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PROACTIVE TEACHING AND LEARNING IN THE AEROSPACE ENGINEERING CURRICULUM 2000

PROACTIVE TEACHING AND LEARNING IN THE AEROSPACE ENGINEERING CURRICULUM 2000. Brian M. Argrow Department of Aerospace Engineering Sciences University of Colorado, Boulder. ASEE Annual Conference Montreal, Canada 23 May 2002. KNOWLEDGE & CURRICULUM. Knowledge & Curriculum.

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PROACTIVE TEACHING AND LEARNING IN THE AEROSPACE ENGINEERING CURRICULUM 2000

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  1. PROACTIVE TEACHING AND LEARNING IN THE AEROSPACE ENGINEERING CURRICULUM 2000 Brian M. Argrow Department of Aerospace Engineering Sciences University of Colorado, Boulder ASEE Annual Conference Montreal, Canada 23 May 2002

  2. KNOWLEDGE & CURRICULUM

  3. Knowledge & Curriculum • A technical curriculum must address each component of knowledge: • Conceptual • Operational • Integral BMA

  4. Basic facts and observations “Heavy” objects fall faster than “light” objects Physical laws and principles Force  Acceleration Diagrams and schematics Mathematical representation Conceptual Knowledge x2 T x1 W BMA

  5. Operational Knowledge • Formulation and Analysis  Conceptual • Requirements? Constraints? Initial conditions? Symmetries? • Methods and Strategies • Analytical (closed-form or approximate?) • Computational • Skills and Resources • Computing  Group dynamics • Library  Internet BMA

  6. Integral Knowledge • Conceptual + Operational = Integral • Synthesis enables design • Practicum provides opportunity to build and test • Integral knowledge is essential for design • The foundation of new technology • Unique to the engineering profession • Given the why and how—what? BMA

  7. D W Knowledge & Technology Conceptual Knowledge Objects fall to earth The rate of change in the falling speed is independent of the object weight : Operational Knowledge + Technology Integral Knowledge BMA

  8. A Proactive Philosophy Instruction and learning begin with teacher and student preparation. The classroom is not the place for teachers to display how much they knowit is the place to learn what students do not know so those things become known. BMA

  9. Teacher Motivation • Faculty are motivated… …to minimize load, maximize quality …by a tangible reward structure …by professional respect …by student respect …by self respect BMA

  10. Student Motivation • Many students... …are not motivated to do what is good for them • reading in preparation for lectures • homework • early exam preparation …are motivated to avoid negative consequences, particularly if the consequences are immediate • low grades • negative peer pressure BMA

  11. Teacher Preparation • Pick the appropriate text • Criticizing the text is a waste of time • Know the text and know your stuff • Prepare to ad-lib (oxymoron?) • Definite, but flexible, plan • Syllabus contract • Learning goals instead of material coverage BMA

  12. Student Preparation • You are responsible for your learning • Being Smart is not Enough* • Reading is fundamental—not intended for homework excerpts • Work outside the proverbial box • Don’t be constrained by “coverage” • Why are there references at the end of the chapter? *D. Dilaura BMA

  13. Teachers in the Classroom • Learn last names • Ms. & Mr. for “friendly” formality • Emphasize good character, integrity, and ethical behavior • Discuss engineers’ social responsibilities • Require attendance • Respect students (those that deserve it) BMA

  14. Students in the Classroom • Respect your teacher (we deserve it) • Bring necessities, e.g., book, calculator, pencil, good attitude... • Respect your classmates • Respect property BMA

  15. Sensors & Tools • Unit Quiz • Preparation is serious because it counts • Gives immediate feedback (get ‘em while they’re hot) • Outlines the “lecture” by promoting discussion • Helps teacher prepare to ad-lib • Keep it simple, but fundamental • Conventional lecture still appropriate BMA

  16. Sensors & Tools • Group exercises • Integral knowledge through synthesis • Group dynamics • Exciting and contemporaneous • Professional identity • Reduces grading • Biweekly Exams • Test individual mastery • Discourage “cramming” BMA

  17. Sensors & Tools • Homework • Minor portion of course grade • Question of the day • Reconnects the math-science-engineering disconnect • Class log and e-mail updates • Summary of the day’s activities • Reflection and hindsight • Complete account of course activities • Complements class website BMA

  18. A Proactive Classroom • Preparation reduced, satisfaction increased • Classroom is energized • Students appreciate your effort and, more importantly, their effort • Students more responsible and responsive • Students display greater depth of knowledge BMA

