the crescent shaped moraine were moved so they were contained within the shapefile ‘rock_exposed_for_modelling_Scullin_Murray’)

    Links: Temporal Extent: Spatial Extent:
    Minimum Bounding Rectangle: -67.7847 66.8874 -67.7837 66.8884

    AU_AADC Short Name: AAS_4088_Adelie_occupancy_Murray_2010 Version ID: 1 Unique ID: C1384658088-AU_AADC

  • Adelie penguin occupancy survey of Scullin Monolith, 2010

    https://cmr.earthdata.nasa.gov/search/concepts/C1384658092-AU_AADC.xml
    Description:

    Oblique hand-held photographs were taken of all Adelie penguin breeding colonies at Scullin Monolith from a fixed wing aircraft on 10 December 2010. These photographs were geo-referenced to a Worldview 2 satellite image of both monoliths taken on 26 January 2011 and the colony boundaries in the geo-referenced photos were digitised as shapefiles.

    Links: Temporal Extent: Spatial Extent:
    Minimum Bounding Rectangle: -67.794 66.7183 -67.793 66.7193

    AU_AADC Short Name: AAS_4088_Adelie_occupancy_Scullin_2010 Version ID: 1 Unique ID: C1384658092-AU_AADC

  • Adelie penguin occupancy survey of the Wilkes Land Coastline, 2011

    https://cmr.earthdata.nasa.gov/search/concepts/C1384660074-AU_AADC.xml
    Description:

    An occupancy survey on 21 January 2011 found a total of 7 islands along the Wilkes Land coastline had populations of breeding Adelie penguins. The survey was conducted from a fixed wing aircraft and oblique aerial photographs were taken of each occupied site except Haswell Island. The aerial photographs were geo-referenced to a satellite image and the boundaries of penguin colonies were digitised from the geo-referenced photos. Details for each island are: Adams: Photographs taken on 21 January 2011 and geo-referenced to a Quickbird satellite image taken on 30 January 2009 Fulmar: Photographs taken on 21 January 2011 and geo-referenced to a WorldView2 satellite image taken on 6 February 2011 Zykov: Photographs taken on 21 January 2011 and geo-referenced to a WorldView2 satellite image taken on 6 February 2011 Buromskiy: Photographs taken on 21 January 2011 and geo-referenced to a WorldView2 satellite image taken on 6 February 2011 Stroitley: Photographs taken on 21 January 2011 and geo-referenced to a WorldView2 satellite image taken on 6 February 2011 Tokarev: Photographs taken on 21 January 2011 and geo-referenced to a WorldView2 satellite image taken on 6 February 2011 Haswell: No photographs taken, no penguin colonies were digitised Note there are two colony boundary layers in each folder except Adams. One is the original layer mapped as above. The second is an adjusted layer that was created so that the mapped boundaries would land on the exposed rock layer. Mapping of some of the islands contained within the coast layer had been coarsely done using imagery available at the time. Now with more accurate satellite imagery the island mapping could potentially be updated which would more accurately locate these islands. If this occurred, the original colony boundary mapping may be a more appropriate fit.

    Links: Temporal Extent: Spatial Extent:
    Minimum Bounding Rectangle: -67 89 -66 93.5

    AU_AADC Short Name: AAS_4088_Adelie_occupancy_Wilkes_2011 Version ID: 1 Unique ID: C1384660074-AU_AADC

  • Airborne, satellite and ground imaging spectroscopy data for estimation of chlorophyll content, leaf density and relative vigour of Antarctic mosses at ASPA 135 and Robinson Ridge study sites.

    https://cmr.earthdata.nasa.gov/search/concepts/C1395371987-AU_AADC.xml
    Description:

