[Arjen Markus] (25 june 2007) Monte Carlo simulations are useful in many cases where the system being studied reacts to random input, but also if you want to determine the integral of a function over a complicated area. Such simulations usually require a lot of steps and sometimes numerous runs to get meaningful results.
The script below is an attempt to model a simple queueing system. See the comments for more information. It tries to answer a vexing question: how long does one have to wait (on average)?
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# simple_queue.tcl
# A simulation of a queue:
# - On average 1 person per 5 minutes enters the system
# - Handling his/her request takes either 3 minutes or 10 minutes
# (with a 1/10 chance for the longer request).
# - The average handling time is therefore (9*3+10)/10 = 3.7 minutes
# - The system can handle this - on average
# - Question is, however, what is the mean waiting time? If you
# are in the queue behind two people whose requests will take 10
# minutes, you will be waiting longer than if these two both have
# the short requests
#
# randomBinomial --
# Return a random value (0 or 1) according to the binomial distribution
#
# Arguments:
# p Chance of returning 1
#
# Result
# Random value of 0 or 1
#
proc randomBinomial {p} {
return [expr {rand()>$p? 0 : 1}]
}
# runQueue --
# Run the queuing system
#
# Arguments:
# nosteps Number of steps to run the system
#
# Result:
# None
#
# Side effects:
# Fills the global variables waiting_times and queue
#
proc runQueue {nosteps} {
global waiting_times
global queue
#
# Start with an empty queue
#
set queue {}
#
# Loop over time
#
for { set time 0 } { $time < $nosteps } { incr time } {
#
# New client entering the system?
#
if { [randomBinomial 0.2] == 1 } {
if { [randomBinomial 0.1] == 1 } {
set request 10
} else {
set request 3
}
set person [list $time $request]
lappend queue $person
}
#
# Handle the current request, if any
#
if { [llength $queue] > 0 } {
set person [lindex $queue 0]
foreach {arrival_time request} $person {break}
if { $request <= 0 } {
# We are done with this client
set queue [lrange $queue 1 end]
lappend waiting_times [expr {$time-$arrival_time}]
} else {
# Reduce the time left for the request
set request [expr {$request-1}]
lset queue 0 1 $request
}
}
}
}
# main --
# Run the queueing system, timestep is one minute:
# For a period of 8 hours (480 minutes), do the following
# every minute:
# - If someone comes in, add them to the queue with the arrival
# time and the type of request
# - If there is someone in the queue, take one minute off the
# remaining time for their request, if it is positive. Otherwise
# remove the entry from the queue and record the waiting time
#
# To get a fairer estimate, we run the queueing system 50 times
set av_av_time 0
set av_max_time 0
set av_queue 0
set av_count 0
for { set i 0 } { $i < 50 } { incr i } {
set waiting_times {}
runQueue 480
set count 0
set average_time 0
set max_time 0
foreach time $waiting_times {
set average_time [expr {$average_time + $time}]
incr count
if { $time > $max_time } {
set max_time $time
}
}
set average_time [expr {$average_time/double($count)}]
set av_count [expr {$av_count + $count}]
set av_av_time [expr {$av_av_time + $average_time}]
set av_max_time [expr {$av_max_time + $max_time}]
set av_queue [expr {$av_queue + [llength $queue]}]
puts "Simulation $i: [format %.1f $average_time] - $max_time"
}
puts "Sample averages:"
puts "----------------"
puts "Number of persons: [format %.1f [expr {$av_count/50.0}]]"
puts "Average waiting time: [format %.1f [expr {$av_av_time/50.0}]]"
puts "Maximum waiting time: [format %.1f [expr {$av_max_time/50.0}]]"
puts "People still waiting: [format %.1f [expr {$av_queue/50.0}]]"
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***Screenshots***
[http://img515.imageshack.us/img515/8632/tclwikirandomqueuesym2.png]
[gold] added pix, mockup plot from TCL8.5 demo code
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!!!!!!
%| [Category Mathematics] | [Category Simulator] |%
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