Processing Kernel for remote sensing data
examples_pkextract

Examples of pkextract

Using vector samples

Extract all points for all layers read in points.sqlite from input.tif. Create a new point vector dataset named extracted.sqlite, where each point will contain an attribute for the individual input bands in input.tif. Notice that the default vector format is Spatialite (.sqlite).

pkextract -i input.tif -s points.sqlite -o extracted.sqlite

Same example as above, but only extract the points for the layer in points.sqlite named "valid"

pkextract -i input.tif -s points.sqlite -ln valid -o extracted.sqlite

Extract points and write output in ESRI Shapefile format

pkextract -i input.tif -s points.shp -f "ESRI Shapefile" -o extracted.shp

Extract the standard deviation for each input band in a 3 by 3 window, centered around the points in the sample vector dataset points.sqlite. The output vector dataset will contain polygon features defined by the buffered points (3x3 window). Use the option -circ to define a circular buffer.

pkextract -i input.tif -s points.sqlite -o extracted.sqlite -r stdev -buf 3 -polygon

Extract all pixels from input.tif covered by the polygons in locations.sqlite. Each polygon can thus result in multiple point features with attributes for each input band. Write the extracted points to a point vector dataset training.sqlite.

pkextract -i input.tif -s polygons.sqlite -o training.sqlite -r point

Extract the first band from input.tif at the centroids of the polygons in vector dataset polygons.sqlite. Assign the extracted point value to a new attribute of the polygon and write to the vector dataset extracted.sqlite.

pkextract -i input.tif -b 0 -s polygons.sqlite -r centroid -o extracted.sqlite -polygon

Extract the mean values for the second band in input.tif covered by each polygon in polygons.sqlite. The mean values are written to a copy of the polygons in output vector dataset extracted.sqlite

pkextract -i input.tif -b 1 -s polygons.sqlite -r mean -o extracted.sqlite -polygon

Extract the majority class in each polygon for the input land cover map. The land cover map contains five valid classes, labeled 1-5. Other class values (e.g., labeled as 0) are not taken into account in the voting.

pkextract -i landcover.tif -s polygons.sqlite -r maxvote -o majority.sqlite -polygon -c 1 -c 2 -c 3 -c 4 -c 5

Using random and grid samples

Extract 100 sample units following a simple random sampling design. For each sample unit, the median value is extracted from the input raster dataset in a window of 3 by 3 pixels and written to an attribute of the output vector dataset. The output vector dataset contains polygon features defined by the windows centered at the random selected sample units.

pkextract -i input.tif -o random.sqlite -rand 100 -median -buf 3 -polygon

Extract points following a systematic grid with grid cell size of 100 m. Discard pixels that have a value 0 in the input raster dataset.

pkextract -i input.tif -o systematic.sqlite -grid 100 -srcnodata 0

Using raster samples

Typical use where pixels are extracted based on a land cover map (sample.tif). Extract all bands for a random sample of 10 percent of the pixels in the land cover map sample.tif where the land cover classes are either 1,2 or 3 (class values). Write output to the point vector dataset extracted.sqlite.

pkextract -i input.tif -s sample.tif -o extracted.sqlite -t 10 -c 1 -c 2 -c 3

Extract all bands for the first 5000 pixels encountered in sample.tif where pixels have a value equal to 1. Write output to point vector dataset extracted.sqlite.

pkextract -i input.tif -s sample.tif -o extracted.sqlite -t -5000 -c 1