Use the attached spreadsheet template to complete the assignment. Click on each of the tabs in the template to view each of the exercises.

Thanks

Ch 8 Ex 4

PMT472 3.2 ASSIGNMENT: WEEK 3 EXERCISES

CH. 8 EXERCISE 4

Given the network plan that follows, compute the early, late, and slack times. Using any approach you wish (e.g., trial and error), develop a loading chart for resource, electrical engineers (EE), and resource, mechanical engineers (ME).

Start

0

1

4

5

End

Legend

EE

EE

ME

ES

ID

EF

2

1

6

SL

Resource

SL

LS

DUR

LF

0

2

6

EE

ME

4

2

0

3

7

ME

EE

3

4

Loading Schedule

EE

ME

0

1

2

3

4

5

6

7

8

9

10

11

12

What is the project duration?

(Enter response)

Assume only one of each resource exists. Given your adjusted loading schedule, compute the early, late, and slack times for your project in the resource activity schedule.

Loading Schedule (adjusted for resource constraint)

EE

ME

0

1

2

3

4

5

6

7

8

9

10

11

12

Resource Activity Schedule (with resource constraint)

ID/RES

ES

LS

EF

LF

SL

1-EE

2-EE

3-ME

4-EE

5-ME

6-ME

7-EE

Which activities are now critical?

(Enter response)

What is the project duration now?

(Enter response)

Could something like this happen in real projects?

(Enter response)

Ch 9 Ex 1

PMT472 3.2 ASSIGNMENT: WEEK 3 EXERCISES

CH. 9 EXERCISE 1

Use the following information to compress one time unit per move using the least-cost method. Reduce the schedule until you reach the crash point of the network. For each move identify what activity or activities were crashed and the adjusted total direct cost. Note: The correct normal project duration, critical path, and total direct cost are provided. The crash cost is how much extra it will cost to crash the activity per time unit reduced. The maximum crash time is how many time units the activity can be reduced by. E.g. Activity D can be reduced by 2 time units down to 1 time unit for a total additional cost of $120.

Activity

Crash Cost (slope)

Maximum Crash Time

Normal Time

Normal Cost

A

$50

1

3

$150

B

$100

1

3

$100

C

$60

2

4

$200

D

$60

2

3

$200

E

$70

1

4

$200

F

$0

0

1

$150

Crash Round 1

B

D

What was crashed:

Activity A was reduced by 1 day (or time unit) from 3 days to 2 days.

3

3

Adjusted total direct cost:

$1,050

A

F

The cheapest activity to reduce is A so we reduce it by its maximum reduction of one time unit to two time units. The A-C-E-F path remains critical at 11 time units and direct costs go up to $1,050 since it cost $50 to crash A.

2

1

C

E

4

4

Crash Round 2

B

D

What was crashed:

(Enter response)

Adjusted total direct cost:

(Enter response)

A

F

C

E

Crash Round 3

B

D

What was crashed:

(Enter response)

Adjusted total direct cost:

(Enter response)

A

F

C

E

Crash Round 4

B

D

What was crashed:

(Enter response)

Adjusted total direct cost:

(Enter response)

A

F

C

E

Ch 9 Ex 2

PMT472 3.2 ASSIGNMENT: WEEK 3 EXERCISES

CH. 9 EXERCISE 2

Use the following information contained below to compress one time unit per move using the least-cost method.* Reduce the schedule until you reach the crash point of the network. For each move identify what activity or activities were crashed and the adjusted total direct cost. Note: Choose B instead of C and E (equal costs) because it is usually smarter to crash early rather than late AND one activity instead of two activities.

Activity

Crash Cost (slope)

Maximum Crash Time

Normal Time

Normal Cost

A

$0

2

$150

B

$100

1

3

$100

C

$50

2

6

$200

D

$40

1

4

$200

E

$50

1

3

$200

F

$0

0

1

$150

Crash Round 1

C

What was crashed:

(Enter response)

Adjusted total direct cost:

(Enter response)

A

B

F

D

E

Crash Round 2

C

What was crashed:

(Enter response)

Adjusted total direct cost:

(Enter response)

A

B

F

D

E

Crash Round 3

C

What was crashed:

(Enter response)

Adjusted total direct cost:

(Enter response)

A

B

F

D

E

Ch 9 Ex 3

PMT472 3.2 ASSIGNMENT: WEEK 3 EXERCISES

CH. 9 EXERCISE 3

Use the following information to compress one time unit per move using the least-cost method. Reduce the schedule until you reach the crash point of the network. For each move identify what activity or activities were crashed and the adjusted total direct cost.

