Outcrop geology was obtained directly from the following 1:250 000 map sheets: Marble Bar, Nullagine, Port Hedland and Yarrie. This dataset consists of both raster and vector data. Raster data which is unsigned 8 bit integer, can be viewed in Arc/Info, ArcView, MapInfo, ERMapper, ERViewer and ArcExplorer. Raster data which is 4 byte real data, can only be viewed and manipulated with an image processing package such as ERMapper.

This entry provides access to surficial geology maps that have been published by the Geological survey of Canada. Two series of maps are available: "A Series" maps, published from 1909 to 2010 and "Canadian Geoscience Maps", published since 2010. Three types of CGM-series maps are available: 1)Surficial Geology: based on expert-knowledge full air photo interpretation (may include interpretive satellite imagery, Digital Elevation Models (DEM)), incorporating field data and ground truthing resulting from extensive, systematic fieldwork across the entire map area. Air photo interpretation includes map unit/deposit genesis, texture, thickness, structure, morphology, depositional or erosional environment, ice flow or meltwater direction, age/cross-cutting relationships, landscape evolution and associated geological features, complemented by additional overlay modifiers, points and linear features, selected from over 275 different geological elements in the Surficial Data Model. Wherever possible, legacy data is also added to the map. 2)Reconnaissance Surficial Geology: based on expert-knowledge full air photo interpretation (may include interpretive satellite imagery, DEMs), with limited or no fieldwork. Air photo interpretation includes map unit/deposit genesis, texture, thickness, structure, morphology, depositional or erosional environment, ice flow or meltwater direction, age/cross-cutting relationships, landscape evolution and associated geological features, complemented by additional overlay modifiers, points and linear features, selected from over 275 different geological elements in the Surficial Data Model. Wherever possible, legacy data is also added to the map. 3)Predictive Surficial Geology: derived from one or more methods of remote predictive mapping (RPM) using different satellite imagery, spectral characteristics of vegetation and surface moisture, machine processing, algorithms etc., DEMs, where raster data are converted to vector, with some expert-knowledge air photo interpretation (training areas or post-verification areas), varying degrees of non-systematic fieldwork, and the addition of any legacy data available. Each map is based on a version of the Geological Survey of Canada's Surficial Data Model (https://doi.org/10.4095/315021), thus providing an easily accessible national surficial geological framework and context in a standardized format to all users. "A series" maps were introduced in 1909 and replaced by CGM maps in 2010. The symbols and vocabulary used on those maps was not as standardized as they are in the CGM maps. Some "A series" maps were converted into, or redone, as CGM maps, Both versions are available whenever that is the case. In addition to CGM and "A series" maps, some surficial geology maps are published in the Open File series. Those maps are not displayed in this entry, but can be found and accessed using the NRCan publications website, GEOSCAN:(https://geoscan.nrcan.gc.ca).

The Geospatial Data Gateway (GDG) provides access to a map library of over 100 high resolution vector and raster layers in the Geospatial Data Warehouse. It is the one stop source for environmental and natural resource data, available anytime, from anywhere. It allows a user to choose an area of interest, browse and select data, customize the format, then download or have it shipped on media. The map layers include data on: Public Land Survey System (PLSS), Census data, demographic statistics, precipitation, temperature, disaster events, conservation easements, elevation, geographic names, geology, government units, hydrography, hydrologic units, land use and land cover, map indexes, ortho imagery, soils, topographic images, and streets and roads. This service is made available through a close partnership between the three Service Center Agencies (SCA): Natural Resources Conservation Service (NRCS), Farm Service Agency (FSA), and Rural Development (RD). Resources in this dataset:Resource Title: Geospatial Data Gateway. File Name: Web Page, url: https://gdg.sc.egov.usda.gov This is the main page for the GDG that includes several links to view, download, or order various datasets. Find additional status maps that indicate the location of data available for each map layer in the Geospatial Data Gateway at https://gdg.sc.egov.usda.gov/GDGHome_StatusMaps.aspx

Dataset for: Bedding scale correlation on Mars in western Arabia Terra

A.M. Annex et al.

Data Product Overview

This repository contains all source data for the publication. Below is a description of each general data product type, software that can load the data, and a list of the file names along with the short description of the data product.

HiRISE Digital Elevation Models (DEMs).

HiRISE DEMs produced using the Ames Stereo Pipeline are in geotiff format ending with ‘*X_0_DEM-adj.tif’, the “X” prefix denotes the spatial resolution of the data product in meters. Geotiff files are able to be read by free GIS software like QGIS.

