Project Planning and Budgeting

1. Project Planning and Budgeting

2. Recall the four stages • Project Definition and Conceptualization • Project Planning and Budgeting • Project Execution and Control • Project Termination and Closeout

3. Elements Of Project Management • Project team • individuals from different departments within company • Matrix organization • team structure with members from different functional areas depending on skills needed • Project manager • leader of project team Ch 17 - 2

4. Project Planning • Statement of work • written description of goals, work & time frame of project • Activities require labor, resources & time • Precedence relationship shows sequential relationship of project activities Ch 17 - 3

5. WORK BREAKDOWN 1

6. WORK BREAKDOWN 2

7. GANTT CHART

8. 1 2 3 Simplified Project Network Construct forms Pour concrete © 2000 by Prentice-Hall Inc Russell/Taylor Oper Mgt 3/e Ch 17 - 4

9. PERT CHART 1

10. PERT CHART 2

11. Elements Of Project Planning • Define project objective(s) • Identify activities • Establish precedence relationships • Make time estimates • Determine project completion time • Compare project schedule objectives • Determine resource requirements to meet objective Ch 17 - 5

12. Work breakdown structure (WBS) • determine subcomponents, activities & tasks © 2000 by Prentice-Hall Inc Russell/Taylor Oper Mgt 3/e Ch 17 - 6

13. Gantt Chart • Popular tool for project scheduling • Graph with bar for representing the time for each task • Provides visual display of project schedule • Also shows slack for activities • (amount of time activity can be delayed without delaying project) © 2000 by Prentice-Hall Inc Russell/Taylor Oper Mgt 3/e Ch 17 - 7

14. A Gantt Chart Month 0 2 4 6 8 10      Activity Design house and obtain financing Lay foundation Order and receive materials Build house Select paint Select carpet Finish work      1 3 5 7 9 Ch 17 - 8 Month

15. CPM/PERT • Critical Path Method (CPM) • DuPont & Remington-Rand (1956) • deterministic task times • activity-on-node network construction • Project Eval. & Review Technique (PERT) • US Navy, Booz, Allen & Hamilton • multiple task time estimates • activity-on-arrow network construction Ch 17 - 9

16. 1 2 3 The Project Network Network consists of branches & nodes Node Branch Ch 17 - 10

17. Network Construction • In AON, nodes represent activities & arrows show precedence relationships • In AOA, arrows represent activities & nodes are events for points in time • An event is the completion or beginning of an activity • A dummy shows precedence for two activities with same start & end nodes Ch 17 - 11

18. Project Network For A House 3 Dummy Lay foundation 0 Build house Finish work 2 3 1 7 6 1 2 4 3 1 Design house and obtain financing Order and receive materials 1 1 Select paint Select carpet 5 © 2000 by Prentice-Hall Inc Russell/Taylor Oper Mgt 3/e Ch 17 - 12

19. Critical Path • A path is a sequence of connected activities running from start to end node in network • The critical path is the path with the longest duration in the network • Project cannot be completed in less than the time of the critical path Ch 17 - 13

20. All Possible Paths A: 1-2-3-4-6-7 3 + 2 + 0 + 3 + 1 = 9 months; the critical path B: 1-2-3-4-5-6-7 3 + 2 + 0 + 1 + 1 + 1 = 8 months C: 1-2-4-6-7 3 + 1 + 3 + 1 = 8 months D: 1-2-4-5-6-7 3 + 1 + 1 + 1 + 1 = 7 months Ch 17 - 14

21. Lay foundation 3 2 Order material Concurrent Activities 3 Lay foundation Dummy 2 4 Order material Incorrect precedence relationship Correct precedence relationship © 2000 by Prentice-Hall Inc Russell/Taylor Oper Mgt 3/e Ch 17 - 15

