.TH v.net.alloc 1grass "" "GRASS 6.4.2" "Grass User's Manual"
.SH NAME
\fI\fBv.net.alloc\fR\fR  - Allocate subnets for nearest centres (direction from centre).
.br
Centre node must be opened (costs >= 0). Costs of centre node are used in calculation
.SH KEYWORDS
vector, network, allocation
.SH SYNOPSIS
\fBv.net.alloc\fR
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\fBv.net.alloc help\fR
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\fBv.net.alloc\fR [-\fBg\fR] \fBinput\fR=\fIname\fR \fBoutput\fR=\fIname\fR  [\fBtype\fR=\fIstring\fR[,\fIstring\fR,...]]   [\fBalayer\fR=\fIinteger\fR]   [\fBnlayer\fR=\fIinteger\fR]   [\fBafcolumn\fR=\fIstring\fR]   [\fBabcolumn\fR=\fIstring\fR]   [\fBncolumn\fR=\fIstring\fR]  \fBccats\fR=\fIrange\fR  [--\fBoverwrite\fR]  [--\fBverbose\fR]  [--\fBquiet\fR] 
.SS Flags:
.IP "\fB-g\fR" 4m
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Use geodesic calculation for longitude-latitude locations
.IP "\fB--overwrite\fR" 4m
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Allow output files to overwrite existing files
.IP "\fB--verbose\fR" 4m
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Verbose module output
.IP "\fB--quiet\fR" 4m
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Quiet module output
.PP
.SS Parameters:
.IP "\fBinput\fR=\fIname\fR" 4m
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Name of input vector map
.IP "\fBoutput\fR=\fIname\fR" 4m
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Name for output vector map
.IP "\fBtype\fR=\fIstring[,\fIstring\fR,...]\fR" 4m
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Arc type
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Options: \fIline,boundary\fR
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Default: \fIline,boundary\fR
.IP "\fBalayer\fR=\fIinteger\fR" 4m
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Layer number
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Arc layer
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Default: \fI1\fR
.IP "\fBnlayer\fR=\fIinteger\fR" 4m
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Layer number
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Node layer
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Default: \fI2\fR
.IP "\fBafcolumn\fR=\fIstring\fR" 4m
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Arc forward/both direction(s) cost column (number)
.IP "\fBabcolumn\fR=\fIstring\fR" 4m
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Arc backward direction cost column (number)
.IP "\fBncolumn\fR=\fIstring\fR" 4m
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Node cost column (number)
.IP "\fBccats\fR=\fIrange\fR" 4m
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Category values
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Categories of centres (points on nodes) to which net will be allocated, layer for this categories is given by nlayer option
.PP
.SH DESCRIPTION
\fIv.net.alloc\fR allocates subnets for nearest centers (direction from 
center). center nodes must be opened (costs >= 0). Costs of center nodes are 
used in the calculation. 
.PP
Costs may be either line lengths, or attributes saved in a database 
table. These attribute values are taken as costs of whole segments, not 
as costs to traverse a length unit (e.g. meter) of the segment. 
For example, if the speed limit is 100 km / h, the cost to traverse a 
10 km long road segment must be calculated as 
length / speed = 10 km / (100 km/h) = 0.1 h.
Supported are cost assignments for both arcs and nodes, 
and also different costs for both directions of a vector line. 
For areas, costs will be calculated along boundary lines.
.PP
The input vector needs to be prepared with \fIv.net operation=connect\fR 
in order to connect points representing center nodes to the network.
.SH NOTES
Nodes and arcs can be closed using cost = -1. 
.PP
Center nodes can also be assigned to vector nodes using 
\fIwxGUI vector digitizer\fR. 