    For the complete description, including images and original formatting, see the metadata file in the downloadable dataset. Research sites All remote sensing data sets were collected at two pilot research sites, Antarctic Specially Protected Area 135 (ASPA) and Robinson Ridge (Robbos), that host significant populations of Antarctic moss species, particularly: Schistidium antarctici (Cardot) L.I. Savicz and Smirnova, Bryum pseudotriquetrum (Hedw.) Gaertn., Meyer and Scherb., and Ceratodon purpureus (Hedw.) Brid. Verification of remote sensing products was performed with data from a long-term monitoring project of Windmill Islands' plant communities using observations of 13 permanent quadrats, which were established at ASPA and Robbos in 2003 (Wasley et al., 2012). Laboratory spectral and biochemical measurements for training of predictive machine leaning algorithms were performed on moss samples collected in the vicinity of the Casey polar station in 2013 and previously in 1999 (Lovelock and Robinson, 2002). Airborne UAS hyperspectral image data UAS imaging spectroscopy data were acquired with a Headwall Photonics Micro-Hyperspec VNIR scanner (Headwall Inc., USA) mounted on an Aeronavics Skyjib multirotor (oktokopter) heavy-lift airframe. The Micro-Hyperspec push-broom scanner, equipped with an objective of 8 mm focal length, a field of view (FOV) of 49.8 degrees, a slit entrance of 25 microns and a 12- bit charge-coupled device (CCD) of 1004 pixels, was flown in a binned mode with the frame period and integration time of 20 milliseconds (maximum rate of 50 frames s-1) 11 m above ground level at a speed of 2.5 m s-1. The acquired imagery of 162 spectral bands between 361 and 961 nm had a bandwidth from 4.75 to 5.25 nm and a spatial resolution of 5.0 cm. The raw hyperspectral data was radiometrically standardized and corrected for atmospheric interferences. Digital counts of recorded light were converted to physical units of at-sensor radiance (mW cm2 sr-1 microns-1) and to relative reflectance by applying sensor-specific radiometric calibration coefficients and an empirical line atmospheric correction as described in Lucieer et al. (2014). The accuracy of the resulting UAS reflectance was assessed as acceptable using spectral signatures of several spatially homogeneous natural targets (6 large rocks and 9 green moss patches) measured on ground with an ASD HandHeld-2 spectroradiometer (ASD, Inc. and PANalytical, Boulder, Colorado, USA). To provide georeferenced images and derived maps, the hyperspectral images were orthorectified and mosaicked using detailed (1 cm resolution) three-dimensional digital surface models and orthophotos of research plots into the map coordinate system of WGS84 UTM zone 49 South, with a rubber sheeting triangulation based on 50 evenly distributed artificial ground control points. Final hyperspectral mosaic for ASPA is depicted in Figure 1 and light lines over Robbos in Figure 2 (see the metadata file in the downloadable dataset for the figures). Fig. 1. Hyperspectral mosaic in false colours (acquired on 2nd and 8th February 2013) superimposed over orthophoto of the Antarctic Specially Protected Area 135 (ASPA 135) research site acquired in 2013 (red colour = moss canopy). The epsilon Support Vector Regression (SVR) learning machine, using the nonlinear Gaussian radial basis function (RBF) kernel, was applied on reflectance hyperspectral data to estimate the total chlorophyll a and b content (Cab) and the effective leaf density (ELD) of investigated moss turfs. To produce a single moss health evaluator, the Cab and ELD maps were merged into a synthetic map of a relative vigour indicator (RVI), which was computed as the arithmetic mean of Cab and inverted LD, both scaled between zero and the largest value measured in laboratory (i.e. Cab = 1500 nmol.gdw-1 and LD = 15 leaves.mm-1). The RVI maps represent relative vigour, where 100% indicates optimally growing healthy moss, and 0% indicates moss highly stressed by unfavourable environmental conditions. Details regarding the method, i.e. design, training, validation and application of the SVR algorithms, are provided in Malenovsky et al. (2015). Fig. 2. Two hyperspectral flight lines in false colours (acquired on 5th and 6th February 2013) superimposed over ortho-photomap of the Robinson Ridge (Robbos) study site from 2011 (red colour = moss canopy). All UAS airborne data are located in the directory Airborne_UAS. All image datasets are stored in two file formats: - *.bsq - band sequential image file and - *.hdr - header ASCII file containing all essential metadata about the complementary *.bsq file. The following UAS image datasets are provided for both study sites: - '0208 or 05/06'FEB2013_'ASPA135 or ROBBOS'_'geomosaic or flightline#'_living_moss_Cab -' chlorophyll content of living moss turf in nmol.gdw-1 retrieved with the SVR algorithm from the hyperspectral imagery (for more information see complementary *.hdr ASCII file). - '0208 or 05/06' FEB2013_'ASPA135 or ROBBOS'_'geomosaic or flightline#'_living_moss _ELD -' effective leaf density of living moss turf in leaves.mm-1 retrieved with the SVR algorithm from hyperspectral imagery (for more information see complementary *.hdr ASCII file). - '0208 or 05/06' FEB2013_'ASPA135 or ROBBOS'_'geomosaic or flightline#'_living_moss _RVI -' relative vigour index of living moss turf in % generated as mean of chlorophyll content and inverted leaf density scaled between 0 and the maximal measured values (for more information see *.hdr ASCII file). - '0208 or 05/06' FEB2013_'ASPA135 or ROBBOS'_'geomosaic or flightline#'_moribund_moss _MASK -' classification of moribund moss (value = 1) derived from the MTVI2 optical index (MTVI2 greater than or equal to 0.25) computed from hyperspectral images (more information in *.hdr ASCII file). - '0208 or 05/06' FEB2013_'ASPA135 or ROBBOS'_'geomosaic or flightline#'_reflectance - 'image of relative hemispherical-directional reflectance acquired with the Micro-Hyperspec spectroradiometer mounted to Skyjib multirotor UAS (more information in *.hdr ASCII file). The Microsoft Excel file Hyperspec_SVR_inputs.xlsx contains 4 spreadsheets with datasets used for training and testing of leaf chlorophyll content (Cab in in nmol.gdw-1) and effective leaf density (ELD in number of leaves. mm-1) estimating SVR machines applicable to Micro-Hyperspec VNIR bands (CR ~ continuum removed reflectance and R ~ reflectance at given wavelength in nm). Satellite spectral image data The multispectral WorldView-2 (WV2) space-borne images (DigitalGlobe, Inc., Westminster, Colorado, USA) of the Windmill Islands, containing 8 spectral bands at spatial resolution of 2.2 m, were acquired on 30th January 2011 for Robbos and 7th February 2011 for ASPA. Radiometric calibration, converting the 11-bit image into physically meaningful radiance, was performed with the WV2 calibration coefficients available in the ENVI/IDL image processing software (Harris Geospatial Solutions/Exelis Visual Information Solutions, Inc., Boulder, Colorado, USA) and atmospheric correction was carried out with the fast line-of-sight atmospheric analysis of hypercubes (FLAASH) module. The reflectance images were projected into the Universal Transverse Mercator coordinate system (UTM Zone 49 South, datum WGS84). Only image pixels with greater than 50% abundance of vigorous moss were used in the health assessment analyses. These pixels were selected by applying the threshold of the normalized difference vegetation index (NDVI greater than 0.6) in combination with the spectral mixture tuned matched filtering (MTMF). The