Activity

Crash Cost (slope)

Maximum Crash Time

Normal Time

Normal Cost

A

$100

1

2

$150

B

$80

1

3

$100

C

$60

1

2

$200

D

$40

1

5

$200

E

$40

2

5

$200

F

$40

2

3

$150

G

$20

1

5

$200

H

$0

0

1

$200

Crash Round 1

C

F

What was crashed:

(Enter response)

B

Adjusted total direct cost:

(Enter response)

A

H

D

G

E

Crash Round 2

C

F

What was crashed:

(Enter response)

B

Adjusted total direct cost:

(Enter response)

A

H

D

G

E

Crash Round 3

C

F

What was crashed:

(Enter response)

B

Adjusted total direct cost:

(Enter response)

A

H

D

G

E

Crash Round 4

C

F

What was crashed:

(Enter response)

B

Adjusted total direct cost:

(Enter response)

A

H

D

G

E

Ch 9 Ex 4

PMT472 3.2 ASSIGNMENT: WEEK 3 EXERCISES

CH. 9 EXERCISE 4

Given the data and information that follow, compute the total direct cost for each project duration. If the indirect costs for each project duration are $90 (15 time units), $70 (14), $50 (13), $40 (12), and $30 (11), compute the total project cost for each duration.

NOTE: Total project cost = total direct cost + indirect cost.

Activity

Crash Cost (slope)

Maximum Crash Time

Normal Time

Normal Cost

A

$30

1

5

$50

B

$60

2

3

$60

C

$0

0

4

$70

D

$10

1

2

$50

E

$60

3

5

$100

F

$100

1

2

$90

G

$30

1

5

$50

H

$0

0

2

$60

I

$200

1

3

$200

Crash Round 1

C

F

What was crashed:

(Enter response)

A

Adjusted total direct cost:

(Enter response)

Indirect cost (given):

(Enter response)

D

G

I

Adjusted total project cost:

(Enter response)

B

E

H

Crash Round 2

C

F

What was crashed:

(Enter response)

A

Adjusted total direct cost:

(Enter response)

Indirect cost (given):

(Enter response)

D

G

I

Adjusted total project cost:

(Enter response)

B

E

H

Crash Round 3

C

F

What was crashed:

(Enter response)

A

Adjusted total direct cost:

(Enter response)

Indirect cost (given):

(Enter response)

D

G

I

Adjusted total project cost:

(Enter response)

B

E

H

Crash Round 4

C

F

What was crashed:

(Enter response)

A

Adjusted total direct cost:

(Enter response)

Indirect cost (given):

(Enter response)

D

G

I

Adjusted total project cost:

(Enter response)

B

E

H

What is the optimum cost-time schedule for the project? What is this cost?

(Enter response)

Ch 9 Ex 5

PMT472 3.2 ASSIGNMENT: WEEK 3 EXERCISES

CH. 9 EXERCISE 5

Use the following information to compress one time unit per move using the least-cost method. Assume the total indirect cost for the project is $700 and there is a savings of $50 per time unit reduced. Record the total direct, indirect, and project costs for each duration.

Activity

Crash Cost (slope)

Maximum Crash Time

Normal Time

Normal Cost

A

0

2

$100

B

$100

1

3

$200

C

$40

1

5

$200

D

$60

2

3

$200

E

$20

1

5

$200

F

$40

1

4

$150

G

$0

0

2

$150

Crash Round 1

B

D

What was crashed:

(Enter response)

Adjusted total direct cost:

(Enter response)

Adjusted total indirect cost:

(Enter response)

A

E

G

Adjusted total project cost:

(Enter response)

C

F

Crash Round 2

B

D

What was crashed:

(Enter response)

Adjusted total direct cost:

(Enter response)

Adjusted total indirect cost:

(Enter response)

A

E

G

Adjusted total project cost:

(Enter response)

C

F

What is the optimum cost-time schedule for the project? What is this cost?

(Enter response)

Ch 9 Ex 6

PMT472 3.2 ASSIGNMENT: WEEK 3 EXERCISES

CH. 9 EXERCISE 6

If the indirect costs for each duration are $300 for 27 days, $240 for 26 days, $180 for 25 days, $120 for 24 days, $60 for 23 days, and $50 for 22 days, compute the direct, indirect, and total costs for each duration.

