An Introduction to Management Science: Quantitative Approaches
to Decision Making 14th edition by David R. Anderson, Dennis J.
Sweeney, Thomas A. Williams, Jeffrey D. Camm, James J.
Cochran, Fry and Ohlmann Solution Manual
Link full download solution manual: />Link full download test bank: />
Chapter 2
An Introduction to Linear Programming

Learning Objectives
1.

Obtain an overview of the kinds of problems linear programming has been used to solve.

2.

Learn how to develop linear programming models for simple problems.

3.

Be able to identify the special features of a model that make it a linear programming model.

4.

Learn how to solve two variable linear programming models by the graphical solution procedure.

5.

Understand the importance of extreme points in obtaining the optimal solution.

6.

Know the use and interpretation of slack and surplus variables.

7.

Be able to interpret the computer solution of a linear programming problem.

8.

Understand how alternative optimal solutions, infeasibility and unboundedness can
occur in linear programming problems.

9.

Understand the following terms:
problem formulation
constraint function
objective function
solution
optimal solution
nonnegativity constraints
mathematical model
linear program
linear functions
feasible solution

feasible region
slack variable
standard form

redundant constraint

extreme point
surplus variable
alternative optimal solutions

infeasibility
unbounded

2-1


Chapter 2

Solutions:
1.

a, b, and e, are acceptable linear programming
2

relationships. c is not acceptable because of 2B
d is not acceptable because of 3
A f is not acceptable because of 1AB

c, d, and f could not be found in a linear programming model because they have the
above nonlinear terms.
2.

a.
B
8


4

0

A

4

8

4

8

b.
B
8

4

0

A

c.
B
8

Points on line
are only feasible

points

4
A

0

4

2-2

8


An Introduction to Linear Programming

3.

a.
B
(0,9)

A

0

(6,0)

b.
B

(0,60)

A

0

(40,0)

c.
B
Points
on line are only
feasible solutions
(0,20)
A
(40,0)

0
4.

a.
B

(20,0)

(0,-15)

2-3

A



Chapter 2

b.
B

(0,12)
(-10,0)

A

c.
B
(10,25)

Note: Point shown was
used to locate position of

the constraint line

A

0
5.
B

a

300


c
200

100
b
A
0

100

200

2-4

300


An Introduction to Linear Programming

6.

7A + 10B = 420 is labeled (a)
6A + 4B = 420 is labeled (b) 4A + 7B = 420 is labeled (c)

B
100
80
60
(b)


(c)

40
20

(a)
A

-100

-80

-60

-40

-20

0

20

40

60

80

100


7.
B
100

50

A

0
50

100

150

2-5

200

250


Chapter 2

8.
B
200

133


1

/3

(100,200)

A
-200

-100

0

100

200

9.

B
(150,225)
200

100

(150,100)

0


A
100

-100

-200

2-6

200

300


An Introduction to Linear Programming

10.
B
5

4
Optimal Solution
A = 12/7, B = 15/7
3
Value of Objective Function = 2(12/7) + 3(15/7) = 69/7
2

1

0


A
1

2

(1) × 5
(2) - (3)

3

4

A +
5A +
5A +
-

2B
3B
10B
7B
B

From (1), A = 6 - 2(15/7) = 6 - 30/7 = 12/7

2-7

5


=
6 (1)
=
15 (2)
=
30 (3)
= -15
= 15/7

6


Chapter 2

11.
B
A = 100

Optimal Solution
A = 100, B = 50
Value of Objective Function = 750

100
B = 80

0

A
100


200

12. a.
B
6

5

4

Optimal Solution
A = 3, B = 1.5

3

Value of Objective Function = 13.5
(3,1.5)

2

1

(0,0)

A
1

2

3


2-8

4
(4,0)

5

6


An Introduction to Linear Programming

b.

B
3

Optimal Solution

A = 0, B = 3
Value of ObjectFunction = 18

2

1

(0,0)

A

1

2

3

4

5

6

7

8

c. There are four extreme points: (0,0), (4,0), (3,1,5), and (0,3).
13. a.
B
8

6
Feasible Region

4

consists of this line

segment only
2


0

A
2

4

b. The extreme points are (5, 1) and (2, 4).

