HOWTO import SRTM elevation data: Difference between revisions
(+Import of SRTM tiles with reprojection on the fly) |
|||
Line 86: | Line 86: | ||
* M. Neteler, 2005. ''SRTM and VMAP0 data in OGR and GRASS.'' GRASS Newsletter, Vol.3, pp 2-6, June 2005. [ [http://grass.osgeo.org/newsletter/GRASSNews_vol3.pdf PDF] | [http://grass.osgeo.org/newsletter/GRASSNews_vol3_erratum.txt Erratum 1/2006 (txt)] ] | * M. Neteler, 2005. ''SRTM and VMAP0 data in OGR and GRASS.'' GRASS Newsletter, Vol.3, pp 2-6, June 2005. [ [http://grass.osgeo.org/newsletter/GRASSNews_vol3.pdf PDF] | [http://grass.osgeo.org/newsletter/GRASSNews_vol3_erratum.txt Erratum 1/2006 (txt)] ] | ||
Update 2014: better use the already void filled SRTM V3 data (get from NASA EarthExplorer, see above) | ''Update 2014'': better use the already void filled SRTM V3 1 arc-second for global coverage (~30 meters) data (get from NASA EarthExplorer, see above) | ||
== Import of SRTM tiles with reprojection on the fly == | |||
Instead of processing SRTM in a different location, it can be imported right away into the location of interest (e.g. UTM or whateer other projection) through reprojecting on the fly with bilinear resampling using {{cmd|r.import}}. | |||
Example for North Carolina sample dataset with newest 1 arc-second for global coverage (~30 meters). You get the SRTM V3 1 arc-second global data from EarthExplorer (http://earthexplorer.usgs.gov/). The collections are located under the Digital Elevation category. | |||
<source lang="bash"> | |||
# set computational region to e.g. Landsat channel 3: | |||
g.region raster=lsat7_2000_30 -p | |||
# Import with reprojection on the fly. Recommended parameters: | |||
# resample Resampling method to use for reprojection - bilinear | |||
# extent Output raster map extent | |||
# - region: extent of current region | |||
# resolution Resolution of output raster map | |||
# - region: current region resolution - limit to g.region setting from above | |||
r.import input=n35_w079_1arc_v3.tif output=srtmv3_resamp resample=bilinear \ | |||
extent=region resolution=region title="SRTM V3 resampled to Landsat7 resolution" | |||
# beautify colors: | |||
r.colors srtmv3_resamp color=elevation | |||
</source> | |||
== See also == | == See also == |
Revision as of 08:04, 16 May 2016
Background: Space Shuttle Radar Topography Mission
Available data
Space Shuttle Radar Topography Mission - several SRTM Data Products are available:
- Original data - SRTM 3 arc-seconds Non-Void Filled elevation data V1 (US: 1 arc-second (approximately 30 meters); outside the US at 3 arc-seconds (approximately 90 meters))
- SRTM Void Filled elevation data V2, filled the voids using interpolation algorithms in conjunction with other sources of elevation data (US: 1 arc-second (approximately 30 meters); outside the US at 3 arc-seconds (approximately 90 meters))
- SRTM 1 Arc-Second Global elevation data V3 offer worldwide coverage of void filled data at a resolution of 1 arc-second (30 meters) and provide open distribution of this high-resolution global data set.
- EarthExplorer can be used to search, preview, and download Shuttle Radar Topography Mission (SRTM) 1 Arc-Second Global data. The collections are located under the Digital Elevation category.
Download
- Older SRTM: http://www2.jpl.nasa.gov/srtm/ (SRTM V1 + SRTM V2 home page) | http://dds.cr.usgs.gov/srtm/ (SRTM V2 data download)
- https://lpdaac.usgs.gov/dataset_discovery/measures/measures_products_table NASA MEaSUREs Products (SRTM V3 and more)
- (FTP - therein SRTMGL3.003/2000.02.11/ which is a huge file list)
- Map based search: EarthExplorer can be used to search, preview, and download Shuttle Radar Topography Mission (SRTM) 1 Arc-Second Global data. The collections are located under the Digital Elevation category.
Note: GRASS GIS installations usually contain a location 'demolocation' which is in Latitude-Longitude, suitable for SRTM import.
Which SRTM tile to take?
SRTM tiles are of 1 degree by 1 degree size. The SRTM filename contains the coordinates which refer to the center of the lower left pixel (e.g., N51E010: lower left cell center at 10E, 51N). To identify a tile name, a grid can be easily visualized in the GRASS monitor:
d.grid size=1
Import of original SRTM tiles in HGT format
You can easily import many SRTM files in one step:
This menu function calls internally the SRTM driver of GDAL.
Importing multiple SRTM files via command line
Use the r.in.srtm module for automated import into a Latitude-Longitude location.
See:
- M.H. Bowman. Mapping freely available high resolution global elevation and vector data in GRASS. GRASS Newsletter, Vol.3, pp 7-10, June 2005. [ PDF ]
Import of CGIAR SRTM void-filled tiles
- SRTM 90 data in GeoTIFF format are available from http://srtm.csi.cgiar.org/. These come in 5 degree by 5 degree tiles. Horizontal resolution: 3 arc second (90 m at equator). Coverage: world. Import with r.in.gdal
Update: note that NASA EarthExplorer (see on top of this page) offers ~ 30m resolution SRTM V3 data which are void filled.
Import of multiple SRTM tiles in one step (mosaiking)
To simplify the import of multiple SRTM tiles, the tiles can be mosaicked first with gdalwarp:
Original SRTM tiles:
# unzip all
for i in *.hgt.zip ; do unzip $i ; done
# create mosaik (optionally reproject on the fly with -t_srs)
gdalwarp *.hgt srtm_mosaik.tif
# import
r.in.gdal input=srtm_mosaik output=srtm_mosaik
CGIAR SRTM tiles:
# create mosaik (optionally reproject on the fly with -t_srs)
gdalwarp *.tif srtm_mosaik.tif
# import
r.in.gdal input=srtm_mosaik output=srtm_mosaik
Void filling of original SRTM tiles
The module r.fillnulls can be used. See screenshot
See:
- M. Neteler, 2005. SRTM and VMAP0 data in OGR and GRASS. GRASS Newsletter, Vol.3, pp 2-6, June 2005. [ PDF | Erratum 1/2006 (txt) ]
Update 2014: better use the already void filled SRTM V3 1 arc-second for global coverage (~30 meters) data (get from NASA EarthExplorer, see above)
Import of SRTM tiles with reprojection on the fly
Instead of processing SRTM in a different location, it can be imported right away into the location of interest (e.g. UTM or whateer other projection) through reprojecting on the fly with bilinear resampling using r.import.
Example for North Carolina sample dataset with newest 1 arc-second for global coverage (~30 meters). You get the SRTM V3 1 arc-second global data from EarthExplorer (http://earthexplorer.usgs.gov/). The collections are located under the Digital Elevation category.
# set computational region to e.g. Landsat channel 3:
g.region raster=lsat7_2000_30 -p
# Import with reprojection on the fly. Recommended parameters:
# resample Resampling method to use for reprojection - bilinear
# extent Output raster map extent
# - region: extent of current region
# resolution Resolution of output raster map
# - region: current region resolution - limit to g.region setting from above
r.import input=n35_w079_1arc_v3.tif output=srtmv3_resamp resample=bilinear \
extent=region resolution=region title="SRTM V3 resampled to Landsat7 resolution"
# beautify colors:
r.colors srtmv3_resamp color=elevation
See also
- SRTM in Wikipedia