HiRISE map-projected imagery (DRGs).

Map-projected HiRISE images produced using the Ames Stereo Pipeline are in geotiff format ending with ‘*0_Y_DRG-cog.tif’, the “Y” prefix denotes the spatial resolution of the data product in centimeters. Geotiff files are able to be read by free GIS software like QGIS. The DRG files are formatted as COG-geotiffs for enhanced compression and ease of use.

3D Topography files (.ply).

Traingular Mesh versions of the HiRISE/CTX topography data used for 3D figures in “.ply” format. Meshes are greatly geometrically simplified from source files. Topography files can be loaded in a variety of open source tools like ParaView and Meshlab. Textures can be applied using embedded texture coordinates.

3D Geological Model outputs (.vtk)

VTK 3D file format files of model output over the spatial domain of each study site. VTK files can be loaded by ParaView open source software. The “block” files contain the model evaluation over a regular grid over the model extent. The “surfaces” files contain just the bedding surfaces as interpolated from the “block” files using the marching cubes algorithm.

Geological Model geologic maps (geologic_map.tif).

Geologic maps from geological models are standard geotiffs readable by conventional GIS software. The maximum value for each geologic map is the “no-data” value for the map. Geologic maps are calculated at a lower resolution than the topography data for storage efficiency.

Beds Geopackage File (.gpkg).

Geopackage vector data file containing all mapped layers and associated metadata including dip corrected bed thickness as well as WKB encoded 3D linestrings representing the sampled topography data to which the bedding orientations were fit. Geopackage files can be read using GIS software like QGIS and ArcGIS as well as the OGR/GDAL suite. A full description of each column in the file is provided below.

    Column
    Type
    Description




    uuid
    String
    unique identifier


    stratum_order
    Real
    0-indexed bed order


    section
    Real
    section number


    layer_id
    Real
    bed number/index


    layer_id_bk
    Real
    unused backup bed number/index


    source_raster
    String
    dem file path used


    raster
    String
    dem file name


    gsd
    Real
    ground sampling distant for dem


    wkn
    String
    well known name for dem


    rtype
    String
    raster type


    minx
    Real
    minimum x position of trace in dem crs


    miny
    Real
    minimum y position of trace in dem crs


    maxx
    Real
    maximum x position of trace in dem crs


    maxy
    Real
    maximum y position of trace in dem crs


    method
    String
    internal interpolation method


    sl
    Real
    slope in degrees


    az
    Real
    azimuth in degrees


    error
    Real
    maximum error ellipse angle


    stdr
    Real
    standard deviation of the residuals


    semr
    Real
    standard error of the residuals


    X
    Real
    mean x position in CRS


    Y
    Real
    mean y position in CRS


    Z
    Real
    mean z position in CRS


    b1
    Real
    plane coefficient 1


    b2
    Real
    plane coefficient 2


    b3
    Real
    plane coefficient 3


    b1_se
    Real
    standard error plane coefficient 1


    b2_se
    Real
    standard error plane coefficient 2


    b3_se
    Real
    standard error plane coefficient 3


    b1_ci_low
    Real
    plane coefficient 1 95% confidence interval low


    b1_ci_high
    Real
    plane coefficient 1 95% confidence interval high


    b2_ci_low
    Real
    plane coefficient 2 95% confidence interval low


    b2_ci_high
    Real
    plane coefficient 2 95% confidence interval high


    b3_ci_low
    Real
    plane coefficient 3 95% confidence interval low


    b3_ci_high
    Real
    plane coefficient 3 95% confidence interval high


    pca_ev_1
    Real
    pca explained variance ratio pc 1


    pca_ev_2
    Real
    pca explained variance ratio pc 2


    pca_ev_3
    Real
    pca explained variance ratio pc 3


    condition_number
    Real
    condition number for regression


    n
    Integer64
    number of data points used in regression


    rls
    Integer(Boolean)
    unused flag


    demeaned_regressions
    Integer(Boolean)
    centering indicator


    meansl
    Real
    mean section slope


    meanaz
    Real
    mean section azimuth


    angular_error
    Real
    angular error for section


    mB_1
    Real
    mean plane coefficient 1 for section


    mB_2
    Real
    mean plane coefficient 2 for section


    mB_3
    Real
    mean plane coefficient 3 for section


    R
    Real
    mean plane normal orientation vector magnitude


    num_valid
    Integer64
    number of valid planes in section


    meanc
    Real
    mean stratigraphic position


    medianc
    Real
    median stratigraphic position


    stdc
    Real
    standard deviation of stratigraphic index


    stec
    Real
    standard error of stratigraphic index


    was_monotonic_increasing_layer_id
    Integer(Boolean)
    monotonic layer_id after projection to stratigraphic index