2-9

6

8

9

10


Chapter 2

c.
B
8

6

Optimal Solution

A = 2, B = 4

4

2

0

A
2

4

14. a. Let F = number of tons of fuel additive
S = number of tons of solvent base
Max
s.t.

40F

+

30S

2/5F

+

1/


S

200 Material 1

1/

S

5 Material 2

S

21 Material 3

2

3
/ F

5

F, S

5

+

3/

10


0

2 - 10

6

8


An Introduction to Linear Programming

b.
S

F

c.

Material 2: 4 tons are used, 1 ton is unused.

d. No redundant constraints.
15. a.

2 - 11


Chapter 2

b. Similar to part (a): the same feasible region with a different objective function. The optimal

solution occurs at (708, 0) with a profit of z = 20(708) + 9(0) = 14,160.
c. The sewing constraint is redundant. Such a change would not change the optimal
solution to the original problem.
16. a. A variety of objective functions with a slope greater than -4/10 (slope of I & P line) will make
extreme point (0, 540) the optimal solution. For example, one possibility is 3S + 9D.

b. Optimal Solution is S = 0 and D = 540.
c.
Department
Cutting and Dyeing

Hours Used
1(540) = 540

Max. Available
630

Slack
90

2

/6(540) = 450
/3(540) = 360

600
708

150
348


/4(540) = 135

135

0

5

Sewing
Finishing
Inspection and Packaging

1

17.
Max5A + 2B +
s.t.
1A - 2B +
2A + 3B
6A - 1B

0S1 + 0S2

+

1S1

= 420
= 610

+ 1S3 = 125

+ 1S2
A, B, S1, S2, S3

0S3

0

18. a.
Max
s.t.

4A + 1B

+ 0S1 + 0S2

+ 0S3

10A + 2B + 1S1
+ 1S2

3A + 2B
2A + 2B

+ 1S3

A, B, S1, S2, S3

2 - 12


0

= 30
= 12
= 10


An Introduction to Linear Programming

b.
B
14

12

10

8

6
Optimal Solution
A = 18/7, B = 15/7, Value = 87/7
4

2

0

A

2

4

6

8

10

c. S1 = 0, S2 = 0, S3 = 4/7
19. a.
Max
s.t.

3A

+ 4B

+ 0S1 + 0S2

-1A
1A
2A

+ 2B
+ 2B
+ 1B

+ 1S1


+ 0S3

+ 1S2
+ 1S3

A, B, S1, S2, S3

2 - 13

0

= 8
= 12
= 16

(1)
(2)
(3)


Chapter 2

b.
B
14
(3)
12

10


(1)

8

6
Optimal Solution
A = 20/3, B = 8/3
Value = 30 2/3

4

2
(2)
0

A
2

c.

4

6

8

10

12


S1 = 8 + A – 2B = 8 + 20/3 - 16/3 = 28/3
S2 = 12 - A – 2B = 12 - 20/3 - 16/3 = 0
S3 = 16 – 2A - B = 16 - 40/3 - 8/3 = 0

20. a.
Max3A + 2B
s.t.
A + B - S1
+ S2
3A + 4B
- S3
A
A B

- S4

A, B, S1, S2, S3, S4 0

2 - 14

=
4
= 24
=
2
=
0



An Introduction to Linear Programming

b.

c.

S1 = (3.43 + 3.43) - 4 = 2.86
S2 = 24 - [3(3.43) + 4(3.43)] = 0
S3 = 3.43 - 2 = 1.43
S4 = 0 - (3.43 - 3.43) = 0

2 - 15


Chapter 2

21. a. and b.
B
90

80

70
Constraint 2
60

50

40


Optimal Solution

Constraint 1

Constraint 3

30

20

Feasible Region

10

2A + 3B = 60

0

A
10

c.

20

30

40

50


60

70

80

90

100

Optimal solution occurs at the intersection of constraints 1 and 2. For
constraint 2, B = 10 + A
Substituting for B in constraint 1 we obtain
5A + 5(10 + A)
5A + 50 + 5A
10A
A

= 400
= 400
= 350
= 35

B = 10 + A = 10 + 35 = 45
Optimal solution is A = 35, B = 45
d. Because the optimal solution occurs at the intersection of constraints 1 and 2, these
are binding constraints.

