PROBLEMS
1.
Mabel’s Ceramics spent $3000 on a new
kiln last year, in the belief that it would cut energy usage 25% over the old
kiln. This kiln is an oven that turns “greenware” into finished
pottery. Mabel is concerned that the new kiln requires extra labor hours for
its operation. Mabel wants to check the energy savings of the new oven, and
also to look over other measures of their productivity to see if the change
really was beneficial. Mabel has the following data to work with:

The
year before

Year
just ended

Production (finished units)

4000

4100

Labor (hrs)

350

375

Capital ($)

15000

18000

Energy (kWh)

3000

2600

Also, suppose that the average labor
cost is $12 per hour and cost of energy is $0.40 per kwh.
a.
Were the modifications beneficial? (Compute labor, energy, and capital
productivity for the two years and compare.)
b.
Compute percentage change in
multi-factor productivity of the year just ended from that of year before.
c.
If the multifactor productivity must be
restored next year to what is was the year before, assuming the same output
next year as the year just ended, by how the input must be reduced from what it
is this year?

2.
An Appliance Service company made house calls
and repaired 10 lawn-mowers, 2 refrigerators, and 3 washers in an 8-hour day
with his standard crew of 3 workers. The
retail price for each respective service is $50, $200, and $120. The average wage for the workers is $12 per
hour. The materials cost for a day was
$200 while the overhead cost was $50.
a. What is the company’s labor productivity?
b. What is the multifactor productivity?
c. How much of a reduction in input is
necessary for a 5% increase in multifactor productivity?

3.
Consider
the tasks, durations, and predecessor relationships in the following network.
Draw the AON network and answer the questions that follow.

Activity Description

Immediate
Predecessor(s)

Optimistic
(Weeks)

Most Likely
(Weeks)

Pessimistic
(Weeks)

A

—

4

7

10

B

A

2

8

20

C

A

8

12

16

D

B

1

2

3

E

D, C

6

8

22

F

C

2

3

4

G

F

2

2

2

H

F

6

8

10

I

E, G

4

8

12

J

I

1

2

3

a.
Schedule the activities of this project
and determine (i) the expected project completion time, (ii) the earliest and
latest start and finish times, and the slack for all the activities, and (iii)
all the critical paths.
b.
What is the probability of completion of
the project before week 42?
c.
What is the probability of completion of
the project before week 35?
d.
With 99% confidence what is your
estimate for the project completion time.

4.
Consider
the following project. All activity
times are in weeks.

Activity

Immediate
Predecessor(s)

Normal Time

Crash time

Normal cost

Crash cost

A

–

7

4

20000

38000

B

–

8

5

50000

74000

C

A

9

7

80000

110000

D

A, B

8

8

30000

30000

E

B

9

8

10000

12000

F

C

10

8

90000

124000

G

D, E

5

5

25000

25000

H

E

10

8

32000

40000

I

F, G

5

4

28000

35000

a.
Draw an AON network.
b.
Identify all the unique paths from
start to finish and determine the critical path, normal project completion
time, and normal project cost.
c.
Compute MTR, Cost of
crashing/week.
d.
Which activity would you crash
first and by how many weeks?
e.
Determine the project time and
cost after crashing the activity selected in (d).

5.
Consider
the following CPM Solver model.
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a) Determine the successor activities in cells
I2 to I10.
b) Determine the Excel formulas for the following
cells: F2, G2, C15, C18, D18, D21, C25, G19, G16, G15, H15, B27, B28, and B29.
c) What is the Solver Target cell for
minimizing the project completion time?
d) What is the Solver changing cell range?
e) What are the Solver constraints?