    was_monotonic_increasing_meanc
    Integer(Boolean)
    monotonic meanc after projection to stratigraphic index


    was_monotonic_increasing_z
    Integer(Boolean)
    monotonic z increasing after projection to stratigraphic index


    meanc_l3sigma_std
    Real
    lower 3-sigma meanc standard deviation


    meanc_u3sigma_std
    Real
    upper 3-sigma meanc standard deviation


    meanc_l2sigma_sem
    Real
    lower 3-sigma meanc standard error


    meanc_u2sigma_sem
    Real
    upper 3-sigma meanc standard error


    thickness
    Real
    difference in meanc


    thickness_fromz
    Real
    difference in Z value


    dip_cor
    Real
    dip correction


    dc_thick
    Real
    thickness after dip correction


    dc_thick_fromz
    Real
    z thickness after dip correction


    dc_thick_dev
    Integer(Boolean)
    dc_thick <= total mean dc_thick


    dc_thick_fromz_dev
    Integer(Boolean)
    dc_thick <= total mean dc_thick_fromz


    thickness_fromz_dev
    Integer(Boolean)
    dc_thick <= total mean thickness_fromz


    dc_thick_dev_bg
    Integer(Boolean)
    dc_thick <= section mean dc_thick


    dc_thick_fromz_dev_bg
    Integer(Boolean)
    dc_thick <= section mean dc_thick_fromz


    thickness_fromz_dev_bg
    Integer(Boolean)
    dc_thick <= section mean thickness_fromz


    slr
    Real
    slope in radians


    azr
    Real
    azimuth in radians


    meanslr
    Real
    mean slope in radians


    meanazr
    Real
    mean azimuth in radians


    angular_error_r
    Real
    angular error of section in radians


    pca_ev_1_ok
    Integer(Boolean)
    pca_ev_1 < 99.5%


    pca_ev_2_3_ratio
    Real
    pca_ev_2/pca_ev_3


    pca_ev_2_3_ratio_ok
    Integer(Boolean)
    pca_ev_2_3_ratio > 15


    xyz_wkb_hex
    String
    hex encoded wkb geometry for all points used in regression

Geological Model input files (.gpkg).

Four geopackage (.gpkg) files represent the input dataset for the geological models, one per study site as specified in the name of the file. The files contain most of the columns described above in the Beds geopackage file, with the following additional columns. The final seven columns (azimuth, dip, polarity, formation, X, Y, Z) constituting the actual parameters used by the geological model (GemPy).

    Column
    Type
    Description




    azimuth_mean
    String
    Mean section dip azimuth 


    azimuth_indi
    Real
    Individual bed azimuth


    azimuth
    Real
    Azimuth of trace used by the geological model


    dip
    Real
    Dip for the trace used by the geological mode


    polarity
    Real
    Polarity of the dip vector normal vector 


    formation
    String
    String representation of layer_id required for GemPy models


    X
    Real
    X position in the CRS of the sampled point on the trace


    Y
    Real
    Y position in the CRS of the sampled point on the trace


    Z
    Real
    Z position in the CRS of the sampled point on the trace

Stratigraphic Column Files (.gpkg).

Stratigraphic columns computed from the Geological Models come in three kinds of Geopackage vector files indicated by the postfixes _sc, rbsc, and rbssc. File names include the wkn site name.

sc (_sc.gpkg).

Geopackage vector data file containing measured bed thicknesses from Geological Model joined with corresponding Beds Geopackage file, subsetted partially. The columns largely overlap with the the list above for the Beds Geopackage but with the following additions

    Column
    Type
    Description




    X
    Real
    X position of thickness measurement


    Y
    Real
    Y position of thickness measurement


    Z
    Real
    Z position of thickness measurement


    formation
    String
    Model required string representation of bed index


    bed thickness (m)
    Real
    difference of bed elevations


    azimuths
    Real
    azimuth as measured from model in degrees


    dip_degrees
    Real
    dip as measured from model in

The high resolution sensor HRV operates in two modes: panchromatic (0.51-0.73 micrometer) with 10 meter resolution and multispectral (0.50-0.59, 0.61-0.68, and 0.79-0.89 micrometer) with 20 meter resolution. Each scene is normally 60x60 km.

 More than 700 000 SPOT images (over 100 000 per year) from all parts of the
 world are archived at SSC Satellitbild. About 40% of the total number is from
 the onboard recorder of the satellite.
 The ratio between multispectral and panchromatic data is 40/60.
 Approximately 3000 scenes per year are processed and equally many films
 produced.

