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Time-Cost optimisation
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Transcript of Time-Cost optimisation
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Time-Cost Optimisation
ByDr. Mahdi Damghani
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Objective
To determine a reduced or optimum length of contract and still save money
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Introduction
The use of CPM is not limited to calculation of project duration
Reducing the duration of projects leads to cost consideration
Reducing the time of project may lead to increase in cost due to use of more resources
There must be a balanced point wherein the project finishes at minimum cost and optimum duration
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Direct costs
As the project is conceived, cost is incurred on the purchase of Materials Plant Equipment Manpower
Relationship of direct costs with time is of rime importance
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Direct costs
There is an optimum duration for a project for which the direct cost is a minimum
During this time the resources are optimally used
This duration is called Normal Duration
Crash point is a point beyond which the project duration can not be decreased irrespective of the increase in direct costs
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Direct costs
Cost
Time Crash time Normal time
Crash Point
Normal PointNormal cost
Crash cost
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Indirect costs
Includes Overheads Administrative expenses Depreciation Loss of profit Loss of revenue Penalty
The loss in profit, penalty comes under a category called outage loss
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Indirect costs
Cost
Time Crash time Normal time
Supervisory and overheads
Outage loss
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Total cost
Direct cost + Indirect costCost
Time Crash time Normal time
Indirect cost
Direct cost
Total cost
Optimum time
Optimum cost
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Some terms
Normal time (tn) Standard time that an estimator normally allow for an activity
Crash time (tc) Minimum possible time in which an activity can be
completed, by employing extra resources Normal cost(Cn) Direct cost required to complete the activity in the normal
time duration Crash cost(Cc) Direct cost corresponding to the completion of the activity
within crash time Cost slope (Cs) Slope of the line(s) used to approximate the direct cost curve
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Cost slope
t
c
tt
CCC
cn
ncs
Increase in cost
Decrease in time
Note:If the cost curve is approximated by one single line it will have only one cost slope whereas if it is approximated by more than one line it would adopt more cost slopes and more calculations, respectively.
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Using network analysis
The project time is controlled by the activities lying on the critical path
To minimize the cost we crash the critical activities.
Particularly, critical activity with minimum cost slope must be crashed first
At each and every time check whether the critical path is unique
If not, crash the activity one by one
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Example 1
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Solution 1
Critical path is 1-2-3-5-6 Length of critical path
=6+14+12+8=40 Calculate the cost slop for each
activity and rank them in descending order
Activity
Cost slope
Ranking
1-2 20 3
2-3 14 2
3-5 12 1
1-4 20 4
4-5 120 6
5-6 100 5
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Solution 1
Instruction Extra direct cost
New project duration
New direct cost
New indirect cost
New project cost
Normal overall duration
_ 40 1030 0 1030
3-5 (5) 5x12=60 40-5=35 1090 0 1090
2-3 (5) 5x14=70 35-5=30 1160 0 1160
1-2 (2) 2x20=40 30-2=28
1-2 (1) 1x20=20 30-1=29 1180 0 1180
1-4 (1) 1x20=20 29-1=28 1200 0 1200
Activity
Cost slope
Ranking
1-2 20 3
2-3 14 2
3-5 12 1
1-4 20 4
4-5 120 6
5-6 100 5
By doing this the critical path changes to 1-4-5-6 so I reduce 1-2 by 1 day
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Solution 1 Instruction Extra
direct cost
New project duration
New direct cost
New indirect cost
New project cost
Normal overall duration
_ 40 1030 0 1030
3-5 (5) 5x12=60 40-5=35 1090 0 1090
2-3 (5) 5x14=70 35-5=30 1160 0 1160
1-2 (2) 2x20=40 30-2=28
1-2 (1) 1x20=20 30-1=29 1180 0 1180
1-4 (1) 1x20=20 29-1=28 1200 0 1200
By doing this the critical path changes to 1-4-5-6 so I reduce 1-2 by 1 day
Now we have two parallel critical paths with duration 29 days. (i.e. 1-2-3-5-6 & 1-4-5-6)The following are the activities yet to be crashed. They are 1 - 4, 4 - 5 and 5 - 6. Of the 3 activities 1 - 4 is with minimum cost slope.
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Solution 1
Therefore, a 28-day project schedule costs 1200 pounds
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Example 2 The following data shows the
duration and costs of each activity of a project. The indirect cost of the project is £3000 per week. Determine the optimum duration of project and the corresponding minimum cost.
Activity Normal Duratio
n (week)
Normal Cost (£)
Crash Duration (week)
Crash Cost (£)
1-2 6 7000 3 14500
1-3 8 4000 5 8500
2-3 4 6000 1 9000
2-4 5 8000 3 15000
3-4 5 5000 3 11000
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Solution 2
1 4
2
3
N6C3
N8C5
N4C1
N5C3
N5C3
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Solution 2
Critical path is 1-2-3-4 = 15 weeks
Notes:1. The critical path must remain critical whilst
crashing2. When you have more than one critical path,
crash the common activities to the same amount to maintain the first condition
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Solution 2
Activity ΔC (£) Δt (weeks)
Cost slope (£/week)
Rank
1-2 14500-7000=7500
6-3=3 2500 3
1-3 8500-4000=4500
8-5=3 1500 2
2-3 9000-6000=3000
4-1=3 1000 1
2-4 15000-8000=7000
5-3=2 3500 5
3-4 11000-5000=6000
5-3=2 3000 4
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Solution 2
Instruction Extra direct cost
New project duration
New direct cost
New indirect cost
New project cost
Normal overall duration
_ 15 30000 15x3000= 45000
45000+30000=75000
2-3 (2) 2x1000=2000
15-2=13 32000 13x3000 71000
2-3 (1) & 1-3 (1)
1x1000+1x1500=2500
13-1=12 34500 12x3000 70500
3-4 (1) 1x3000=3000
12-1=11 37500 11x3000 70500
1-2 (2) & 1-3 (2)
2x1500+2x2500=8000
11-2=9 45500 9x3000 72500
3-4 (1) & 2-4 (1)
3000+3500=6500
9-1=8 52000 8x3000 76000
Activity Cost slope (£/week)
Rank
1-2 2500 3
1-3 1500 2
2-3 1000 1
2-4 3500 5
3-4 3000 4
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Solution 2
From the table on the last slide the minimum cost is 70500 for duration of 11 weeks
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Example 3
Activity Normal Duratio
n (week)
Normal Cost (£)
Crash Duration (week)
Crash Cost (£)
10-20 2 1000 2 1000
10-30 7 500 3 900
20-30 6 300 3 420
20-40 5 200 4 250
30-40 0 0 0 0
30-50 9 600 4 900
40-60 11 600 6 1000
50-60 6 700 3 910
Determine minimum cost and optimum duration
Indirect cost is £80 per day
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Solution 3
Optimum project duration is 18 days Corresponding cost=£4320