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Systems Engineering Case Studies

Systems Engineering Case Studies. Charles M. Garland Air Force Center for Systems Engineering (937) 255-3355 x3368 Charles.Garland@us.af.mil Dr John Colombi Dept of Systems and Engineering Mgt Air Force Institute of Technology. October 3, 2008. Agenda.

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Systems Engineering Case Studies

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  1. Systems Engineering Case Studies Charles M. Garland Air Force Center for Systems Engineering (937) 255-3355 x3368 Charles.Garland@us.af.mil Dr John Colombi Dept of Systems and Engineering Mgt Air Force Institute of Technology October 3, 2008

  2. Agenda • Air Force Center for Systems Engineering • Case Studies • Case Framework/ Approach • Learning Principles • Teaching Systems Engineering Cases

  3. Air Force Center for Systems Engineering

  4. AF CSE Vision and Mission Vision: Become a national center of excellence for systems engineering, from theory to application, for the defense community. Mission: Shape the future of systems engineering in the AF and DoD to improve our ability to deliver war-fighting capabilities. We will accomplish this by conceptualizing new processes, practices, tools, and resources for the SE workforce through research, education, and consultation.

  5. AF CSE Leadership Director Mr. George Mooney Deputy Director Technical Director Col. John Camps Mr. G. Richard Freeman Education & Training Division Applications & Development Division Curriculum Chair for Systems Engineering Maj. Jeffrey Havlicek Mr. Mike Ucchino Dr. David Jacques

  6. Systems Engineering Case Studies • Began under the academic oversight of a Subcommittee on Systems Engineering to the Air University Board of Visitors • Chaired by Air Force Chief Scientist Dr. Alex Levis • Selected four programs for initial case studies (Hubble Space Telescope, Theater Battle Management Core System, F-111, and C-5) • AF CSE Strategic Plan for Case Studies • Five year plan updated every three years • Identified, evaluated, and prioritized candidate programs

  7. Completed Case Studies Hubble Space Telescope GPS (Global Positioning System) F-111 Aardvark B-2 C-5 Galaxy TBMCS (Theater Battle Management Core Systems) Peacekeeper Intercontinental Ballistic Missile A-10

  8. Ongoing & Future Case Studies International Space Station E-10 MH-53J/M Helicopter on contract FY10 Option FY09 Option underway Global Hawk T-6A Texan II KC-135 Simulators on contract FY09 Option underway underway

  9. Based on student heuristics, developed by: Dr George Friedman: University of Southern California Dr Andy Sage: George Mason University Comprised of 9 concept domains (rows) & 3 responsibility domains (columns) Rows represent phases in SE life cycle & necessary process and systems management support Columns depict responsibilities from both sides of the program (industry and government) Derived into matrix - Identifies learning principles Used to organize the case writing Friedman-Sage Framework * Case Studies of Systems Engineering and Management in Systems Acquisition. Systems Engineering, Vol.7, No. 1, 2004

  10. Friedman-Sage Framework

  11. Peacekeeper Learning Principles

  12. Peacekeeper LP1 • Development commands must manage their technology base to optimize progress over several programs. • Ballistic Missile Office (BMO) developed and managed a technology base that spanned several programs • Atlas, Titan, Minuteman, Peacekeeper and Small ICBM • This matured technologies such as: • Solid rocket propellants • Nozzle manufacture • Liquid fueled engines • Guidance systems

  13. GPS Learning Principles

  14. GPS Learning Principle 2 The systems integrator must rigorously maintain program baselines Joint Program Office (JPO) retained the role of managing and controlling the systems specification This allowed control of functional baseline JPO derived and constructed an “agreed-to” set of systems requirements that became the program baseline Performance/Risk/Cost trade studies against functional baseline Interface Control Working Group managed the functional requirements of the allocated baseline Processes gave JPO first-hand knowledge and insight into risks at lowest level

