NAME
r.connectivity.corridors - Compute corridors between habitat patches of an input-layer based on (cost) distance raster maps
KEYWORDS
raster,
vector,
corridor,
cost distance,
least cost paths
SYNOPSIS
r.connectivity.corridors
r.connectivity.corridors --help
r.connectivity.corridors [-sdr] input=Result from r.connectivity.network containing edge measures layer=string [weights=Column names[,Column names,...]] [where=where (SQL statement)] suffix=string [corridor_tolerance=float] [cores=integer] [--help] [--verbose] [--quiet] [--ui]
Flags:
- -s
- Show edges selected by where-clause and exit
- -d
- Assign distance values to corridors instead of connection ids and weights
- -r
- Recalculate already computed corridors (default is only weight and summarize already existing corridor maps)
- --help
- Print usage summary
- --verbose
- Verbose module output
- --quiet
- Quiet module output
- --ui
- Force launching GUI dialog
Parameters:
- input=Result from r.connectivity.network containing edge measures [required]
- Name of input vector map
- Name of the table containing edge measures from r.connectivity.network
- layer=string [required]
- Layer number or name
- layer containing patch geometries
- Default: 1
- weights=Column names[,Column names,...]
- Column names separated by comma
- where=where (SQL statement)
- WHERE conditions of SQL statement without 'where' keyword
- where conditions of SQL statement without 'where' keyword. (example: cf_mst_ud = 1 or cf_eb_ud > 100)
- suffix=string [required]
- Output suffix for corridor summary result
- corridor_tolerance=float
- Tolerance for deviation from (cost) distance within corridors (in %)
- Default: 0.0
- cores=integer
- cores used for multithreading (1 means no multithreading)
- Default: 1
r.connectivity.corridors is th 3rd tool of the r.connectivity.* toolset.
r.connectivity.corridors loops through the user-selected edges
(where option) of the edge-measure output vector map from
r.connectivity.network and computes the respective corridor(s).
Corridors are defined as all pixels that have a lower average cost distance
from a pair of patches, than the average cost distance between that pair.
The user can add a tolerance for allowed deviation from cost distance
within corridors in %, using the corridor_tolerance option.
r.connectivity.corridors can account for the importance of the
corridors for the entire network by weighting them with regards to one or
more network measures from r.connectivity.network, using the
weights option.
Thus,
r.connectivity.corridors produces two types of output,
that are named according to a user defined
prefix and
suffix:
- a set of individual corridor raster maps
(named: prefix_corridor_edge_id_weight) and
- a summary over all computed corridors
(named: prefix_corridor_edge_id_weight_sum_suffix).
Finally, all individual corridors are being put together using r.series.
In this step, the values of the cells in all corridor maps are summed up,
which indicates the importance of an area (raster cell) for the network
of the given patches (either the number of corridors a cell is part of,
or other graph-theoretical measures for corridor importance).
Corridors are only computed for an undirected graph.
The following example is continued from and based on the example in
r.connectivity.network!
In this example two alternative (or to some extent complementary) sets
of corridors are calculated:
For the first set, corridors are only computed for the minimum spanning
tree (in literture sometimes called the backbone of an ecological network).
This is specified in the "where"-parameter. Edge betweenness values are
used as weights, which represent the centrality of a connection (edge)
in a network (and is therewith a measure of importance). The output is a
set of corridor raster maps (named: "prefix" _corridor_ "edge_id" _ "weight")
and a summary over all computed corridors
(named: "prefix" _corridor_ "edge_id" _ "weight" _sum_ "suffix").
r.connectivity.corridors input=hws_connectivity_edge_measures layer=1 \
weights=cd_eb_ud suffix=mst corridor_tolerance=0.05 where="cf_mst_ud>0" \
cores=1
Figure: Corridors computed for connections on the minimum spanning
tree weighted by edge betweenness in the example above.
For the second set, corridors are computed for all edges in the graph
(network). This takes a little more time. Corridors are then weighted by
the modeled, undirected (= in oth directions) flow of propagules ("cf_u").
r.connectivity.corridors input=hws_connectivity_edge_measures layer=1 \
weights=cf_u suffix=all corridor_tolerance=0.05 \
cores=1
Figure: Corridors computed for all connections, weighted by
potential flow of propagules.
Users with a multi-processor computer (e.g. dual-core) may speed up
corridor processing by setting cores > 1 r.connectivity.corridors.
An other means for speeding up processing would be to use integer weights
(e.g. by converting edge betweenness to integer afte multiplying with 10
to the power of the relevant number of digits). Then
r.reclass
is used in the script instead of
r.recode.
When all analysis is finnished some cleanup may be appropriate, in order
to save disk space:
# Add the f-lag (-f) to the following two commands if you are sure you
# want to delete all intermediate maps from r.connectivity.*.
g.remove type=raster pattern=hws_connectivity_corridor_*
g.remove type=raster pattern=hws_connectivity_patch_*
r.connectivity.distance,
r.connectivity.network
Stefan Blumentrath, Norwegian Institute for Nature Research (NINA)
Last changed: $Date: 2018-09-12 14:01:08 +0200 (Wed, 12 Sep 2018) $
SOURCE CODE
Available at: r.connectivity.corridors source code (history)
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