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Needing someone to do a written optimization setup for the problem I have attached in the problem file. Please attach the completed problem in a word document for me.
I have attached 2 example pdfs of how they should be setup. As well as instructions below for the assignment.
Thanks for the help in advance!
————
————————————————-
———————————————–
You have some work to do before you ever open Microsoft Excel or download Geogebra, and this is to make sure you are on the right track.
Please review the set up of the example problems as outlined in the pdf files included in this acticity. The included files will cover the thought process or “how to” for setting up these types of problem.
————
As an assignment you will need to describe how you are thinking about the assigned problem, any and all relationships you have established, and define your variables, set up the objective function, constraint inequalities…..and describe what it all means.
You DEFINITELY need to have these correct before moving forward with the technology to get an answer.
You are free to discuss the topics here, but be careful about copying your classmates without thinking for yourself. I will give feedback on Friday to make sure you are on the right track.
Include the following in your post (including any follow up posts you make)
————————————————-
Problem1
The variable x represents:
The variable y represents:
The objective function is:
The constraint inequalities are:
Problem2
The variable x1 represents:
The variable x2 represents:
The variable x3 represents:
The objective function is:The constraint inequalities are:
To: Software Development Team Leaders
From: Robert Hofmann
Date: 12 December
Re: Written Optimization Analysis
M e s s a g e
The state has created new legislation about “crunch-time”, and as such requires us to adjust our
projects for the next quarter. So for the next 13 weeks we will assume that there will be no
scheduled overtime. Our adjusted budget for the quarter gives us 520 hours to schedule per
employee (13 weeks x 40 hours per week = 520 total hours).
We have to determine how many projects we can complete during this time period, making
adjustments based on the man-hours worked on previous projects. Please figure out the
number of game we can make of each type that yields the highest profit.
Additional Information and the projected profit and estimated man-hours based on previous
projects are presented in the following pages pages.
Q u a r t e r l y P r o j e c t i o n
U p d a t e
Written Optimization Report:
Problem 1
To create a single console game, we previously required 10,920 man-hours of development,
13,000 man-hours on art, 3,120 man-hours for design, and 2,080 man-hours for production
management. The projected profit for console game titles is $3.6 million each.
The work requirements for a mobile game are quite a bit different: 7,280 man-hours in
development, 2,600 man-hours art, 9,360man-hours in design, and 2,600 man-hours in
production management. The projected profit for handheld game titles is $2 million each.
Our current staff consists of 238 programmers, 225 artists, 180 designers, and 57 production
managers.
This should give us:
§ 123,760 man-hours in the development pool (238 x 520 = 123,760)
§ 117,000 man-hours in the art pool (225 x 520 = 117,000),
§ 93,600 man-hours in the design pool (180 x 520 = 93,600), and
§ 29,640 man-hours in management (57 x 520 = 29,640)
to allocate to projects,
Department
Console
Game
Mobile
Game
Development
10,920
man-‐hours
7,280
man-‐hours
Art
13,000
man-‐hours
2,600
man-‐hours
Management
2,080
man-‐hours
2,600
man-‐hours
Design
3,120
man-‐hours
9,360
man-‐hours
Profit
Projection
$3,600,000
$2,000,000
Figure out how many console and mobile games can be made this quarter to maximize
our profit. In addition, report what pools (development, artists, designers, and
managers) have some unutilized employees, and which pools could be expanded to
increase profits.
Note: If you want to analyze this problem in terms of number of people on each project, you will
need to convert from man-hours to number of people. Divide the number of man-hours by 520
hours to determine the number of people needed to complete the work in 13 weeks.
Written Optimization Report:
Problem 2
We have decided to expand and create a new PC games department. Out projections indicate
PC game titles will make $2.8 million in profit each. The work requirements are 9,360 man-
hours for development, 8,840 man-hours on artwork, 5,720 man-hours for design, and 1,560
man-hours for production management.
Department
Console
Game
Mobile
Game
PC
Game
Development
10,920
man-‐hours
7,280
man-‐hours
9,360
man-‐hours
Art
13,000
man-‐hours
2,600
man-‐hours
8,840
man-‐hours
Management
2,080
man-‐hours
2,600
man-‐hours
1,560
man-‐hours
Design
3,120
man-‐hours
9,360
man-‐hours
5,720
man-‐hours
Profit
Projection
$3,600,000
$2,000,000
$2,800,000
To help staff this department, we hired 44 more programmers for the development team, 58
more artists for the art team, and 2 more managers for the management team. Please adjust
the total man-hours available based on this new staff before calculating the new estimations.