same type of the SVR machines were trained and applied to estimate the total chlorophyll a and b content (Cab) and the effective leaf density (ELD) of investigated moss turfs. Subsequently, the relative moss vigour (RVI) was computed as in Malenovsky et al. (2015). The satellite datasets are located in the directory Satellite_WV2. All image data is stored in two file formats: - *.bsq - band sequential image file and - *.hdr - header ASCII file containing all essential metadata about the complementary *.bsq file. The following WV2 image datasets are provided for both study sites: - WV2_'07FEB or 30JAN'2011_'ASPA135 or ROBBOS'_moss_Cab -' chlorophyll content in nmol.gdw-1 for pixels with more than 50% moss abundance retrieved with the SVR algorithm from the WV2 multispectral imagery (for more information see complementary *.hdr ASCII file). - WV2_'07FEB or 30JAN'2011_'ASPA135 or ROBBOS'_moss_ELD -' effective leaf density in leaves.mm-1 for pixels with more than 50% moss abundance retrieved with the SVR algorithm from the WV2 multispectral imagery (for more information see complementary *.hdr ASCII file). - WV2_'07FEB or 30JAN'2011_'ASPA135 or ROBBOS'_moss_RVI -' relative vigour index in % for pixels with more than 50% moss abundance generated as mean of chlorophyll content and inverted leaf density scaled between 0 and the maximal measured values (for more information see *.hdr ASCII file). - WV2_'07FEB or 30JAN'2011_'ASPA135 or ROBBOS'_moss_reflectance -' image of relative hemispherical-directional reflectance for pixels with more than 50% moss abundance acquired by the WorldView-2 satellite spectroradiometer (for more information see *.hdr ASCII file). The Microsoft Excel file WV2_SVR_inputs.xlsx contains 4 spreadsheets with datasets used for training and testing of leaf chlorophyll content (Cab in in nmol.gdw-1) and effective leaf density (ELD in number of leaves. mm-1) estimating SVR machines applicable to WorldView-2 multispectral bands (CR ~ continuum removed reflectance and R ~ reflectance at given wavelength in nm). Ground validation measurements Applicability of the remote sensing moss health indicators was validated by direct one-to-one comparison with the relative abundance of healthy, stressed and moribund moss in 13 monitoring quadrats of 25x25 cm in size. The ground-collected data are stored in the directory Ground_validation. Ground validation data per quadrat and complementary remote sensing products obtained by interpretation of the red-green-blue (RGB) colour composite photographs and the hyperspectral UAS data, respectively, are listed in the Microsoft Excel file spreadsheet Validation_input_data quadrats2013.xlsx. Geo-locations of the validation quadrats in UTM Zone 49 South (datum WGS84) are available in the ESRI vector shape file Validation_quadrats_FEB2013.shp (with the ancillary files *.shx, *.dbf, *.prj and *.qpj). References Lovelock, C. E. and Robinson S. A. (2002), Surface reflectance properties of Antarctic moss and their relationship to plant species, pigment composition and photosynthetic function. Plant Cell and Environment, 25, 1239-1250. Lucieer, A., Malenovsky, Z., Veness, T. and Wallace, L. (2014a), HyperUAS - Imaging spectroscopy from a multi-rotor unmanned aircraft system. Journal of Field Robotics, 31, 571-590. Malenovsky, Z., Turnbull, J. D., Lucieer, A. and Robinson, S. A. (2015), Antarctic moss stress assessment based on chlorophyll, water content, and leaf density retrieved from imaging spectroscopy data. New Phytologist, 208, 608-624. Wasley, J., Robinson, S. A., Turnbull, J. D., King, D. H., Wanek, W. and Popp, M. (2012), Bryophyte species composition over moisture gradients in the Windmill Islands, East Antarctica: Development of a baseline for monitoring climate change impacts. Biodiversity, 13, 257-264.