.SH EXAMPLES
.PP
1. Subnetwork allocation using distance:
.PP
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.PP
2. Subnetwork allocation using traveling time:
.PP
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.PP
Example 1: \fICalculating subnets for 3 center nodes using distances\fR
\fC
.DS
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# Spearfish
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# center nodes:
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echo "591235.5|4926306.62|1
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596591.8|4917042.5|2
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602722.9|4923544.2|3" | v.in.ascii in=- out=centernodes
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g.copy vect=roads,myroads
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# connect points to network
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v.net myroads points=centernodes out=myroads_net op=connect thresh=200
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# allocate, specifying range of center cats (easier to catch all):
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v.net.alloc myroads_net out=myroads_net_alloc ccats=1-100000 nlayer=2
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# report categories
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v.category myroads_net_alloc option=report
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.DE
\fR
To display the result, run for example:
\fC
.DS
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# show result
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g.region vect=myroads_net
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d.mon x0
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d.vect myroads_net layer=1
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# the result has to be selected by category number of the relevant node:
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d.vect myroads_net_alloc cat=1 col=red layer=1
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d.vect myroads_net_alloc cat=2 col=green layer=1
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d.vect myroads_net_alloc cat=3 col=yellow layer=1
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# center nodes
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d.vect myroads_net col=red icon=basic/triangle fcol=green size=12 layer=2
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.DE
\fR
.PP
Example 2: \fICalculating subnets for 3 center nodes using traveling time\fR
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\fC
.DS
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# Spearfish
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# center nodes:
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echo "591235.5|4926306.62|1
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596591.8|4917042.5|2
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602722.9|4923544.2|3" | v.in.ascii in=- out=centernodes
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g.copy vect=roads,myroads
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# create lines map connecting points to network
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v.net myroads points=centernodes out=myroads_net op=connect thresh=500 alayer=1 nlayer=2
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# set up costs
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# create unique categories for each road in layer 3
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v.category in=myroads_net out=myroads_net_time opt=add cat=1 layer=3 type=line
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# add new table for layer 3
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v.db.addtable myroads_net_time layer=3 col="cat integer,label varchar(43),length double precision,speed double precision,cost double precision,bcost double precision"
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# copy road type to layer 3
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v.to.db myroads_net_time layer=3 qlayer=1 opt=query qcolumn=label columns=label
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# upload road length in miles
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v.to.db myroads_net_time layer=3 type=line option=length col=length unit=miles
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# set speed limits in miles / hour
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v.db.update myroads_net_time layer=3 col=speed val="5.0"
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v.db.update myroads_net_time layer=3 col=speed val="75.0" where="label='interstate'"
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v.db.update myroads_net_time layer=3 col=speed val="75.0" where="label='primary highway, hard surface'"
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v.db.update myroads_net_time layer=3 col=speed val="50.0" where="label='secondary highway, hard surface'"
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v.db.update myroads_net_time layer=3 col=speed val="25.0" where="label='light-duty road, improved surface'"
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v.db.update myroads_net_time layer=3 col=speed val="5.0" where="label='unimproved road'"
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# define traveling costs as traveling time in minutes:
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# set forward costs
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v.db.update myroads_net_time layer=3 col=cost val="length / speed * 60"
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# set backward costs
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v.db.update myroads_net_time layer=3 col=bcost val="length / speed * 60"
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# subnetwork allocation with fastest paths
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v.net.alloc in=myroads_net_time alayer=3 nlayer=2 afcol=cost abcol=bcost out=myroads_net_alloc_time ccats=1-3
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.DE
\fR
To display the result, run for example:
\fC
.DS
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# show result
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g.region vect=myroads_net
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d.mon x0
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d.vect myroads_net type=line layer=1
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# the result has to be selected by category number of the relevant node:
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d.vect myroads_net_alloc_time cat=1 col=red layer=1
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d.vect myroads_net_alloc_time cat=2 col=green layer=1
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d.vect myroads_net_alloc_time cat=3 col=yellow layer=1
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# center nodes
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d.vect myroads_net_time col=red icon=basic/triangle fcol=green size=12 type=point layer=2
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.DE
\fR
.SH SEE ALSO
\fId.path\fR,
\fIv.net\fR,
\fIv.net.iso\fR,
\fIv.net.path\fR,
\fIv.net.steiner\fR,
\fIv.net.salesman\fR
.SH AUTHOR
Radim Blazek, ITC-Irst, Trento, Italy
.br
Documentation: Markus Neteler, Markus Metz
.PP
\fILast changed: $Date: 2011-12-11 21:06:55 +0100 (Sun, 11 Dec 2011) $\fR
.PP
Full index
.PP
© 2003-2011 GRASS Development Team