Active/Collaborative Learning Student Teams Integrating Technology Effectively Women and Minorities Assessment and Evaluation EC2000 Emerging Technology Foundation Coalition Curricula Concept Inventories
 
 
 
 
 
A Unified Framework for Engineering Science: Principles and Sample Curricula
 

Sophomore Engineering Curricula
Introduction  Conservation and Accounting Framework Curriculum Structure: Texas A&M four-course structure Curriculum Structure: Texas A&M Five-Course Structure
Curriculum Structure: Rose-Hulman Institute of Technology Sophomore Engineering Curriculum Example Problems

Student Performance/Faculty Reactions

Conclusions

I. Introduction

When students complete their required physics, chemistry, and mathematics, they bring a large quantity of fragmented information and skills into their engineering courses. Unfortunately, their abilities to integrate various concepts, to use these concepts to analyze novel physical situations, or to justify the applicability of the solutions they “know” are less developed than desired for engineering design and analysis. The following examples are intended to illustrate the information that students bring and some of the challenges that they face in integrating their knowledge.

Example: Person Supporting a Barbell

Example: Ice Skater

Example: Swimming Pool

Overview of the Paper

References

  1. Grinter, L.E. (Chair), Report on Evaluation of Engineering Education, American Society for Engineering Education, Washington, DC, 1955.
  2.   Harris, Eugene M. DeLoatch, William R. Grogan, Irene C. Peden, and John R. Whinnery, "Journal of Engineering Education Round Table: Reflections on the Grinter Report," Journal of Engineering Education, Vol. 83, No. 1, pp. 69-94 (1994) (includes as an Appendix the Grinter Report, issued in September, 1955).
  3. Glover, Charles, J., and Carl A. Erdman, "Overview of the Texas A&M/NSF Engineering Core Curriculum Development," Proceedings, 1992 Frontiers in Education Conference, Nashville, Tennessee, 11-14 November 1992, pp. 363-367
  4. Glover, Charles J., K. M. Lunsford, and John A. Fleming, “TAMU/NSF Engineering Core Curriculum Course 1: Conservation Principles in Engineering,” Proceedings, 1992 Frontiers in Education Conference, Nashville, Tennessee, 11-14 November 1992, pp. 603-608
  5. Glover, Charles J., K. M. Lunsford, and John A. Fleming, Conservation Principles and the Structure of Engineering, 3rd edition, New York: McGraw-Hill College Custom Series, 1992
  6. Pollock, Thomas C., “TAMU/NSF Engineering Core Curriculum Course 2: Properties of Matter,” Proceedings, 1992 Frontiers in Education Conference, Nashville, Tennessee, 11-14 November 1992, pp. 609-613
  7. Pollock, Thomas C., Properties of Matter, 3rd edition, New York: McGraw-Hill College Custom Series, 1992
  8. Everett, Louis J., “TAMU/NSF Engineering Core Curriculum Course 3: Understanding Engineering via Conservation,” Proceedings, 1992 Frontiers in Education Conference, Nashville, Tennessee, 11-14 November 1992, pp. 614-619
  9. Everett, Louis J., Understanding Engineering Systems via Conservation, 2nd edition, New York: McGraw-Hill College Custom Series, 1992
  10. Glover, Charles J. and H. L. Jones, “TAMU/NSF Engineering Core Curriculum Course 4: Conservation Principles for Continuous Media,” Proceedings, 1992 Frontiers in Education Conference, Nashville, Tennessee, 11-14 November 1992 Conference, pp. 620-624
  11. Glover, C. J. and H. L. Jones, Conservation Principles for Continuous Media, 2nd edition, New York: McGraw-Hill College Custom Series, 1992
  12. Erdman, Carl A., Charles J. Glover, and V. L. Willson, “Curriculum Change: Acceptance and Dissemination,” Proceedings, 1992 Frontiers in Education Conference, Nashville, Tennessee, 11-14 November 1992, pp. 368-372
  13. B. A. Black, “From Conservation to Kirchoff: Getting Started in Circuits with Conservation and Accounting,” Proceedings of the 1996 Frontiers in Education Conference, Salt Lake City, Utah, 6-9 November 1996
  14. Griffin, Richard B., Louis J. Everett, P. Keating, Dimitris C. Lagoudas, E. Tebeaux, D. Parker, William Bassichis, and David Barrow, "Planning the Texas A&M University College of Engineering Sophomore Year Integrated Curriculum," Fourth World Conference on Engineering Education, St. Paul, Minnesota, October 1995, vol. 1, pp. 228-232.
  15. Everett, Louis J., "Experiences in the Integrated Sophomore Year of the Foundation Coalition at Texas A&M," Proceedings, 1996 ASEE National Conference, Washington, DC, June 1996
  16. Richards, Donald E., Gloria J. Rogers, "A New Sophomore Engineering Curriculum -- The First Year Experience," Proceedings, 1996 Frontiers in Education Conference, Salt Lake City, Utah, 6-9 November 1996
  17. Heenan, William and Robert McLaughlan, "Development of an Integrated Sophomore Year Curriculum,” Proceedings of the 1996 Frontiers in Education Conference, Salt Lake City, Utah, 6-9 November 1996
  18. Mashburn, Brent, Barry Monk, Robert Smith, Tan-Yu Lee, and Jon Bredeson, "Experiences with a New Engineering Sophomore Year,” Proceedings of the 1996 Frontiers in Education Conference, Salt Lake City, Utah, 6-9 November 1996
  19. Everett, Louis J., "Dynamics as a Process, Helping Undergraduates Understand Design and Analysis of Dynamics Systems," Proceedings, 1997 ASEE National Conference,
  20. Doering, E., “Electronics Lab Bench in a Laptop: Using Electronics Workbench to Enhance Learning in an Introductory Circuits Course,” Proceedings of the 1997 Frontiers in Education Conference, November 1997
  21. Cornwell, P., and J. Fine, “Mechanics in the Rose-Hulman Foundation Coalition Sophomore Curriculum,” Proceedings of the Workshop on Reform of Undergraduate Mechanics Education, Penn State, 16-18 August 1998
  22. Cornwell, P., and J. Fine, “Mechanics in the Rose-Hulman Foundation Coalition Sophomore Curriculum,” to appear in the International Journal of Engineering Education
  23. Cornwell, P. and J. Fine, “Integrating Dynamics throughout the Sophomore Year,” Proceeedings, 1999 ASEE Annual Conference, Charlotte, North Carolina, 20-23 June 1999
  24. Burkhardt, H. "System physics: A uniform approach to the branches of classical physics." Am. J. Phys. 55 (4), April 1987, pp. 344–350.
  25. Fuchs, Hans U. Dynamics of Heat. Springer-Verlag, New York, 1996.

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