Figure out how many console, PC, and mobile games can be made this quarter to
maximize our profit. In addition, report what pools (development, artists, designers, and
managers) have some unutilized employees, and which pools could be expanded to
increase profits.
2
Variable
Example
Problem
Part
2:
Analysis
and
set-‐up
Analysis
There
is
quite
a
bit
of
information
to
sort
through
in
these
optimization
problems,
and
this
example
is
no
different.
In
this
part
of
the
problem
we
are
only
trying
to
mathematically
define
the
relationships
for
all
the
information
we
are
given.
Do
not
try
to
“solve”
anything
yet
at
this
point
in
the
process!
Define
the
Variables
The
most
important
step
is
to
define
the
variables
for
the
problem,
which
is
tricky
because
there
is
nothing
to
really
point
to
in
the
presentation
of
the
problem.
The
main
criteria
you
are
looking
for
in
a
variable
are:
• There
is
an
unknown
or
unstated
number
or
amount
of
objects/people
• The
provided
numbers
in
the
problem
relate
directly
to
the
number
or
amount
of
the
unknown
objects.
The
second
question
might
be
the
easier
of
the
two
to
figure
out.
Consider
the
following
statements
from
the
presentation
of
the
problem
in
part
1:
-‐“What
is
the
cheapest
diet
that
will
fulfill
the
dietary
requirements?”
-‐“An
uncooked
cup
of
rice
contains
15
grams
of
protein,
810
calories,
and
1/9
of
a
milligram
of
B2,
all
at
a
price
of
21
cents.”
-‐“An
uncooked
cup
of
soybeans
costs
14
cents…”
Since
we
are
trying
to
figure
out
the
cost
of
the
diet,
we
want
to
look
for
price
information
in
the
problem.
We
have
information
for
the
price
per
cup
for
both
soybeans
and
rice,
but
do
not
know
how
many
cups
of
each
type
of
food
we
will
require!
These
unknown
quantities
will
be
our
variables:
x :
Number
of
cups
of
rice
per
day
y :
Number
of
cups
of
soybeans
per
day
Establish
the
Objective
Function
In
case
you’re
not
sure
how
to
create
a
mathematical
expression
to
represent
the
cost,
consider
the
situations
below
• If
we
have
zero
cups
of
rice
and
zero
cups
of
soybeans,
it
should
be
obvious
that
the
cost
of
that
diet
will
be
zero
cents.
• If
we
have
one
cup
of
rice
only,
the
diet
will
cost
21
cents.
2
Variable
Example
Problem
Part
2:
Analysis
and
set-‐up
• If
we
have
two
cups
of
rice,
the
diet
will
cost
42
cents.
We
calculate
this
by
multiplying
the
cost
per
cup
by
the
number
of
cups:
cost
=
21×2
=
42
cents
• If
we
add
a
cup
of
soybeans
(so
two
cups
of
rice,
one
cup
of
soybeans)
we
will
add
the
cost
of
a
cup
soybeans
to
the
cost
of
the
rice:
cost
=
21×2
+
14
=
56
cents
Since
we
do
not
know
the
amount
of
cups
of
rice
and
soybeans,
but
instead
have
variables
to
stand
in
place
of
them,
we
can
create
a
general
function
to
describe
the
cost
for
any
amount
of
rice
and
soybeans.
Cost = 21x+14y
Defining
the
Constraint
Inequalities
Now
that
we
know
what
we
are
trying
to
optimize
(minimal
cost),
have
defined
our
variables
(number
of
cups
of
rice,
number
of
cups
of
soybeans),
and
have
created
an
objective
function
describing
the
value
we
are
trying
to
optimize
we
can
now
take
a
look
at
our
constraints.
While
it
should
be
obvious
that
the
fewer
cups
of
“food”
(rice
and
soybeans)
we
have
in
the
diet,
the
cheaper
it
is
going
to
be.
However,
we
have
to
make
sure
me
meet
some
nutritional
requirement.
In
our
original
problem
we
stated:
“We
want
to
insure
that
people
on
this
diet
receive
at
least
§ 90g
of
protein,
§ 1620
calories,
§ 1
milligram
of
Vitamin
B2.”
With
that
in
mind,
we
have
to
create
expressions
that
define
how
much
protein,
how
many
calories,
and
how
much
vitamin
B2
is
in
the
diet.
This
follows
the
same
pattern
as
our
objective
function.