  19. THE AES CURRICULUM 2000

  20. Need for Reform • Emphasis on basic science, mathematics, and engineering science in the early cold-war years 1945-65 • Renewed hands-on, product design focus • A good engineer… must strike a balance between knowing and doing* *Seely, B. E., “The Other Re-engineering of Engineering Education, 1900-1965,” Journal of Engineering Education, 88 (3), Jul. 1999, pp. 285-294. BMA

  21. Traditional EngineeringEducation Model* • Students enter discipline tracks and proceed through distincts steps to graduation • Little interaction with other disciplines • Little interaction between graduate and undergraduate programs • Little interaction with industry or K-12 BMA

  22. Integrated Teaching and LearningLaboratory Model • Create interdisciplinary learning through team projects • Building as a laboratory • Learning by exploring HORIZONTAL INTEGRATION BMA

  23. Discovery LearningCenter Model • Create industry partnerships • Do first-class research • Expose all students to research • Promote inreach and outreach opportunities • Create knew knowledge VERTICAL INTEGRATION BMA

  24. AES Curriculum 2000 Objectives • Establish a core curriculum • Integrate topics in this core • Make the curriculum relevant to applications • Make the curriculum experiential  hands-on • Integrate communications and teamwork skills • Provide more curricular choice in upper division • Implement continuous improvement procedures BMA

  25. Curriculum 2000 Lower Division BMA

  26. Curriculum 2000 Upper Division BMA

  27. Sophomore Year: 2000-Series (Fall) • ASEN 2001 Intro to Statics Structures and Materials • Analytical tools for statics and structural analysis in context of the physics of aerospace materials • Force/moment equilibrium, truss analysis, beam theory, stress and strain, material structure, alloy phase diagrams, polymers, ceramics, composites, and aerospace structural design • ASEN 2002 Intro to Thermodynamics and Aerodynamics • Fundamental concepts and principles of thermodynamic and fluid systems • Properties of a pure substance, conservation of energy: 1st law for closed systems and flow systems, aerodynamic forces and dimensional analysis, 1-D incompressible and compressible flow, two-dimensional flow: lift and drag, viscous flow BMA

  28. Sophomore Year: 2000-Series (Spring) • ASEN 2003 Intro to Dynamics and Systems • Introduces the principles of particle and 2-D rigid-body dynamics, vibrations, systems, and controls • Kinematics, kinetics, energy methods, systems modeling, and simple feedback control • ASEN 2004 Aerospace Vehicle Design and Performance • Introduces design and performance analyses of aircraft and spacecraft • Aircraft: wings, propulsion, cruise performance, stability and control, structures, and preliminary design • Spacecraft: orbital mechanics, orbit and constellation design, rocket equation and staging, launch systems, and spacecraft subsystems BMA

  29. 2000-Series TypicalBi-weekly Curriculum Block • Unit quiz basis for preparation and classroom activities • Group exercises synthesise concepts and methods in a relevant applications • Conventional homework • Individual exam • Concurrent experimental and design laboratories BMA

  30. Upper Division Courses • To maximize multidisciplinary opportunities, no professional electives required to be AES courses • All junior AES courses include a laboratory component • Capstone Senior Projects is a year-long synthesis and practicum course with design, build, and test requirement • Senior Projects sequence is focus of proposed vertical curriculum integration BMA

  31. Challenges and Compromises • Team teaching • A rewarding new paradigm for AES • Assessment • Graduate surveys, student review team • Spreadsheet tool for mapping assignments according to desired outcomes and learning goals, and conventional grade assignment • Diligence • Resources and Facilities • Unilateral reform at a state university • ITLL space limitations and laboratory expendibles • Increased TA need—quantity and quality • External funding BMA

  32. Conclusions and Future Initiatives • Opportunity to employ a proactive teaching and learning philosophy • Increased student-faculty contact hours • Curriculum lauded by academic peers, industry, advisory boards, and students • Improved national ranking • Vertical integration based on the Senior Projects courses • Discovery Learning Initiative BMA

  33. Acknowledgements • AES Colleagues Penina Axelrad, Robert Culp, David Kalahar, Dale Lawrence, Lee Peterson • David Dilaura, John Dow, Michael Lightner (Univ. Colorado) • Ronald Blackwelder (Univ. Southern California), Adele Howe (Colorado State Univ.) • Dedicated to the memory of Professor A. Richard Seebass BMA

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