Skip to content
Projects
Groups
Snippets
Help
Loading...
Help
Support
Keyboard shortcuts
?
Submit feedback
Contribute to GitLab
Sign in / Register
Toggle navigation
dream
Project overview
Project overview
Details
Activity
Releases
Repository
Repository
Files
Commits
Branches
Tags
Contributors
Graph
Compare
Issues
1
Issues
1
List
Boards
Labels
Milestones
Merge Requests
0
Merge Requests
0
Analytics
Analytics
Repository
Value Stream
Wiki
Wiki
Members
Members
Collapse sidebar
Close sidebar
Activity
Graph
Create a new issue
Commits
Issue Boards
Open sidebar
nexedi
dream
Commits
0893c001
Commit
0893c001
authored
Oct 27, 2015
by
Georgios Dagkakis
Browse files
Options
Browse Files
Download
Email Patches
Plain Diff
count total WIP of the model
parent
d9970ac0
Changes
1
Show whitespace changes
Inline
Side-by-side
Showing
1 changed file
with
56 additions
and
39 deletions
+56
-39
dream/simulation/Examples/OperationalFailures.py
dream/simulation/Examples/OperationalFailures.py
+56
-39
No files found.
dream/simulation/Examples/OperationalFailures.py
View file @
0893c001
...
...
@@ -8,7 +8,7 @@ import time
start
=
time
.
time
()
# simulation time
maxSimTime
=
2
00
maxSimTime
=
100
00
# the capacity of B123
capacity
=
42
#float('inf')
...
...
@@ -28,16 +28,16 @@ class OpQueue(Queue):
return
M2
return
None
# calculate average buffer level
def
postProcessing
(
self
):
Queue
.
postProcessing
(
self
,
MaxSimtime
=
maxSimTime
)
totalBufferLevel
=
0
for
i
in
range
(
0
,
len
(
self
.
wipStatList
)
-
1
):
bufferLevel
=
self
.
wipStatList
[
i
][
1
]
duration
=
self
.
wipStatList
[
i
+
1
][
0
]
-
self
.
wipStatList
[
i
][
0
]
totalBufferLevel
+=
bufferLevel
*
duration
averageBufferLevel
=
totalBufferLevel
/
maxSimTime
self
.
BufferLevel
.
append
(
averageBufferLevel
)
#
# calculate average buffer level
#
def postProcessing(self):
#
Queue.postProcessing(self, MaxSimtime=maxSimTime)
#
totalBufferLevel=0
#
for i in range(0,len(self.wipStatList)-1):
#
bufferLevel=self.wipStatList[i][1]
#
duration=self.wipStatList[i+1][0]-self.wipStatList[i][0]
#
totalBufferLevel+=bufferLevel*duration
#
averageBufferLevel=totalBufferLevel/maxSimTime
#
self.BufferLevel.append(averageBufferLevel)
class
OpExit
(
Exit
):
# set numGoodParts=0 at every replication
...
...
@@ -95,7 +95,9 @@ class OpMachine(Machine):
# method invoked by the generator at every time period
def
controllerMethod
():
# at the start of the simulation reset the G.totalWIP counter
if
G
.
env
.
now
==
0
:
G
.
totalWIP
=
0
# for every machine calculate the state (based on transition probabilities)
for
M
in
[
M1
,
M2
,
M3
]:
rn1
=
createRandomNumber
()
...
...
@@ -166,6 +168,14 @@ def controllerMethod():
M2
.
locked
=
True
break
# count the total WIP for the machines and the Queue
for
obj
in
[
M1
,
M2
,
M3
,
B123
]:
G
.
totalWIP
+=
len
(
obj
.
getActiveObjectQueue
())
# at the end of the simulation append to the list that keeps for all replications
if
G
.
env
.
now
==
G
.
maxSimTime
-
1
:
G
.
AverageWIP
.
append
(
G
.
totalWIP
/
float
(
G
.
maxSimTime
))
# returns a number from the uniform distribution (0,1)
def
createRandomNumber
():
return
Rnd
.
uniform
(
0
,
1
)
...
...
@@ -200,12 +210,15 @@ for obj in objectList:
# GoodExits will keep the number of good parts produced in every replication
E
.
GoodExits
=
[]
# variables to keep the WIP
G
.
totalWIP
=
0
G
.
AverageWIP
=
[]
# GoodParts will keep the number of good parts a machine produced in every replication
for
M
in
[
M1
,
M2
,
M3
]:
M
.