2 - 16



An Introduction to Linear Programming

e. Constraint 3 is the nonbinding constraint. At the optimal solution 1A + 3B = 1(35) + 3(45)
= 170. Because 170 exceeds the right-hand side value of 90 by 80 units, there is a
surplus of 80 associated with this constraint.
22. a.
C
3500

3000

2500

Inspection and
Packaging

2000

Cutting and
Dyeing

5
1500

Feasible Region

4
1000


Sewing
3
5A + 4C = 4000

500

2
0

1

A
500

1000
1500
2000
2500
Number of All-Pro Footballs

3000

b.
Extreme Point
1
2
3
4
5


Coordinates
Profit
(0, 0)
5(0) + 4(0) = 0
(1700, 0)5(1700) + 4(0) = 8500
(1400, 600)5(1400) + 4(600) = 9400
(800, 1200)5(800) + 4(1200) = 8800
(0, 1680)5(0) + 4(1680) = 6720

Extreme point 3 generates the highest profit.
c. Optimal solution is A = 1400, C = 600
d.

The optimal solution occurs at the intersection of the cutting and dyeing constraint and the inspection
and packaging constraint. Therefore these two constraints are the binding constraints.

e. New optimal solution is A = 800, C =
1200 Profit = 4(800) + 5(1200) = 9200

2 - 17


Chapter 2

23. a. Let E = number of units of the EZ-Rider produced
L = number of units of the Lady-Sport produced
Max2400E

+


6E

+

2E

+

1800L

s.t.
3L
L
2.5L
E, L 0

2100 Engine time
280 Lady-Sport maximum
1000 Assembly and testing

b.
L
700
Engine

600

Manufacturing


500

400

300

for Lady-Sport
Optimal Solution E = 250, L = 200
Profit = $960,000

200

100
Assembly and Testing
0

E
100

200

300

400

500

Number of Lady-Sport Produced
c. The binding constraints are the manufacturing time and the assembly and testing time.


24. a. Let R = number of units of regular model.
C = number of units of catcher’s model.
Max
s.t.

5R

+

8C

1R

900 Cutting and sewing

1/ 2 R

+ 3/ 2 C
+ 1/ 3 C

1/ 8 R

+ 1/ 4 C

100 Packing and Shipping

300 Finishing

R, C 0


2 - 18


An Introduction to Linear Programming

b.
C

Model

1000

800

F
600

C

Catcher's

&

Optimal Solution
(500,150)

S
400

P

& S

200
R
0

200

400

600

800

1000

Regular Model
c.

5(500) + 8(150) = $3,700

d. C & S

3

1(500) + / (150) = 725
2

1


/ (500) +

F

1

2

P&S

/ (150) = 300
3

1

/ (500) +

1

8

/ (150) = 100
4

e.
Department
C&S
F
P&S
25.


Capacity
900
300
100

Usage
725
300
100

Slack
175 hours
0 hours
0 hours

a. Let B = percentage of funds invested in the bond fund S =
percentage of funds invested in the stock fund

Max
s.t.

0.06 B
B
0.06 B
B

b.

+


+
+

0.10 S

0.10 S
S =

Optimal solution: B = 0.3, S = 0.7 Value
of optimal solution is 0.088 or 8.8%

2 - 19

0.3
0.075
1

Bond fund minimum
Minimum return
Percentage requirement


Chapter 2

26. a. a. Let N = amount spent on newspaper advertising
R = amount spent on radio advertising

Max
s.t.


50N + 80R
N +
N
N
N, R

R = 1000 Budget
250 Newspaper
min. R 250 Radio min.
-2R0 News 2 Radio

0

b.
R

1000

Radio Min

Optimal Solution
N = 666.67, R = 333.33
Value = 60,000

Budget

N = 2R

500


Newspaper Min
Feasible region
is this line segment
N
0
27.

5 00

1000

Let I = Internet fund investment in thousands
B = Blue Chip fund investment in thousands
Max
s.t.