NOTE:
The
amount
of
protein,
calories,
and
vitamin
B2
all
vary
by
different
amounts
per
cup
of
soybeans
or
rice.
We
will
treat
each
separately,
each
with
their
own
constraint
inequality.
Protein
A
cup
of
rice
contains
15
grams
of
protein.
15x
will
represent
the
amount
of
protein
from
x
cups
of
rice
(remember
our
variables?)
2
Variable
Example
Problem
Part
2:
Analysis
and
set-‐up
A
cup
of
soybeans
contains
22.5
grams
of
protein.
22.5y
will
represent
the
amount
of
protein
from
y
cups
of
soybeans
The
amount
of
protein
in
our
diet
is
expressed
by:
15x+22.5y
Now
since
this
amount
has
to
be
greater
than
or
equal
to
90
grams
(the
phrase
“at
least”
means
we
cannot
have
a
value
below
90)
we
define
the
following
inequality
as
a
requirement
for
the
diet
15x+22.5y ! 90
The
other
constrains
will
follow
a
similar
pattern.
Calories
A
cup
of
rice
contains
810
calories.
180x
will
represent
the
amount
of
calories
from
x
cups
of
rice.
A
cup
of
soybeans
contains
270
calories.
270y
will
represent
the
amount
of
protein
from
y
cups
of
soybeans.
The
amount
of
calories
in
our
diet
is
expressed
by:
810x+270y
Now
since
this
amount
has
to
be
greater
than
or
equal
to
1620
(the
phrase
“at
least”
means
we
cannot
have
a
value
below
1620)
we
define
the
following
inequality
as
a
requirement
for
the
diet
810x+270y !1620
Vitamin
B2
A
cup
of
rice
contains
1/9th
of
a
milligram
of
vitamin
B2.
1x
will
represent
the
amount
of
vitamin
B2
from
x
cups
of
rice.
A
cup
of
soybeans
contains
1/3
of
a
milligram
of
vitamin
B2.
(1/3)y
will
represent
the
amount
of
protein
from
y
cups
of
soybeans.
The
amount
of
vitamin
B2
in
our
diet
is
expressed
by:
1
9
!
”
#
$
%
&x+
1
3
!
”
#
$
%
&y
Now
since
this
amount
has
to
be
greater
than
or
equal
to
1
milligram
of
vitamin
B2
we
define
the
following
inequality
as
a
requirement
for
the
diet
1
9
!
”
#
$
%
&x+
1
3
!
”
#
$
%
&y ‘1
2
Variable
Example
Problem
Part
2:
Analysis
and
set-‐up
Non-‐negativity
The
last
constraints
are
our
non-‐negativity
constraints.
What
this
means
for
our
problem
is
that
we
can’t
have
negative
values
for
x
and
y
(that
is,
x
and
y
must
be
greater
than
or
equal
to
zero).
This
makes
sense
because
the
context
of
the
problem
does
not
allow
for
us
to
sell
rice
or
soybeans,
nor
does
it
allow
us
to
someone
extract
a
cup
of
rice
or
soybeans
OUT
of
someone’s
body.
Thus
we
have
the
final
set
of
constraints:
15x+22.5y ! 90
810x+270y !1620
1
9
x+
1
3
y !1
x ! 0,y ! 0
”
#
$
$
%
$
$
4
Variable
Example
Problem
Part
2:
Analysis
and
set-‐up
Analysis
There
is
quite
a
bit
of
information
to
sort
through
in
these
optimization
problems,
and
this
example
is
no
different.
In
this
part
of
the
problem
we
are
only
trying
to
mathematically
define
the
relationships
for
all
the
information
we
are
given.
Do
not
try
to
“solve”
anything
yet
at
this
point
in
the
process!
Define
the
Variables
The
most
important
step
is
to
define
the
variables
for
the
problem,
which
is
tricky
because
there
is
nothing
to
really
point
to
in
the
presentation
of
the
problem.
The
main
criteria
you
are
looking
for
in
a
variable
are:
• There
is
an
unknown
or
unstated
number
or
amount
of
objects/people
• The
provided
numbers
in
the
problem
relate
directly
to
the
number
or
amount
of
the
unknown
objects.
The
second
part
might
be
the
easier
to
look
at.
Consider
the
following
statements
from
the
presentation
of
the
problem
in
part
1:
“A
Velite
requires
2
gold
to
recruit,
1
gold
to
equip,
and
half
a
gold
to
train.”