22. Early Times(Housebuilding example) • ES - earliest time activity can start • Forward pass starts at beginning of CPM/PERT network to determine ES times • EF = ES + activity time • ESij = maximum (EFi) • EFij = ESij + tij • ES12 = 0 • EF12 = ES12 + t12 = 0 + 3 = 3 months © 2000 by Prentice-Hall Inc Russell/Taylor Oper Mgt 3/e Ch 17 - 16

23. Computing Early Times • ES23 = max (EF2) = 3 months • ES46 = max (EF4) = max (5,4) = 5 months • EF46 = ES46 + t46 = 5 + 3 = 8 months • EF67 =9 months, the project duration © 2000 by Prentice-Hall Inc Russell/Taylor Oper Mgt 3/e Ch 17 - 17

24. Late Times • LS - latest time activity can start & not delay project • Backward pass starts at end of CPM/PERT network to determine LS times • LF = LS + activity time • LSij = LFij - tij • LFij = minimum (LSj) © 2000 by Prentice-Hall Inc Russell/Taylor Oper Mgt 3/e Ch 17 - 18

25. Computing Late Times • LF67 = 9 months • LS67 = LF67 - t67 = 9 - 1 = 8 months • LF56 = minimum (LS6) = 8 months • LS56 = LF56 - t56 = 8 - 1 = 7 months • LF24 = minimum (LS4) = min(5, 6) = 5 months • LS24 = LF24 - t24 = 5 - 1 = 4 months © 2000 by Prentice-Hall Inc Russell/Taylor Oper Mgt 3/e Ch 17 - 19

26. ES=5, EF=5 LS=5, LF=5 ( ) ES=3, EF=5 LS=3, LF=5 ( ) ES=8, EF=9 LS=8, LF=9 ( ) ES=5, EF=8 LS=5, LF=8 ( ) ES=3, EF=4 LS=4, LF=5 ( ) ES=0, EF=3 LS=0, LF=3 ( ) ES=6, EF=7 LS=7, LF=8 ( ) ES=5, EF=6 LS=6, LF=7 ( ) Early And Late Times 3 0 2 3 1 7 6 1 2 4 3 1 1 1 5 © 2000 by Prentice-Hall Inc Russell/Taylor Oper Mgt 3/e Ch 17 - 20

27. Activity Slack • Activities on critical path have ES=LS & EF=LF • Activities not on critical path have slack • Sij = LSij - ESij • Sij = LFij - EFij • S24 = LS24 - ES24 = 4 - 3 = 1 month © 2000 by Prentice-Hall Inc Russell/Taylor Oper Mgt 3/e Ch 17 - 21

28. Activity Slack Data Activity LS ES LF EF Slack (S) 1-2* 0 0 3 3 0 2-3 3 3 5 5 0 2-4 4 3 5 4 1 3-4* 5 5 5 5 0 4-5 6 5 7 6 1 4-6* 5 5 8 8 0 5-6 7 6 8 7 1 6-7* 8 8 9 9 0 * Critical path © 2000 by Prentice-Hall Inc Russell/Taylor Oper Mgt 3/e Ch 17 - 22

29. a + 4m + b t = Mean (expected time): 6 b - a ( ) Variance: 2 = 6 Probabilistic Time Estimates • Reflect uncertainty of activity times • Beta distribution is used in PERT 2 Where, a = optimistic estimate m = most likely time estimate b = pessimistic time estimate © 2000 by Prentice-Hall Inc Russell/Taylor Oper Mgt 3/e Ch 17 - 23

30. P (time) a t m Example Beta Distributions P (time) b a b m t P (time) a b m = t © 2000 by Prentice-Hall Inc Russell/Taylor Oper Mgt 3/e Ch 17 - 24

31. PERT Example Equipment testing and modification 2 6 Final debugging Dummy Equipment installation System Training 1 3 5 7 9 System development Manual Testing System changeover System Testing Job training Dummy Position recruiting Orientation 4 8 © 2000 by Prentice-Hall Inc Russell/Taylor Oper Mgt 3/e Ch 17 - 25