GoodExits
=
[]
# BufferLevel will keep the average buffer level for each replication
B123
.
BufferLevel
=
[]
# the transition probabilities for machines
M1
.
p
=
0.01
...
...
@@ -222,21 +235,25 @@ M3.r=0.1
M3
.
f
=
0.2
# call the runSimulation giving the objects and the length of the experiment
runSimulation
(
objectList
,
maxSimTime
,
numberOfReplications
=
1
,
trace
=
'No'
)
runSimulation
(
objectList
,
maxSimTime
,
numberOfReplications
=
20
,
trace
=
'No'
)
#print the results
PRt
=
sum
(
E
.
Exits
)
/
float
(
len
(
E
.
Exits
))
PRg
=
sum
(
E
.
GoodExits
)
/
float
(
len
(
E
.
GoodExits
))
B123ABF
=
sum
(
B123
.
BufferLevel
)
/
float
(
len
(
B123
.
BufferLevel
))
#
B123ABF=sum(B123.BufferLevel)/float(len(B123.BufferLevel))
print
E
.
Exits
print
E
.
GoodExits
print
G
.
AverageWIP
print
'PRt='
,
PRt
/
float
(
maxSimTime
)
print
'PRg='
,
PRg
/
float
(
maxSimTime
)
print
'B123 average buffer level='
,
B123ABF
#
print 'B123 average buffer level=',B123ABF
for
M
in
[
M1
,
M2
,
M3
]:
GE
=
sum
(
M
.
GoodExits
)
/
float
(
len
(
M
.
GoodExits
))
print
'PRg'
+
M
.
id
,
'='
,
GE
/
float
(
maxSimTime
)
AVGWIP
=
sum
(
G
.
AverageWIP
)
/
float
(
len
(
G
.
AverageWIP
))
print
'AVGWIP='
,
AVGWIP
# ExcelHandler.outputTrace('OperationalFailures')
print
"running time="
,
time
.
time
()
-
start
...
...
@@ -246,26 +263,26 @@ from rpy2.robjects.packages import importr
from
rpy2.rinterface
import
NA_Real
# to plot B123 if we want
base
=
importr
(
"base"
)
stats
=
importr
(
"stats"
)
grdevices
=
importr
(
"grDevices"
)
graphics
=
importr
(
"graphics"
)
graphWipStatList
=
list
(
B123
.
wipStatList
)
index
=
0
for
i
in
range
(
len
(
B123
.
wipStatList
)
-
1
):
if
B123
.
wipStatList
[
i
][
0
]
==
B123
.
wipStatList
[
i
+
1
][
0
]:
del
graphWipStatList
[
index
]
else
:
index
+=
1
simTime
=
[
x
[
0
]
for
x
in
graphWipStatList
]
bufferLevel
=
[
x
[
1
]
for
x
in
graphWipStatList
]
grdevices
.
png
(
"B123 Buffer Level.png"
)
graphics
.
plot
(
simTime
,
bufferLevel
,
xlab
=
"Simulation Time"
,
ylab
=
"Buffer Level"
,
col
=
"red"
,
type
=
"l"
,
tck
=
1
)
graphics
.
title
(
"Buffer level time series"
)
grdevices
.
dev_off
()
#
#
to plot B123 if we want
#
base = importr("base")
#
stats = importr("stats")
#
grdevices = importr("grDevices")
#
graphics = importr("graphics")
#
#
graphWipStatList=list(B123.wipStatList)
#
index=0
#
for i in range(len(B123.wipStatList)-1):
#
if B123.wipStatList[i][0]==B123.wipStatList[i+1][0]:
#
del graphWipStatList[index]
#
else:
#
index+=1
#
#
#
simTime = [x[0] for x in graphWipStatList]
#
bufferLevel = [x[1] for x in graphWipStatList]
#
#
grdevices.png("B123 Buffer Level.png")
#
graphics.plot(simTime, bufferLevel, xlab="Simulation Time", ylab="Buffer Level", col="red", type="l", tck=1)
#
graphics.title("Buffer level time series")
#
grdevices.dev_off()
Write
Preview
Markdown
is supported
0%
Try again
or
attach a new file
Attach a file
Cancel
You are about to add
0
people
to the discussion. Proceed with caution.
Finish editing this message first!
Cancel
Please
register
or
sign in
to comment