  15. Hubble Learning Principles

  16. Hubble Learning Principle For complex programs, the number of players (government and contractor) demands that the program be structured to cope with high risk factors in many management and technical areas Contractors Lockheed (LMSC) and Perkin-Elmer (P-E) “owned” very significant and unique program risk areas LM was the overall integrator P-E was the technical expert in the critical optical system Lack of insight into quality assurance led directly to the primary mirror defects, in spite of substantial evidence otherwise

  17. Synopsis of Learning Principles • Created as a reference tool for practitioners • Categorizes LPs • Consider adopting the approach highlighted • Problem to be avoided • Will be updated as more case studies are completed

  18. Learning Principle Distribution

  19. Case Study Availability http://www.afit.edu/cse/cases.cfm

  20. Support teaching of Systems Engineering principles Systems engineering/ programmatic decisions Operational effectiveness Processes, principles, tools Decision material Highlight the importance of skills from multiple functional areas, including multiple engineering disciplines Audience – students in a classroom? Audience – practitioners (engineers/management) throughout the organization? Can a single case address both? Case Study Audience?

  21. Format is different for the audience Students Typical Harvard Business School case Chronologic story emphasizing decision making Shorter length of typically 10-30 pages No “answers”, guided discussion and personal discovery Practitioners Executive Summary Detailed treatment of Systems Engineering activity What to avoid - What to emphasize/apply We attempt to blend both SE Case Study Format

  22. For Practitioners (Part 1) Executive Summary Description of the Learning Principles Students (Case Body Part 2) Systems Engineering Intro/ Appropriate guidance System Description Detailed Chronology Insightful Questions Appendix Material -Trade studies, reviews, Requirements, architecture, other analysis SE Case Study Format

  23. Case Study Scope • Need to understand scope as key controlling factor • Time/ Schedule • Total Resources • Outline/ Page Allocation • Scope! Focus on 4-6 LP • Apply a framework • Assessment • Reference

  24. Don’t confuse operational system success with systems engineering success C-5 example: Heavy-lift aircraft capable of carrying multiple tanks and related equipment Maximum take-off Gross Weight over 764,000 lbs! Unique front and aft ramps facilitate easy drive-on, drive-off loading of military vehicles and equipment Accomplishes tasks that no other military aircraft can Success

  25. So while a very successful operational aircraft, but LP #2. Total Package Procurement Concept (TPPC) was a fixed-price, incentive fee contract strategy for the design, development, and production of 58 aircraft. Invented to control cost growth – underlying cause for overruns LP #3. A Weight Empty Guarantee was included in the specification and in the contract as a cost penalty for each delivered overweight aircraft. Contract Penalty: $10,000 per pound per delivered aircraft Dominated the traditionally balanced requirements resulting in a major shortfalls in wing and pylon fatigue life Negative effects of forcing (out-of-balance) one system parameter Trend in forcing an aircraft from “nominal” weight C-5 Success Synopsis

  26. Expected weight trend Insight into TPM (Weight)

  27. How best to teach (Systems Engineering)? Wrong question How best do students learn? Student centered Discussion based Active Learning Teaching* • *Participant Centered Learning and the Case Method, Harvard Business School Publishing

  28. Participant Centered Learning • Harvard Business School Participant-Centered Learning and the Case Method • Typically a class will cover a 2-3 key points (LPs) • No Lecturing • Students don’t have the LPs… need to discovery as a class • Students must apply course material together with experience • Listen to other students • Professor will elicit student participation • “How do you know that …?” • “What do you think about …?” “Why?” • Professor questions, listens and responds • Organize responses, ask more questions, summarize

  29. Summary • Feedback suggests these can be very effective to support Graduate and Continuous Learning courses • Provide real-world, well-known examples • Target an organization / domain • DoD examples for DoD students • NASA examples for NASA students • Provide for practitioners and resident students • Use a student-led Case Study pedagogical approach

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