32. Activity Information Time estimates (wks) Mean Time Variance Activity a b c t 2 1 - 2 6 8 10 8 .44 1 - 3 3 6 9 6 1.00 1 - 4 1 3 5 3 .44 2 - 5 0 0 0 0 .00 2 - 6 2 4 12 5 2.78 3 - 5 2 3 4 3 .11 4 - 5 3 4 5 4 .11 4 - 8 2 2 2 2 .00 5 - 7 3 7 11 7 1.78 5 - 8 2 4 6 4 .44 7 - 8 0 0 0 0 .00 6 - 9 1 4 7 4 1.00 7 - 9 1 10 13 9 4.00 © 2000 by Prentice-Hall Inc Russell/Taylor Oper Mgt 3/e Ch 17 - 26

33. Early And Late Times Activity t 2 ES EF LS LF S 1 - 2 8 0.44 0 8 1 9 1 1 - 3 6 1.00 0 6 0 6 0 1 - 4 3 0.44 0 3 2 5 2 2 - 5 0 0.00 8 8 9 9 1 2 - 6 5 2.78 8 13 16 21 8 3 - 5 3 0.11 6 9 6 9 0 4 - 5 4 0.11 3 7 5 9 2 4 - 8 2 0.00 3 5 14 16 11 5 - 7 7 1.78 9 16 9 16 0 5 - 8 4 0.44 9 13 12 16 3 7 - 8 0 0.00 13 13 16 16 3 6 - 9 4 1.00 13 17 21 25 8 7 - 9 9 4.00 16 25 16 25 0 © 2000 by Prentice-Hall Inc Russell/Taylor Oper Mgt 3/e Ch 17 - 27

34. ES=8, EF=13 LS=16 LF=21 ( ) ES=0, EF=8 LS=1, LF=9 ES=13, EF=25 LS=16 LF=25 ( ) ( ) ES=8, EF=8 LS=9, LF=9 ( ) ES=0, EF=6 LS=0, LF=6 ES=9, EF=13 LS=9, LF=16 ( ) ( ) ES=6, EF=9 LS=6, LF=9 ES=13, EF=25 LS=16 LF=25 ( ) ( ) ES=9, EF=13 LS=12, LF=16 ( ) ES=0, EF=3 LS=2, LF=5 ( ) ES=13, EF=13 LS=16 LF=16 ES=3, EF=7 LS=5, LF=9 ( ) ( ) ES=3, EF=5 LS=14, LF=16 ( ) Network With Times 2 6 5 8 4 0 3 9 1 3 5 7 9 6 7 0 4 3 4 2 4 8 © 2000 by Prentice-Hall Inc Russell/Taylor Oper Mgt 3/e Ch 17 - 28

35. Project Variance • Project variance is the sum of variances on the critical path © 2000 by Prentice-Hall Inc Russell/Taylor Oper Mgt 3/e Ch 17 - 29

36. x -  Z =  Probabilistic Network Analysis Determine probability that project is completed within specified time where  = tp = project mean time  = project standard deviation x = proposed project time Z = number of standard deviations x is from mean © 2000 by Prentice-Hall Inc Russell/Taylor Oper Mgt 3/e Ch 17 - 30

37. Normal Distribution Of Project Time Probability Z  = tp x Time © 2000 by Prentice-Hall Inc Russell/Taylor Oper Mgt 3/e Ch 17 - 31

38. Probabilistic Analysis Example What is the probability that the project is completed within 30 weeks? © 2000 by Prentice-Hall Inc Russell/Taylor Oper Mgt 3/e Ch 17 - 32

39. . . . . . . . . . . . . Determining Probability From Z Value Z 0.00 0.01 ... 0.09 1.9 0.4713 0.4719 … 0.4767 P( x<= 30 weeks) = 0.9719  = 25 x = 30 Time (weeks) © 2000 by Prentice-Hall Inc Russell/Taylor Oper Mgt 3/e Ch 17 - 33

