Provided by: tcllib_1.17-dfsg-1_all 
NAME
simulation::montecarlo - Monte Carlo simulations
SYNOPSIS
package require Tcl ?8.4?
package require simulation::montecarlo 0.1
package require simulation::random
package require math::statistics
::simulation::montecarlo::getOption keyword
::simulation::montecarlo::hasOption keyword
::simulation::montecarlo::setOption keyword value
::simulation::montecarlo::setTrialResult values
::simulation::montecarlo::setExpResult values
::simulation::montecarlo::getTrialResults
::simulation::montecarlo::getExpResult
::simulation::montecarlo::transposeData values
::simulation::montecarlo::integral2D ...
::simulation::montecarlo::singleExperiment args
_________________________________________________________________________________________________
DESCRIPTION
The technique of Monte Carlo simulations is basically simple:
• generate random values for one or more parameters.
• evaluate the model of some system you are interested in and record the interesting
results for each realisation of these parameters.
• after a suitable number of such trials, deduce an overall characteristic of the
model.
You can think of a model of a network of computers, an ecosystem of some kind or in fact
anything that can be quantitatively described and has some stochastic element in it.
The package simulation::montecarlo offers a basic framework for such a modelling
technique:
#
# MC experiments:
# Determine the mean and median of a set of points and compare them
#
::simulation::montecarlo::singleExperiment -init {
package require math::statistics
set prng [::simulation::random::prng_Normal 0.0 1.0]
} -loop {
set numbers {}
for { set i 0 } { $i < [getOption samples] } { incr i } {
lappend numbers [$prng]
}
set mean [::math::statistics::mean $numbers]
set median [::math::statistics::median $numbers] ;# ? Exists?
setTrialResult [list $mean $median]
} -final {
set result [getTrialResults]
set means {}
set medians {}
foreach r $result {
foreach {m M} $r break
lappend means $m
lappend medians $M
}
puts [getOption reportfile] "Correlation: [::math::statistics::corr $means $medians]"
} -trials 100 -samples 10 -verbose 1 -columns {Mean Median}
This example attemps to find out how well the median value and the mean value of a random
set of numbers correlate. Sometimes a median value is a more robust characteristic than a
mean value - especially if you have a statistical distribution with "fat" tails.
PROCEDURES
The package defines the following auxiliary procedures:
::simulation::montecarlo::getOption keyword
Get the value of an option given as part of the singeExperiment command.
string keyword
Given keyword (without leading minus)
::simulation::montecarlo::hasOption keyword
Returns 1 if the option is available, 0 if not.
string keyword
Given keyword (without leading minus)
::simulation::montecarlo::setOption keyword value
Set the value of the given option.
string keyword
Given keyword (without leading minus)
string value
(New) value for the option
::simulation::montecarlo::setTrialResult values
Store the results of the trial for later analysis
list values
List of values to be stored
::simulation::montecarlo::setExpResult values
Set the results of the entire experiment (typically used in the final phase).
list values
List of values to be stored
::simulation::montecarlo::getTrialResults
Get the results of all individual trials for analysis (typically used in the final
phase or after completion of the command).
::simulation::montecarlo::getExpResult
Get the results of the entire experiment (typically used in the final phase or even
after completion of the singleExperiment command).
::simulation::montecarlo::transposeData values
Interchange columns and rows of a list of lists and return the result.
list values
List of lists of values
There are two main procedures: integral2D and singleExperiment.
::simulation::montecarlo::integral2D ...
Integrate a function over a two-dimensional region using a Monte Carlo approach.
Arguments PM
::simulation::montecarlo::singleExperiment args
Iterate code over a number of trials and store the results. The iteration is
gouverned by parameters given via a list of keyword-value pairs.
int n List of keyword-value pairs, all of which are available during the execution
via the getOption command.
The singleExperiment command predefines the following options:
• -init code: code to be run at start up
• -loop body: body of code that defines the computation to be run time and again. The
code should use setTrialResult to store the results of each trial (typically a list
of numbers, but the interpretation is up to the implementation). Note: Required
keyword.
• -final code: code to be run at the end
• -trials n: number of trials in the experiment (required)
• -reportfile file: opened file to send the output to (default: stdout)
• -verbose: write the intermediate results (1) or not (0) (default: 0)
• -analysis proc: either "none" (no automatic analysis), standard (basic statistics
of the trial results and a correlation matrix) or the name of a procedure that will
take care of the analysis.
• -columns list: list of column names, useful for verbose output and the analysis
Any other options can be used via the getOption procedure in the body.
TIPS
The procedure singleExperiment works by constructing a temporary procedure that does the
actual work. It loops for the given number of trials.
As it constructs a temporary procedure, local variables defined at the start continue to
exist in the loop.
KEYWORDS
math, montecarlo simulation, stochastic modelling
CATEGORY
Mathematics
COPYRIGHT
Copyright (c) 2008 Arjen Markus <arjenmarkus@users.sourceforge.net>