Provided by: grass-doc_7.0.3-1build1_all 
NAME
v.select - Selects features from vector map (A) by features from other vector map (B).
KEYWORDS
vector, geometry, spatial query
SYNOPSIS
v.select
v.select --help
v.select [-tcr] ainput=name [alayer=string] [atype=string[,string,...]] binput=name
[blayer=string] [btype=string[,string,...]] output=name operator=string
[relate=string] [--overwrite] [--help] [--verbose] [--quiet] [--ui]
Flags:
-t
Do not create attribute table
-c
Do not skip features without category
-r
Reverse selection
--overwrite
Allow output files to overwrite existing files
--help
Print usage summary
--verbose
Verbose module output
--quiet
Quiet module output
--ui
Force launching GUI dialog
Parameters:
ainput=name [required]
Name of input vector map
Input vector map from which to select features (A)
alayer=string
Layer number (vector map A)
Vector features can have category values in different layers. This number determines
which layer to use. When used with direct OGR access this is the layer name.
Default: 1
atype=string[,string,...]
Feature type (vector map A)
Input feature type
Options: point, line, boundary, centroid, area
Default: point,line,area
binput=name [required]
Name of input vector map
Query vector map (B)
blayer=string
Layer number (vector map B)
Vector features can have category values in different layers. This number determines
which layer to use. When used with direct OGR access this is the layer name.
Default: 1
btype=string[,string,...]
Feature type (vector map B)
Input feature type
Options: point, line, boundary, centroid, area
Default: point,line,area
output=name [required]
Name for output vector map
operator=string [required]
Operator defines required relation between features
A feature is written to output if the result of operation ’ainput operator binput’ is
true. An input feature is considered to be true, if category of given layer is
defined.
Options: overlap, equals, disjoint, intersects, touches, crosses, within, contains,
overlaps, relate
Default: overlap
overlap: features partially or completely overlap
equals: features are spatially equals (using GEOS)
disjoint: features do not spatially intersect (using GEOS)
intersects: features spatially intersect (using GEOS)
touches: features spatially touches (using GEOS)
crosses: features spatially crosses (using GEOS)
within: feature A is completely inside feature B (using GEOS)
contains: feature B is completely inside feature A (using GEOS)
overlaps: features spatially overlap (using GEOS)
relate: feature A is spatially related to feature B (using GEOS, requires ’relate’
option)
relate=string
Intersection Matrix Pattern used for ’relate’ operator
DESCRIPTION
v.select allows the user to select features from a vector map by features from another
one.
Supported operators (without GEOS; using GRASS’ own algorithm):
• overlap - features partially or completely overlap
Supported operators (internally using GEOS - Geometry Engine, Open Source):
• equals - features are spatially equals
• disjoint - features do not spatially intersect
• intersects - features spatially intersect
• touches - features spatially touches
• crosses - features spatially crosses
• within - feature A is completely inside feature B
• contains - feature B is completely inside feature A
• overlaps - features spatially overlap
• relate - feature A is spatially related to feature B
NOTES
Only features with category numbers will be considered. If required the v.category module
can be used to add them. Typically boundaries do not need to be given a category number,
as an area’s attributes are inherited from the centroid. Typically points, lines, and
centroids will always want to have a cat number. E.g. take a road which separates two
farms. It is ambiguous as to which farm an attribute that is attached to the road belongs
to. The boundary only needs a cat number if it will hold its own attributes, such as road
name or pavement form. A centroid in each paddock holds the information with respect to
ownership, area, etc.
EXAMPLES
Preparation of example data (North Carolina sample dataset):
# Create an grid for overlaying to ZIP code vector map
v.mkgrid map=boxgrid grid=10,10 position=coor \
coordinates=583600,201500 box=5000,5000
# set region to ZIP codes and boxgrid vector maps
g.region vector=zipcodes_wake,boxgrid -p res=100 -a
# enlarge region a bit for "white border" around map in monitor
g.region n=n+1000 s=s-1000 w=w-1000 e=e+1000 -p
d.mon wx0
OVERLAP: features partially or completely overlap (using GRASS)
Select grid boxes (North Carolina sample dataset):
d.vect map=zipcodes_wake fill_color=0:128:0
d.vect map=boxgrid fill_color=85:130:176
v.select ainput=boxgrid binput=zipcodes_wake output=v_select_OVERLAP operator=overlap
d.vect map=v_select_OVERLAP
d.vect map=zipcodes_wake type=boundary color=50:50:50
v.select with OVERLAP operator: selected grid boxes shown in grey
OVERLAPS features spatially overlap (using GEOS)
Select grid boxes (North Carolina sample dataset):
d.vect map=zipcodes_wake fill_color=0:128:0
d.vect map=boxgrid fill_color=85:130:176
v.select ainput=boxgrid binput=zipcodes_wake output=v_select_OVERLAPS operator=overlaps
d.vect map=v_select_OVERLAPS
d.vect map=zipcodes_wake type=boundary color=50:50:50
v.select with OVERLAPS operator: selected grid boxes shown in grey
DISJOINT: features do not spatially intersect (using GEOS)
Select grid boxes (North Carolina sample dataset):