Activity

Crash Cost (slope)

Maximum Crash Time

Normal Time

Normal Cost

A

$80

2

10

$40

B

$30

3

8

$10

C

$40

1

5

$80

D

$50

2

11

$50

E

$100

4

15

$100

F

$30

1

6

$20

Crash Round 1

A

D

What was crashed:

(Enter response)

Adjusted total direct cost:

(Enter response)

Indirect cost (given):

(Enter response)

B

F

Adjusted total project cost:

(Enter response)

C

E

Crash Round 2

A

D

What was crashed:

(Enter response)

Adjusted total direct cost:

(Enter response)

Indirect cost (given):

(Enter response)

B

F

Adjusted total project cost:

(Enter response)

C

E

Crash Round 3

A

D

What was crashed:

(Enter response)

Adjusted total direct cost:

(Enter response)

Indirect cost (given):

(Enter response)

B

F

Adjusted total project cost:

(Enter response)

C

E

Crash Round 4

A

D

What was crashed:

(Enter response)

Adjusted total direct cost:

(Enter response)

Indirect cost (given):

(Enter response)

B

F

Adjusted total project cost:

(Enter response)

C

E

Crash Round 5

A

D

What was crashed:

(Enter response)

Adjusted total direct cost:

(Enter response)

Indirect cost (given):

(Enter response)

B

F

Adjusted total project cost:

(Enter response)

C

E

What is the optimum cost-time schedule?

(Enter response)

The customer offers you $10 for every day you shorten the project from your original network. Would you take it? If so for how many days?

(Enter response)

Ch 9 Ex 7

PMT472 3.2 ASSIGNMENT: WEEK 3 EXERCISES

CH. 9 EXERCISE 7

Use the following information to compress one time unit per move using the least-cost method. Assume the total indirect cost for the project is $2,000 and there is a savings of $100 per time unit reduced. Calculate the total direct, indirect, and project costs for each duration. Plot these costs on a graph.

Activity

Crash Cost (slope)

Maximum Crash Time

Normal Time

Normal Cost

A

$0

0

2

$200

B

$50

1

4

$1,000

C

$200

2

5

$800

D

$200

2

5

$1,000

E

$100

1

3

$800

F

$40

1

5

$1,000

G

$40

1

4

$1,000

H

$0

0

1

$200

Crash Round 1

C

F

What was crashed:

(Enter response)

Adjusted total direct cost:

(Enter response)

A

B

E

H

Adjusted total indirect cost:

(Enter response)

Adjusted total project cost:

(Enter response)

D

G

Crash Round 2

C

F

What was crashed:

(Enter response)

Adjusted total direct cost:

(Enter response)

A

B

E

H

Adjusted total indirect cost:

(Enter response)

Adjusted total project cost:

(Enter response)

D

G

Crash Round 3

C

F

What was crashed:

(Enter response)

Adjusted total direct cost:

(Enter response)

A

B

E

H

Adjusted total indirect cost:

(Enter response)

Adjusted total project cost:

(Enter response)

D

G

Crash Round 4

C

F

What was crashed:

(Enter response)

Adjusted total direct cost:

(Enter response)

A

B

E

H

Adjusted total indirect cost:

(Enter response)

Adjusted total project cost:

(Enter response)

D

G

Crash Round 5

C

F

What was crashed:

(Enter response)

Adjusted total direct cost:

(Enter response)

A

B

E

H

Adjusted total indirect cost:

(Enter response)

Adjusted total project cost:

(Enter response)

D

G

NOTE: Enter data for the graph in the table below and the graph will automatically update.

Duration

Total Direct Cost

Total Indirect Cost

Total Project Cost

What is the optimum cost-time schedule for the project?

(Enter response)

Total Project Cost Breakdown

Total Direct Cost Total Indirect Cost Total Project Cost

Duration

Cost

Ch 9 Ex 8

PMT472 3.2 ASSIGNMENT: WEEK 3 EXERCISES

CH. 9 EXERCISE 8

Use the following information to compress one time unit per move using the least-cost method.* Reduce the schedule until you reach the crash point of the network. For each move identify what activity or activities were crashed and the adjusted total cost, and explain your choice if you have to choose between activities that cost the same. The indirect cost for each duration is $1,500 for 17 weeks, $1,450 for 16 weeks, $1,400 for 15 weeks, $1,350 for 14 weeks, $1,300 for 13 weeks, and $1,250 for 12 weeks.

Activity

Crash Cost (slope)

Maximum Crash Time

Normal Time

Normal Cost

A

$0

0

3

$150

B

$100

1

4

$200

C

$60

1

3

$250

D

$40

1

4

$200

E

$0

0

2

$250

F

$30

2

3

$200

G

$20

1

2

$250

H

$60

2

4

$300

I

$200

1

2

$200

Crash Round 1

B

F

G

What was crashed:

(Enter response)

Adjusted total direct cost:

(Enter response)

A

D

I

Indirect cost (given):

(Enter response)

Adjusted total project cost:

(Enter response)

C

E

H

Crash Round 2

B

F

G

What was crashed:

(Enter response)

Adjusted total direct cost:

(Enter response)

A

D

I

Indirect cost (given):

(Enter response)

Adjusted total project cost:

(Enter response)

C

E

H

What is the optimum cost-time schedule for the project? What is this cost?

(Enter response)

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