0.12I +

0.09B

1I +
1B
1I
6I +
4B
I, B 0

50
35

240

Available investment funds
Maximum investment in the internet fund
Maximum risk for a moderate investor

2 - 20


An Introduction to Linear Programming

B

60

Risk Constraint
Optimal Solution
I = 20, B = 30

50

$5,100
Maxim
Inte
Funds

40

30


20

10

Funct
0.
+ 09B

Available Funds
$50,000

0

I

10

20

30

40

50

60

Internet Fund (000s)
Internet fund
Blue Chip fund

Annual return

$ 20,000
$ 30,000
$ 5,100

b. The third constraint for the aggressive investor becomes
6I + 4B 320
This constraint is redundant; the available funds and the maximum Internet fund
investment constraints define the feasible region. The optimal solution is:
Internet fund
Blue Chip fund
Annual return

$ 35,000
$ 15,000
$ 5,550

The aggressive investor places as much funds as possible in the high return but high
risk Internet fund.
c.

The third constraint for the conservative investor becomes
6I + 4B 160
This constraint becomes a binding constraint. The optimal solution is
Internet fund
Blue Chip fund
Annual return

$ 0

$ 40,000
$ 3,600

2 - 21


Chapter 2

The slack for constraint 1 is $10,000. This indicates that investing all $50,000 in the Blue Chip
fund is still too risky for the conservative investor. $40,000 can be invested in the Blue Chip
fund. The remaining $10,000 could be invested in low-risk bonds or certificates of deposit.
28. a. Let W = number of jars of Western Foods Salsa produced M
= number of jars of Mexico City Salsa produced

Max
s.t.

1W

+

1.25M

5W
3W
+
2W
+
W, M 0


7M
1M
2M

4480
2080
1600

Whole tomatoes
Tomato sauce
Tomato paste

Note: units for constraints are ounces
b. Optimal solution: W = 560, M = 240
Value of optimal solution is 860
29. a. Let B = proportion of Buffalo's time used to produce component 1
D = proportion of Dayton's time used to produce component 1

Buffalo
Dayton

Maximum Daily Production
Component 1
Component 2
2000
1000
600
1400

Number of units of component 1 produced: 2000B + 600D

Number of units of component 2 produced: 1000(1 - B) + 600(1 - D)
For assembly of the ignition systems, the number of units of component 1 produced
must equal the number of units of component 2 produced.
Therefore,
2000B + 600D = 1000(1 - B) + 1400(1 - D)
2000B + 600D = 1000 - 1000B + 1400 - 1400D
3000B + 2000D = 2400
Note: Because every ignition system uses 1 unit of component 1 and 1 unit of component
2, we can maximize the number of electronic ignition systems produced by maximizing
the number of units of subassembly 1 produced.
Max 2000B + 600D
In addition, B 1 and D

1.

2 - 22


An Introduction to Linear Programming

The linear programming model is:
Max
s.t.

2000B

+ 600D

3000B
B


+ 2000D = 2400
1
D

1

B, D

0

The graphical solution is shown below.
D
1.2

1.0

.8

.6

.4

Optimal
Solution

.2

2000B + 600D = 300


B
0

.2

.4

.6

.8

1.0

Optimal Solution: B = .8, D = 0
Optimal Production Plan
Buffalo - Component 1
Buffalo - Component 2
Dayton - Component 1
Dayton - Component 2

.8(2000) = 1600
.2(1000) = 200
0(600) = 0
1(1400) = 1400

Total units of electronic ignition system = 1600 per day.

2 - 23

1.2



Chapter 2

30. a. Let

E = number of shares of Eastern Cable
C = number of shares of ComSwitch
Max15E

+ 18C

40E
40E

+ 25C

s.t.

25C
25C
E, C 0

50,000
15,000
10,000
25,000

Maximum Investment
Eastern Cable Minimum

ComSwitch Minimum
ComSwitch Maximum

b.
C
2000

Minimum Eastern Cable

1500

Maximum Comswitch

1000

Maximum Investment
500
Minimum Conswitch

0

c.

500
1000
1500
Number of Shares of Eastern Cable

E


There are four extreme points: (375,400); (1000,400);(625,1000); (375,1000)

d. Optimal solution is E = 625, C =
1000 Total return = $27,375

2 - 24


An Introduction to Linear Programming

31.
B
6

Feasible
Region

4

2

A
0

2

4

6
3A + 4B = 13


Optimal Solution
A = 3, B = 1
Objective Function Value = 13
32.
BA
A

AB

2 - 25