d.vect map=zipcodes_wake fill_color=0:128:0
d.vect map=boxgrid fill_color=85:130:176
v.select ainput=boxgrid binput=zipcodes_wake output=v_select_DISJOINT operator=disjoint
d.vect map=v_select_DISJOINT
d.vect map=zipcodes_wake type=boundary color=50:50:50
v.select with DISJOINT operator: selected grid boxes shown in grey
EQUALS: features are spatially equals (using GEOS)
Select zipcode polygon (North Carolina sample dataset):
d.vect map=zipcodes_wake fill_color=0:128:0
v.extract input=zipcodes_wake where=ZIPCODE_ID=35 output=zipcodeID35
v.select ainput=zipcodes_wake binput=zipcodeID35 output=v_select_EQUALS operator=equals
d.vect map=v_select_EQUALS
d.vect map=zipcodes_wake type=boundary color=50:50:50
v.select with EQUALS operator: selected grid boxes shown in grey
INTERSECTS: features spatially intersect (using GEOS)
Select zipcode polygons (North Carolina sample dataset):
d.vect map=zipcodes_wake fill_color=0:128:0
d.vect map=boxgrid fill_color=85:130:176
v.select ainput=zipcodes_wake binput=boxgrid output=v_select_INTERSECTS operator=intersects
d.vect map=v_select_INTERSECTS
d.vect map=boxgrid type=boundary color=50:50:50
v.select with INTERSECTS operator: selected grid boxes shown in grey
TOUCHES: features spatially touches (using GEOS)
Select polygons (North Carolina sample dataset):
d.vect map=zipcodes_wake fill_color=0:128:0
d.vect map=zipcodeID35 fill_color=85:130:176
v.select ainput=zipcodes_wake binput=zipcodeID35 output=v_select_TOUCHES operator=touches
d.vect map=v_select_TOUCHES
d.vect map=zipcodes_wake type=boundary color=50:50:50
v.select with TOUCHES operator: selected polygons shown in grey (blue: input polygon)
CROSSES: features spatially crosses (using GEOS)
Select zipcode polygons by lines (North Carolina sample dataset):
d.vect map=zipcodes_wake fill_color=0:128:0
d.vect map=busroute1 color=200:27:27 width=3
v.select ainput=zipcodes_wake binput=busroute1 output=v_select_CROSSES operator=crosses
d.vect map=v_select_CROSSES
d.vect map=zipcodes_wake type=boundary color=50:50:50
d.vect map=busroute1 color=200:27:27 width=3
v.select with CROSSES operator: selected polygons shown in grey (red: input lines)
WITHIN feature A is completely inside feature B (using GEOS)
Select zipcode polygons (North Carolina sample dataset):
d.vect map=zipcodes_wake fill_color=0:128:0
d.vect map=boundary_county fill_color=85:130:176
v.select ainput=zipcodes_wake binput=boundary_county output=v_select_WITHIN operator=within
d.vect map=v_select_WITHIN
v.select with WITHIN operator: selected polygons shown in grey (blue: input polygons)
CONTAINS feature B is completely inside feature A (using GEOS)
Select zipcode polygon (North Carolina sample dataset):
CONTAINS with polygons
d.vect map=zipcodes_wake fill_color=0:128:0
d.vect map=zipcodeID35 fill_color=85:130:176
v.select ainput=zipcodes_wake binput=zipcodeID35 \
output=v_select_CONTAINS_pol operator=contains
d.vect map=v_select_CONTAINS
v.select with CONTAINS operator: selected polygon shown in grey (blue: input polygon, not
visible)
CONTAINS with points
d.vect map=zipcodes_wake fill_color=0:128:0
d.vect map=hospitals fill_color=195:31:31 icon=basic/cross3 size=10
v.select ainput=zipcodes_wake binput=hospitals \
output=v_select_CONTAINS_pnts operator=contains
d.vect map=v_select_CONTAINS_pnts
d.vect map=hospitals fill_color=195:31:31 icon=basic/cross3 size=10
v.select with CONTAINS operator: selected polygons shown in grey (red: input points)
RELATE feature A is spatially related to feature B (using GEOS)
This operator additionally requires the relate parameter (in other GIS called
’ST_Relate’). This operator allows calculating the Dimensionally Extended
nine-Intersection Model (DE-9IM). In the following one example: Select polygon with
’TOUCHES’ operator (North Carolina sample dataset):
d.vect map=zipcodes_wake fill_color=0:128:0
d.vect map=zipcodeID35 fill_color=85:130:176
v.select ainput=zipcodeID35 binput=zipcodes_wake \
output=v_select_TOUCHES_relate operator=relate relate=’T********’
d.vect map=v_select_TOUCHES
The result of relate=’T********’ is the same as seen above in the example ’TOUCHES’. See
the DE-9IM page for related operators and their definition.
Extraction of points falling into a polygon
Extract fire stations (points) falling into urban area (polygon) - North Carolina data set
(point in polygon test):
v.select ainput=firestations binput=urbanarea output=urban_firestations \
operator=overlap
Extraction of lines overlapping with a polygon
Extract railroad lines from zip code map overlapping with the urban area (line in polygon
test):
v.select ainput=railroads binput=urbanarea \
output=railroads_in_urbanarea operator=overlap
Extraction of areas overlapping with a line
Extract those areas from zip code map which overlap with railroads (polygon on line test):
# first add a tiny buffer around railroad lines:
v.buffer input=railroads output=railroads_buf20m \
distance=20
v.select ainput=zipcodes_wake binput=railroads_buf20m \
output=zipcodes_wake_railroads operator=overlap
SEE ALSO
v.category, v.overlay, v.extract
GRASS SQL interface
GEOS - Geometry Engine, Open Source
AUTHORS
Radim Blazek
GEOS support by Martin Landa, Czech Technical University in Prague, Czech Republic
ZIP code examples by Carol X. Garzon-Lopez, Trento, Italy
Last changed: $Date: 2015-10-22 00:41:33 +0200 (Thu, 22 Oct 2015) $
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