40. What is the probability that the project is completed within 22 weeks? P( x<= 22 weeks) =0.1271 x = 22  = 25 Time (weeks) © 2000 by Prentice-Hall Inc Russell/Taylor Oper Mgt 3/e Ch 17 - 34

41. Project Crashing • Crashing is reducing project time by expending additional resources • Crash time is an amount of time an activity is reduced • Crash cost is the cost of reducing the activity time • Goal is to reduce project duration at minimum cost © 2000 by Prentice-Hall Inc Russell/Taylor Oper Mgt 3/e Ch 17 - 35

42. House-building Network Activity times in weeks 3 0 8 12 4 7 6 1 2 4 12 4 4 4 5 © 2000 by Prentice-Hall Inc Russell/Taylor Oper Mgt 3/e Ch 17 - 36

43. Normal Activity And Crash Data Total Normal Crash Allowable Crash Time Time Normal Crash Crash Time Cost per Activity (wks) (wks) Cost Cost (wks) Week 1-2 12 7 $3,000 $5,000 5 $400 2-3 8 5 2,000 3,500 3 500 2-4 4 3 4,000 7,000 1 3,000 3-4 0 0 0 0 0 0 4-5 4 1 500 1,100 3 200 4-6 12 9 50,000 71,000 3 7,000 5-6 4 1 500 1,100 3 200 6-7 4 3 15,000 22,000 1 7,000 $75,000 $110,700 © 2000 by Prentice-Hall Inc Russell/Taylor Oper Mgt 3/e Ch 17 - 37

44. Network With Crashing Costs Activity 1-2 can be crashed a total of 5 weeks for $2000 Crash cost per week = Total crash cost/Total crash time = $2,000/5 = $400 per week 3 $500 0 8 $7,000 12 $7,000 4 7 6 1 2 4 12 4 $400 $3,000 4 4 $200 $200 5 © 2000 by Prentice-Hall Inc Russell/Taylor Oper Mgt 3/e Ch 17 - 38

45. 7,000 6,000 5,000 4,000 3,000 2,000 1,000 0 2 4 6 8 10 12 14 Normal And Crash Relationships $ Crash cost Crashed activity Slope = crash cost per week Normal cost Normal activity Crash time Normal time Weeks © 2000 by Prentice-Hall Inc Russell/Taylor Oper Mgt 3/e Ch 17 - 39

46. Crashing Solution Normal Crash Crash Crash Crashing Time Time Time Cost per Cost Activity (wks) (wks) Used Week Incurred 1-2 12 7 5 $400 $2,000 2-3 8 5 3 500 1,500 2-4 4 3 0 3,000 0 3-4 0 0 0 0 0 4-5 4 1 0 200 0 4-6 12 9 3 7,000 21,000 5-6 4 1 0 200 0 6-7 4 3 1 7,000 7,000 12 $31,500 © 2000 by Prentice-Hall Inc Russell/Taylor Oper Mgt 3/e Ch 17 - 40

47. Crashed Project 3 8 5 0 4 3 12 9 12 7 7 6 1 2 4 4 3 4 4 5 Original time Crashed times © 2000 by Prentice-Hall Inc Russell/Taylor Oper Mgt 3/e Ch 17 - 41

48. Time-Cost Relationship • Crashing costs increase as project duration decreases • Indirect costs increase as project duration increases • Reduce project length as long as crashing costs are less than indirect costs © 2000 by Prentice-Hall Inc Russell/Taylor Oper Mgt 3/e Ch 17 - 42

49. Time-Cost Tradeoff Minimum cost = optimal project time Total cost Cost ($) Indirect cost Direct cost Time Crashing Project Duration © 2000 by Prentice-Hall Inc Russell/Taylor Oper Mgt 3/e Ch 17 - 43