“A
Hopolite
has
a
battle
rating
of:
1
Nowhere
is
there
a
number
provided
for
the
number
of
Hopolites
or
Velites,
and
all
of
our
information
(recruitment
cost,
equipment
cost,
training
cost,
and
battle
rating)
is
given
in
the
terms
of
a
single
Hopolite
or
Velite,
and
the
totals
(costs
and
battle
rating)
will
only
be
know
if
we
know
the
numbers
of
each
type
of
soldiers.
We
will
then
define
our
variables
as
follows:
• x1
:
Number
of
Velites
• x2
:
Number
of
Hoplites
• x3
:
Number
of
Legionaries
• x4
:
Number
of
Equites
Establish
the
Objective
Function
We
are
interested
in
the
total
battle
rating
of
all
the
soldiers
in
the
army.
Therefore
we
want
to
add
the
battle
rating
contributed
by
each
group
of
soldiers:
Overall
Battle
Rating
=
Total
Velite
Battle
Rating
+
Total
Hopolite
Battle
Rating
+
Total
Legionary
Battle
Rating
+
Total
Equite
Battle
Rating
4
Variable
Example
Problem
Part
2:
Analysis
and
set-‐up
Think:
If
a
single
Equite
has
a
battle
rating
of
2
then
two
Equites
will
have
a
battle
rating
of
4
(2
x
2
=
4);
while
10
Equites
will
have
a
battle
rating
of
20
(2
x
10
=
20).
Now
to
find
the
total
battle
rating
for
each
group
of
soldier,
we
will
multiply
the
battle
rating
for
a
single
soldier
by
the
number
of
soldiers.
Now
since
we
do
not
have
the
number
for
the
of
soldiers
of
each
type,
we
will
use
the
variables.
So
we
get
the
following
terms:
§ Total
Velite
Battle
Rating
=
(0.5)×
(x1)
§ Total
Hopolite
Battle
Rating
=
(1)×
(x2)
§ Total
Legionary
Battle
Rating
=
(1.5)×
(x3)
§ Total
Equite
Battle
Rating=
(2)×
(x4)
And
therefore,
our
objective
function
is:
BattleRating = 0.5( )x1 + 1( )x2 + 1.5( )x3 + 2( )x4
Defining
the
Constraint
Inequalities
With
our
variables
and
objective
function
defined,
we
then
want
to
look
at
the
constraint
inequalities.
In
our
problems,
we
are
limited
by
the
amount
of
gold
allotted
to
each
category:
recruitment,
training,
and
equipment.
We
do
not
have
to
use
all
the
gold
in
a
category,
but
we
cannot
go
over.
Note:
This
means
we
will
use
the
“less
than
or
equal
to”
relationship
between
the
amount
of
gold
required,
and
the
total
amount
available
The
mathematical
principle
behind
this
is
much
the
same
as
the
one
set
up
in
the
objective
function:
We
will
multiply
the
cost
involved
for
a
single
soldier
of
each
type,
and
multiply
by
the
number
of
soldiers.
(A
hopolite
costs
2.5
gold
to
recruit,
2
hopolites
will
cost
2.5×2
=
5
gold
to
recruit,
20
hopolites
will
cost
2.5×20
=
50
gold
to
recruit
and
so
on)
Thus
we
have
the
following
constraints:
§ recruitment : 2×1 + 2.5×2 + 2×3 + 2×4 ! 4000
§ equipment :1×1 + 1.5×2 + x3 + 2×4 !1800
§ training : 0.5×1 + 0.5×2 + x3 + x4 ! 4000
So,
with
4
variables,
we
will
not
be
able
to
solve
this
problem
graphically.
This
means
either
using
some
linear
algebra
techniques
or
a
solver.
4
Variable
Example
Problem
Part
2:
Analysis
and
set-‐up
To
use
a
solver,
we
will
have
to
add
the
values
into
a
spreadsheet.
Using
the
empty
3
variable
sheet
and
adding
an
extra
column
should
give
us
a
similar
result
after
filling
in
the
values
and
relabeling
some
cells:
Army
Battle
Value
Variables
X1
X2
X3
X4
Sign
RHS
LHS
Slack
Objective
Function
0.5
1
1.5
2
=
Max
Battle
Points
Recruitment
Constraint
2
2.5
2
2
≤
4000
Constraint
1
Equipment
Constraint
1
1.5
1
2
≤
1800
Constraint
2
Training
Constraint
0.5
0.5
1
1
≤
1000
Constraint
3
Solutions
Velites
Hoplites
Legionares
Equites