 The different processing levels include various radiometric and geometric
 corrections, precision correction using group control points, with or without
 digital terrain model, and output in any standard map projection.

 The data is produced as digital data or as a variety of photographic products.
 A unique product at Satellitbild is the Satellite Image Map which, as a
 complement to the scene format, is imagery in map sheet format. Another product
 is digital terrain models from SPOT data.

 The most common digital distribution media is magnetic tape at 1600 or 6250 bpi.
 The production system is able to read and produce all of the most frequently
 used formats for satellite imagery, i.e. CRIS-format, SPOT IMAGE-format,
 LTWG-format, FAST-format, ERDAS-format, etc.

 For input to ARC/INFO GIS system, the GISIMAGE format is available. GISIMAGE
 is an ERDAS image format delivered on 1/4 inch cassettes or CCTs for input
 on both SUN and VAX stations. The GISIMAGE is ideal as a background image for
 integrated raster/vector updating of map information.

This map contains a group of vegetation maps at three scales in the vicinity of the Toolik Field Station, Alaska. The maps are intended to support research at the field station. The front side of the map contains a vegetation map and ancillary maps of a 751 km^2 region surrounding the upper Kuparuk River watershed, including the Toolik lake and the Imnavait Creek research areas, as well as portions of the Dalton Highway and Trans-Alaska Pipeline from the northern end of Galbraith Lake to Slope Mountain. The back side of the map shows more detailed vegetation maps of the 20-km^2 research area centered on Toolik Lake and a 1.2-km^2 intensive research grid on the south side of Toolik Lake. All the maps are part of a hierarchical geographic information system (GIS). They are vector (shp) files, displaying the vegetation (14 units), the glacial geology (20 units), and surficial geomorphology (11 units) (legend details: http://www.arcticatlas.org/maps/themes/uk/index). In addition there are raster images of the same extent, based on satellite data from SPOT (false-color infrared (CIR) and NDVI) and Landsat (NDVI trend 1985-2007). "Back to" Upper Kuparuk River Region Vegetation (Walker & Maier 2008) Go to Website Link :: Toolik Arctic Geobotanical Atlas below for details on legend units, photos of map units and plant species, glossary, bibliography and links to ground data. Map Themes: Elevation, Glacial Geology, Hydrology, Landform, Landsat NDVI trend 1985-2007, SPOT CIR, SPOT NDVI, Surficial Geology, Surficial Geomorphology References Walker, D. A. and H. A. Maier. 2008. Vegetation in the vicinity of the Toolik Field Station, Alaska. Institute of Arctic Biology, University of Alaska Fairbanks, Biological Papers of the University of Alaska #28.

Topographic sheets (t-sheets) produced by the National Ocean Service (NOS) during the 1800s provide the position of past shorelines. The shoreline data can be vectorized into a geographic information system (GIS) and compared to modern shoreline data to calculate estimates of long-term shoreline rates of change. Many t-sheets were scanned and digitized by the National Oceanic and Atmospheric Administration (NOAA) and are available on the NOAA Shoreline website (https://shoreline.noaa.gov/data/datasheets/t-sheets.html). However, some t-sheets were not scanned by NOAA and are only available via the National Archives and Records Administration (NARA). The data included within this data release were previously unavailable or not published in digital format. These data were produced to provide a more comprehensive record of shoreline position for Fire Island and Great South Bay, New York, to aid geologic and coastal hazards studies. This data release includes previously unavailable georeferenced t-sheets and digital vector shorelines for the Fire Island and Great South Bay, New York, coastline from 1834, 1838, and 1874/1875. The original t-sheets were scanned by the NARA-authorized vendor and sent to the Unites States Geological Survey St. Petersburg Coastal and Marine Science Center (USGS SPCMSC) as non-georeferenced digital raster files. Upon arrival at the SPCMSC, USGS staff performed the following procedures: rasters were georeferenced, projected to a modern datum, and shorelines were digitized to create a vector polyline depicting the historical shoreline position. The t-sheets included in this data release are: 1) T-479a, T-479b, T-1 (Parts 2 and 3) (1834); 2) T-58 (Parts 1 and 2) (1838); 3) T-1374a, T-1374b, T-1375a, T-1375b (1874); and 4) T-1402 (1875). All shorelines, including the ocean-facing barrier island shoreline, back-barrier island shoreline, mainland and islands were digitized. Please read the full metadata for details on data collection, dataset variables, and data quality.