1. SAE 599 - Modeling and Simulation for �Systems Architecting and Engineering Dr. Raymond Madachy
September 26, 2007
2. Outline Course Project Status
Continuous Systems Modeling with Demonstrations
Extend Demonstration
3. Course Project Status Projects
Tony DiCarlo - xx
Jared Fortune EZSIM II architecting and acceptance testing (EZSIM)
Pernell Gray - Airport system delays
Ben Haas - Laser clearinghouse
Harry Johnson Sustaining engineering for the International Space Station integration processes (Simulink)
Lloyd Matthews xx
Mauricio Pea - Fotochatter social network
Jared Smith - Resource adaptability model for disasters and terrorist attacks
David Voracek - NASA Dryden hiring and training process
Initial status presentations extended to October 10
4. Continuous Systems Examples Hiring delay
Learning curves
Exhaustion
Rayleigh effort curve
ODC COQUALMO defect dynamics
Earned value
Integrated project model
Inspection model
Some are discrete systems modeled as continuous
5. Delays Time delays are ubiquitous in processes
They are important structural components of feedback systems.
Example: hiring delays in software development.
the average hiring delay represents the time that a personnel requisition remains open before a new hire comes on board
6. Learning Curve
7. Learning Curve Models
8. Exhaustion Model Assumptions Workers increase their effective hours by decreasing slack time or working overtime
The maximum shortage that can be handled varies.
Workers are less willing to work hard if deadline pressures persist for a long time.
The overwork duration threshold increases or decreases as people become more or less exhausted.
The exhaustion level also increases with overwork.
The multiplier for exhaustion level is 1 when people work full 8 hour days, and goes over 1 with overtime. The exhaustion increases at a greater rate in overtime mode up to the maximum tolerable exhaustion.
The exhaustion level slowly decreases when the threshold is reached or deadline pressures stop with an exhaustion depletion delay.
During this time, workers dont go into overwork mode again until the exhaustion level is fully depleted.
9. Exhaustion Model
10. Exhaustion Model Relationships
11. Exhaustion Behavior
12. Rayleigh Manpower Distribution Rayleigh curve is a popular model of personnel loading
Assumptions:
Only a small number of people are needed at the beginning of a project to carry out planning and specification. As the project progresses and more detailed work is required, the number of staff builds up to a peak. After implementation and unit testing is complete, the number of staff required starts to fall until the product is delivered.
The number of people working on a project is approximately proportional to the number of problems ready for solution at that time
13. Rayleigh Formula A Rayleigh curve describes the rate of change of manpower effort per the following first order differential equation:
where C(t) is the cumulative effort at time t, K is the total effort, and p(t) is a learning function. The learning function is linear and can be represented by
where a is a positive number.
The manpower rate of change represents the number of people involved in development at any time (staffing profile).
The a parameter is an important determinant of the peak personnel loading called the manpower buildup parameter.
14. Rayleigh Curve Applicability Rayleigh curve was based on initial studies of hardware research and development
projects resemble traditional waterfall development for unprecedented systems
Rayleigh staffing assumptions dont hold well for COTS, reuse, architecture-first design patterns, 4th generation languages or staff-constrained situations
However an ideal staffing curve is proportional to the number of problems ready for solution (from a product perspective).
15. Rayleigh Model
16. Interactive Rayleigh Model Demo
17. Dynamic ODC COQUALMO Portion Portion for Requirements Completeness defects only:
18. Dynamic ODC COQUALMO Sample Outputs Example of applying increased V&V for Execution Testing and Tools at 18 months:
19. Earned Value Earned value is a method for measuring project performance.
It compares the amount of work that was planned with what was actually accomplished to determine if cost and schedule performance is as planned.
Cost performance index (CPI) is the ratio of budgeted costs to actual costs (BCWP/ACWP)
Schedule performance index (SPI) is the ratio of work performed to work scheduled (BCWP/BCWS)
20. Guidelines for Using Earned Value If effort is more than 15% complete and your baseline estimates are being overrun, you cannot recover.
The overrun at completion will be greater than current overrun (based on over 700 DoD contracts).
far term estimates are probably worse than short-term estimates
Adjust far-term estimates and figure out how to not get worse.
21. �Earned Value Example Project #2 (hard problems first)
finishes sooner
22. Earned Value Model
23. Introduction to Inspection Model Research problem addressed
What are the dynamic effects to the process of performing inspections?
Model used to evaluate process quantitatively
demonstrates effects of inspection practices on cost, schedule and quality throughout lifecycle
can experiment with changed processes before committing project resources
benchmark process improvement
support project planning and management
Model parameters calibrated to Litton and JPL data
error generation rates, inspection effort, efficiency, productivity, others
Model validated against industrial data
24. System Diagram
26. Effects of Inspections
27. Inspection Policy Tradeoff Analysis Varying error generation rates shows diminishing returns from inspections [Madachy 94]:
28. Derivation of Phase Specific Cost Driver
29. Contributions of Inspection Model Demonstrated dynamic effects of performing inspections.
New knowledge regarding interrelated factors of inspection effectiveness.
Demonstrated complementary features of static and dynamic models.
Techniques adopted in industry.
30. Abdel-Hamid Integrated Project Model
31. Abdel-Hamid Model Behavior
32. QA Policy Tradeoff Analysis
33. Planning
34. Human Resources
35. Estimation
36. Manpower Allocation
37. Testing
38. Control (1/2)
39. Control (2/2)
40. Quality Assurance
41. Software Development Productivity
42. Software Development
