Load and color DEMs - PowerPoint PPT Presentation

1 / 11
About This Presentation
Title:

Load and color DEMs

Description:

... Visualization and Interpretation of lidar-derived Digital Elevation Models. ... – PowerPoint PPT presentation

Number of Views:32
Avg rating:3.0/5.0
Slides: 12
Provided by: ianm2
Category:
Tags: color | dems | derived | load

less

Transcript and Presenter's Notes

Title: Load and color DEMs


1
  • Load and color DEMs
  • Hillshade DEMs
  • Slopeshade DEMs
  • Combine shade and color
  • Differencing, canopy and serial data
  • Generating Contours
  • Point and Profile queries
  • Ground Point Density

DOGAMI lidar data sample from Carpenterville on
Southern Oregon Coast. Bare earth and highest hit
(or first return, or reflective surface) 3 ft
DEMs, from 8 pulse/m2 leaf on data.
2
Load and color DEM
  • Add datagt Bare_Earth_DEM and Highest_hit_DEM
  • Native scheme is grayscale with low values dark
  • Right click layergt propertiesgt symbology
  • Select your preferred color scheme
  • Note differences between the two DEMs
  • DEM image alone is not a particularly useful
    visualization

3
Hillshade visualization
  • Arc Toolboxgt 3D Analystgt Raster Surfacegt
    Hillshade
  • Input, Bare_Earth_DEM, set output to
    be_hs_315.img, accept defaults and run
  • Input Bare_Earth_DEM, set output to
    be_hs_225.img, set azimuth to 225 and run
  • Note difference in hillshades, some illumination
    angles simply dont work.
  • Experiment with highest_hit_DEM, Azimuth,
    Altitude, Z factor, shadows

4
Slopeshade Visualization
  • Arc Toolboxgt 3D analystgt Raster surfacegt slope
  • Input Bare_earth_DEM, set output to be_slope.img,
    run
  • Default color scheme is poison-dart frog
  • Right click layergt propertiesgt symbologygt choose
    stretched, invert, standard deviations and set n
    to 5
  • Slopeshade map is universal hillshade.
  • Shading curve can be adjusted to illuminate
    features in the very steep or very gentle ends of
    the slope range, under Symbology, click
    histograms and play with nodes on curve to
    reshape
  • Experiment with Highest_hit_DEM

5
Combine layers
  • Turn off all layers
  • Load orthoimage
  • Right click layergt propertiesgt displaygt set
    transparency to 50
  • Turn on highest hit hillshade or slopeshade
  • Turn off all layers except beslope and
    Bare_Earth_DEM. Drag beslope below
    Bare_Earth_DEM, set Bare_Earth_DEM display to 50
    transparency. This combination is very useful
    for mapping geologic and geomorphic features
  • Play with combinations of layers!
  • 70 orthoimage over 70 highest hit hillshade
    over bare earth slopeshade makes a nice basemap.

6
DifferencingCanopy Height
  • Turn off all layers
  • Load Highest_Hit_DEM and Bare_Earth_DEM
  • Arc Toolboxgt 3D Analystgt Raster Mathgt Minus
  • Use Highest_Hit_DEM for input 1, Bare_Earth_DEM
    for input 2, canopy.img for output, run
  • Right click canopy layergt propertiesgt displaygt
    set transparency to 50 then symbology and choose
    your favorite color scheme
  • Turn on highest hit hillshade or slopeshade and
    position under canopy.
  • Combined image shows the height of vegetation,
    structures, can you find the transmission lines?
  • Note negative values in canopy. Highest hit and
    bare earth surfaces are made from different
    collections of points.

7
DifferencingSerial Data
  • Turn off all layers
  • Load be_leaf_off and be_leaf_on, select one and
    click zoom to layer
  • Arc Toolboxgt 3D Analystgt Raster Mathgt Minus
  • Use be_leaf_off for input 1, be_leaf_on for input
    2, serial.img for output, run
  • Right click serial layergt propertiesgt displaygt
    set transparency to 50 then symbologygt
    classified, say yes to create histogram, click on
    classify, and set values to -3, -1, 1 and 3.
    Click ok to return to main symbology tab, double
    click patches to select color, set lowest purple,
    next blue, next (-1 to 1) to no color next to
    orange, highest to red.
  • Load leaf_off_beslope and place it under serial
  • Image now shows areas of erosion as orange and
    red, deposition as blue and purple. You should be
    able to find two landslides and three debris flow
    scars.
  • Widespread noise is due to differences in ground
    models under heavy vegetation
  • Serial comparisons require high quality data.