    Links: Temporal Extent: Spatial Extent:
    Minimum Bounding Rectangle: -66.368 110.527 -66.282 110.586

    AU_AADC Short Name: AAS_4046_spectroscopy_chlorophyll Version ID: 1 Unique ID: C1395371987-AU_AADC

  • CMS: Mangrove Canopy Height Estimates from Remote Imagery, Zambezi Delta, Mozambique

    https://cmr.earthdata.nasa.gov/search/concepts/C2343163771-ORNL_CLOUD.xml
    Description:

    This data set provides high resolution canopy height estimates for mangrove forests in the Zambezi Delta, Mozambique, Africa. The estimates were derived from three separate canopy height models (CHM) using airborne Lidar data, stereophotogrammetry with WorldView 1 imagery, and Interferometric-Synthetic Aperture Radar (In-SAR) techniques with TanDEM-X imagery. The data cover the period 2011-10-14 to 2014-05-06.

    Links: Temporal Extent: Spatial Extent:
    Minimum Bounding Rectangle: -18.92 36.12 -18.63 36.34

    ORNL_CLOUD Short Name: CMS_Mangrove_Canopy_Ht_Zambezi_1357 Version ID: 1 Unique ID: C2343163771-ORNL_CLOUD

  • High Mountain Asia 8-meter DEM Mosaics Derived from Optical Imagery V001

    https://cmr.earthdata.nasa.gov/search/concepts/C1431539277-NSIDC_ECS.xml
    Description:

    This data set contains 8-meter Digital Elevation Model (DEM) mosaics of high mountain Asia glacier and snow regions generated from very-high-resolution (VHR) commercial satellite imagery.

    Links: Temporal Extent: Spatial Extent:
    Minimum Bounding Rectangle: 26 67 46 103

    NSIDC_ECS Short Name: HMA_DEM8m_MOS Version ID: 1 Unique ID: C1431539277-NSIDC_ECS

  • High Mountain Asia 8-meter DEMs Derived from Along-track Optical Imagery V001

    https://cmr.earthdata.nasa.gov/search/concepts/C1442092309-NSIDC_ECS.xml
    Description:

    This data set contains 8-meter Digital Elevation Models (DEMs) of high mountain Asia glacier and snow regions generated from very-high-resolution commercial stereoscopic satellite imagery.

    Links: Temporal Extent: Spatial Extent:
    Minimum Bounding Rectangle: 26 67 46 103

    NSIDC_ECS Short Name: HMA_DEM8m_AT Version ID: 1 Unique ID: C1442092309-NSIDC_ECS

  • High Mountain Asia 8-meter DEMs Derived from Cross-track Optical Imagery V001

    https://cmr.earthdata.nasa.gov/search/concepts/C1432250096-NSIDC_ECS.xml
    Description:

    This data set contains 8-meter Digital Elevation Model (DEM) mosaics of high mountain Asia glacier and snow regions generated from from very-high-resolution commercial stereo satellite imagery.

    Links: Temporal Extent: Spatial Extent:
    Minimum Bounding Rectangle: 26 67 46 103

    NSIDC_ECS Short Name: HMA_DEM8m_CT Version ID: 1 Unique ID: C1432250096-NSIDC_ECS

  • Land Cover Classification, Snow Cover, and Fractional Snow-Covered Area Maps from Maxar WorldView Satellite Images V001

    https://cmr.earthdata.nasa.gov/search/concepts/C2695676729-NSIDC_ECS.xml
    Description:

    This data set includes: (1) fine-scale snow and land cover maps from two mountainous study sites in the Western U.S., produced using machine-learning models trained to extract land cover data from WorldView-2 and WorldView-3 stereo panchromatic and multispectral images; (2) binary snow maps derived from the land cover maps; and (3) 30 m and 465 m fractional snow-covered area (fSCA) maps, produced via downsampling of the binary snow maps. The land cover classification maps feature between three and six classes common to mountainous regions and integral for accurate stereo snow depth mapping: illuminated snow, shaded snow, vegetation, exposed surfaces, surface water, and clouds. Also included are Landsat and MODSCAG fSCA map products. The source imagery for these data are the Maxar WorldView-2 and Maxar WorldView-3 Level-1B 8-band multispectral images, orthorectified and converted to top-of-atmosphere reflectance. These Level-1B images are available under the NGA NextView/EnhancedView license.

    Links: Temporal Extent: Spatial Extent:
    Minimum Bounding Rectangle: 48.269722 -121.179528 48.441717 -120.932614

    NSIDC_ECS Short Name: WV_LCC_SC_FSCA Version ID: 1 Unique ID: C2695676729-NSIDC_ECS