NAME
r.agent.aco - Agents wander around on the terrain, marking paths to new locations.
KEYWORDS
SYNOPSIS
r.agent.aco
r.agent.aco --help
r.agent.aco [-pscal] outputmap=string [inputmap=string] costmap=string sitesmap=string rounds=integer [outrounds=integer] [targetvisibility=integer] [highcostlimit=integer] [lowcostlimit=integer] [maxpheromone=integer] [minpheromone=integer] [volatilizationtime=integer] [stepintensity=integer] [pathintensity=integer] [maxants=integer] [antslife=integer] decisionalgorithm=string evaluateposition=string [agentfreedom=integer] pheromoneweight=integer randomnessweight=integer costweight=integer [--help] [--verbose] [--quiet] [--ui]
Flags:
- -p
- Allow overwriting existing pheromone maps
- -s
- Produce a sequence of pheromone maps (by appending a number)
- -c
- Overwrite existing cost map (only used with penalty conversion)
- -a
- Auto-convert cost (slope..) to penalty map (using "tobler", see docu)
- -l
- Avoid loops on the way back
- --help
- Print usage summary
- --verbose
- Verbose module output
- --quiet
- Quiet module output
- --ui
- Force launching GUI dialog
Parameters:
- outputmap=string [required]
- Name of pheromone output map
- inputmap=string
- Name of input pheromone raster map (e.g. from prior run)
- costmap=string [required]
- Name of penalty resp. cost raster map (note conversion checkbox)
- sitesmap=string [required]
- Name of sites map, vector data with possible points of origin
- rounds=integer [required]
- Number of iterations/rounds to run
- Options: 0-999999
- Default: 999
- outrounds=integer
- Produce output after running this number of iterations/rounds
- Options: 0-999999
- targetvisibility=integer
- Distance to target from where it might be 'sensed'
- Options: 0-999999
- highcostlimit=integer
- Penalty values above this point an ant considers as illegal/bogus when in 'costlymarked' modus
- Options: 0-<max integer on system would make sense>
- lowcostlimit=integer
- Penalty values below this point an ant considers as illegal/bogus when in 'costlymarked' modus
- Options: -99999-99999
- maxpheromone=integer
- Absolute maximum of pheromone intensity a position may have
- Options: <minpheromone>-<max integer on system would make sense>
- minpheromone=integer
- Absolute minimum of pheromone intensity to leave on playground
- Options: 0-<maxpheromone>
- volatilizationtime=integer
- Half-life for pheromone to volatize (e.g. =rounds)
- Options: 0-<max integer on system would make sense>
- stepintensity=integer
- Pheromone intensity to leave on each step
- Options: 0-<max integer on system would make sense>
- pathintensity=integer
- Pheromone intensity to leave on found paths
- Options: 0-<max integer on system would make sense>
- maxants=integer
- Maximum amount of ants that may live concurrently (x*y)
- Options: 0-<the bigger the playground, the more space they have>
- antslife=integer
- Time to live for an ant (e.g. four times points distance)
- Options: 0-<max integer on system would make sense>
- decisionalgorithm=string [required]
- Algorithm used for walking step
- Options: standard, marked, costlymarked, random, test
- Default: standard
- evaluateposition=string [required]
- Algorithm used for finding and remembering paths
- Options: standard, avoidloop, forgetloop, avoidorforgetloop
- Default: avoidorforgetloop
- agentfreedom=integer
- Number of possible directions the ant can take (4 or 8)
- Options: 4, 8
- pheromoneweight=integer [required]
- How is the pheromone value (P) weighted when walking (p*P:r*R:c*C)
- Options: 0-99999
- Default: 1
- randomnessweight=integer [required]
- How is the random value (R) weighted when walking (p*P:r*R:c*C)
- Options: 0-99999
- Default: 1
- costweight=integer [required]
- How is the penalty value (C) weighted when walking (p*P:r*R:c*C)
- Options: 0-99999
- Default: 0
As a first real example of a world there is an ACO-based environment
(see
Ant Colony Optimization)
available.
The basic concept of such an ACO world, is to take some cost surface
and transform it to a penalty layer. Even if the algorithm comes from
the realm of insects, it might be adapted to different animal kingdoms.
Depending on the type of agent this penalty layer must be reinterpreted:
if for example, we want to talk about human
agents
the penalty layer may be expressed by the walking velocity, e.g. calculated
with the algorithm proposed by
Tobler1993.
The actors on the playground will wander around on the playground
using the time for their paths that correspond with the values in the penalty
grid.
If they find some attractor, they walk home to the position they
originated, marking their way with pheromones. While this
pheromone vanishes over time, the following agents are more likely
to choose their next steps to a position that smells most.
This first toolset was mainly developed for
Topoi Project A-III-4,
with some
inspirations from previous work conducted at the
Uni Bern in 2008.
The state of this software is: "first do it".
ACO works best on dynamic maps -- it constantly tries to improve paths...
A fictive use case could look something like this
(note: at the moment the
in- and output variables with
libold, are still ascii-files):
r.agent.aco outputmap=out.map penaltymap=testpenalty.grid \
sitesmap=sites.vect rounds=100 outrounds=100 volatilizationtime=5000 \
antslife=2000 maxants=400 pathintensity=1000000
For running the total test suite on the libraries,
i.e. to run all the tests that are at the end
of each python file, use this test collection
(for certain tests, the following files must exist though:
"elev.grid", and "arch.vect"):
user@host:~$ cd /<pathtoaddons>/r.agent/libagent
user@host:libold$ ./alltests.py
Integrate it directly within grass.
Improve encapsulation of classes.
Find good parameters, or parameter finding strategies for the ACO part.
Try to avoid high penalty fields.
Think about heuristics too.
Implement other ABM scenarios.
Michael Lustenberger inofix.ch
SOURCE CODE
Available at:
r.agent.aco source code
(history)
Latest change: Monday Nov 11 18:04:48 2024 in commit: 59e289fdb093de6dd98d5827973e41128196887d
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