8
Contours
  • Arc Toolboxgt 3D Analystgt Raster Surfacegt
    Contour
  • Input be_leaf_off.img, accept default output, set
    contour interval to 1, run.
  • Resultant 1m contours provide additional detail
    on shape of landscape, particularly in areas of
    low slope.
  • Contours can greatly slow down redraw, minimize
    this by using contour with barriers and selecting
    a 1km grid file as the barrier.
  • Contours from lidar can be very rough, reflecting
    the high resolution of the DEM and the natural
    roughness of the surface. For nicer looking
    contours without significant loss of accuracy,
    use Arc Toolboxgt Spatial Analystgt Neighborhoodgt
    Focal Statistics to smooth DEM before contouring.

9
Query Lidar, Point and profile
  • Turn off all layers
  • Turn on slope_be and canopy, select one and click
    zoom to layer
  • Click on info tool, select all visible layers,
    click on point of interest to see point location
    and elevation values
  • From main menu select Viewgt Toolbarsgt and check
    3D Analyst
  • In 3D Analyst toolbar, click layer list control
    and select canopy
  • From 3D Analyst toolbar select interpolate line,
    draw line across area of interest.
  • Initial interpolate line will be slow while grid
    is indexed.
  • When line appears, select create profile graph
    from 3D Analyst toolbar
  • Profile will appear in window, which can be
    stretched in X or Y.
  • Right click profile to see print and export
    options.

10
Ground Point Density
  • It is important to understand how good the data
    behind your DEM is, and ground point density is
    critical
  • Add the file 42124B3317.GPD, right click the
    layer and select zoom to layer
  • This is a vendor-supplied ground point density
    grid, white areas have gt 1 ground point per 4m2,
    black areas less.
  • Zoom to a large area of black, and then turn off
    the GPD grid, leave on only the be_slope grid,
    note the obvious TIN triangle outlines in the
    grid. This is a simple graphic indicator of
    ground point density. Use the measurement tool
    to measure some of the TIN side lengths, some are
    quite long.
  • To make your own groundpoint density grid Arc
    Toolboxgt Conversiongt From Filegt LAS to
    Multipoint, choose 44124B3317_ground as input,
    ground_points as output, point spacing of 2 and
    run.
  • Select Arc Toolboxgt Conversion Toolsgt To Raster
    gt Point to Raster, use ground_points as input,
    pointcount as value field, accept default output,
    set cell assignment type to COUNT, cellsize to 15
    and run.
  • Assign a color scheme to the resulting raster,
    make it 50 transparent and drape over the
    be_slope layer. Examine how the DEM looks in
    areas of low point density.

11
Additional Resources
  • http//blogs.esri.com/Dev/blogs/geoprocessing/arch
    ive/2008/11/06/Lidar-Solutions-in-ArcGIS_5F00_part
    -1_3A00_-Assessing-Lidar-Coverage-and-Sample-Densi
    ty.aspx
  • http//cws.unavco.org8080/cws/learn/uscs/2008/200
    8Lidar/handouts/GeoEarthScopeDataTutorialApril08.p
    df
  • lthttp//cws.unavco.org8080/cws/learn/uscs/2008/20
    08Lidar/handouts/GeoEarthScopeDataTutorialApril08.
    pdfgt
  • http//cws.unavco.org8080/cws/learn/uscs/2008/20
    08Lidar/handouts/GLW_and_ArcMap.pdf
    lthttp//cws.unavco.org8080/cws/learn/uscs/2008/20
    08Lidar/handouts/GLW_and_ArcMap.pdfgt
  • http//arrowsmith410-598.asu.edu/Lectures/Lecture1
    4/ lthttp//arrowsmith410-598.asu.edu/Lectures/Lect
    ure14/gt
  • http//arrowsmith410-598.asu.edu/Lectures/Lecture1
    5/ lthttp//arrowsmith410-598.asu.edu/Lectures/Lect
    ure15/gt
Write a Comment
User Comments (0)
About PowerShow.com