Over the past two decades, computer aided engineering (CAE) processes and procedures became an integral part of the product development cycle. Virtual product development (VPD) refers to procedures that integrate the CAE tools in a unified approach that spans all the product development phases. Current industrial trends utilize VPD tools and procedures to reduce the product development time without jeopardizing the product quality. These trends led to an increasing demand for engineers with computer skills, multidisciplinary engineering knowledge, and acquaintance with VPD tools. ABET program outcomes emphasize providing courses with an accumulated background of curricular components to solve realistic open-ended engineering problems. Capstone design project (CDP) course has been regarded as important learning activity that could be designed to provide senior engineering student an opportunity to solve such problems. A major objective of the CDP course is to simulate industrial setting and allow students to experience real-life engineering practice. This paper presents an implementation of the VPD procedures in a mechanical engineering CDP course. This integration simulates the industrial environment through multidisciplinary teams working together in subsystems to produce one product using standard commercial VPD tools. This course implementation is demonstrated using a case study of teams working to design and build a solar car. 1. Introduction Engineering education is a dynamic continuously evolving process that responds to the job market and industrial needs. It adopts new plans, strategies, and technologies to produce a well-integrated engineer with a set of fundamental professional competencies. Professional societies often conduct market surveys to probe the industry needs while, in the meantime, define the futuristic vision of the profession. The professional societies communicate their findings to educational institutions and accreditation agencies. The accreditation agencies compile these requirements into guidelines for the educational institutions where engineering education program developers adapt the program study plans and curricula contents in response to those guidelines. In order to be accredited, the academic program objectives may be aligned with the guidelines of the accreditation agencies, for example, ABET, European Network for Accreditation of Engineering Education (ENAEE), Engineering Accreditation Council (EAC), and so forth. Table 1 shows example of the students outcomes developed by ABET for the engineering programs. ABET
References
[1]
http://www.abet.org/eac-criteria-2014-2015/.
[2]
PTC, “Concept design study uncovers opportunities for improvement, trends in concept design,” PTC Study, July 2011, http://www.ptc.com/solutions/concept-design/trends/thank-you.ht.
[3]
R. H. Todd, S. P. Magleby, C. D. Sorensen, B. R. Swan, and D. K. Anthony, “A survey of capstone engineering courses in North America,” Journal of Engineering Education, vol. 84, no. 2, pp. 165–174, 1995.
[4]
J. H. B?hn, “Integrating rapid prototyping into the engineering curriculum—A Case Study,” Rapid Prototyping Journal, vol. 3, no. 1, pp. 32–37, 1997.
[5]
R. ?avbi and J. Tav?ar, “Preparing undergraduate students for work in virtual product development teams,” Computers and Education, vol. 44, no. 4, pp. 357–376, 2005.
[6]
P. Schmidt, D. Sharer, D. Hoch et al., Implementation of a Capstone Senior Design Program Using Open Source Course Management Software, Conrad, James M.—Department of Electrical and Computer Engineering, University of North Carolina at Charlotte.
[7]
W. Hills and J. W. Bull, “Innovative approach to integrating engineering design. The Newcastle Engineering Design Centre,” Engineering Structures, vol. 23, no. 1, pp. 120–130, 2001.
[8]
M. L. Cummings, “Integrating ethics in design through the value-sensitive design approach,” Science and Engineering Ethics, vol. 12, no. 4, pp. 701–715, 2006.
[9]
M. Wu and H. Yan, “System dynamics modeling and simulation in software engineering education,” in Proceedings of the 9th International Conference for Young Computer Scientists (ICYCS '08), pp. 2407–2411, IEEE Computer Society, November 2008.
[10]
D. Forney, A. Eid, T. Simiao et al., “Development of a device for attaching a wheelchair to a shopping cart or baby stroller,” in Proceedings of the Rehabilitation Engineers Society of North America Conference (RESNA '07), Phoenix, Ariz, USA, June 2007.
[11]
M. Franchetti, M. S. Hefzy, M. Pourazady, and C. Smallman, “Framework for implementing engineering senior design capstone courses and design clinics,” Journal of STEM Education, vol. 13, no. 3, pp. 30–45, 2012.
[12]
M. S. Hefzy, G. Nemunaitis, and M. Hess, “Design and development of a pressure relief seating apparatus for individuals with quadriplegia,” Assistive Technology, vol. 8, no. 1, pp. 14–22, 1996.
[13]
M. S. Hefzy, G. Nemunaitis, T. Jackman, and C. Csulik, “Crutch-like transfer block,” in Proceedings of the Rehabilitation Engineers Society of North America Conference (RESNA '96), pp. 183–185, Salt Lake City, Utah, USA, June 1996.
[14]
M. S. Hefzy, S. Killen, B. Dieddrich, K. Singer, and M. Forewerck, “Lift assist device,” in Proceedings of the Rehabilitation Engineers Society of North America Conference (RESNA '96), pp. 186–188, Salt Lake City, Utah, USA, June 1996.
[15]
M. S. Hefzy, A. Rizkallah, R. Evans, M. Recker, and G. Nemunaitis, “Accelerator control device,” in Proceedings of the ASME International Mechanical Congress and Exposition, pp. 73–74, November 1995.
[16]
M. Hess, M. Klintworth, L. Simerlink et al., “Design and development of a pressure relief seating apparatus for quadriplegics,” in Proceedings of the Bioengineering Conference, pp. 541–542, July 1995.
[17]
B. Sanschagrin, C. Fortin, A. Vadéan, and A. Lakis, “Virtual product development within a fourth year option in the mechanical engineering curriculum,” in Proceedings of the Canadian Design Engineering Network Conference (CDEN '05), Kaninaskis, Canada, July 2005.
[18]
S. Beyerlein, D. Davis, M. Trevisan, P. Thompson, and K. Harrison, Assessment Framework for Capstone Design Courses, American Society for Engineering Education, 2006.
[19]
M. Franchetti, “Evaluation of the effectiveness of the integration of a LITEE Case Study for a freshman level mechanical engineering course at The University of Toledo,” Journal of STEM Education, vol. 12, no. 3, 2011.
[20]
T. A. Warda, “Common elements of capstone projects in the world's top-ranked engineering universities,” European Journal of Engineering Education, vol. 38, no. 2, pp. 211–218, 2013.
[21]
S. Howe, “Where are we now? Statistics on capstone courses nationwide,” Advances in Engineering Education, vol. 2, no. 1, pp. 1–27, 2010.
[22]
L. J. McKenzie, M. S. Trevisan, D. C. Davis, and S. W. Beyerlein, “Capstone design courses and assessment: A National Study,” in Proceedings of the American Society of Engineering Education Annual, Conference & Exposition, pp. 1545–1562, June 2004.
[23]
R. H. Todd and S. P. Maglebya, “Elements of a successful capstone course considering the needs of stakeholders,” European Journal of Engineering Education, vol. 30, no. 2, pp. 203–214, 2005.
[24]
R. H. Todd, C. D. Sorensen, and S. P. Magleby, “Designing a senior capstone course to satisfy industrial customers,” Engineering Education, vol. 82, no. 2, pp. 92–100, 1993.
[25]
A. Kachra and K. Schnietz, “The capstone strategy course: what might real integration look like?” Journal of Management Education, vol. 32, no. 4, pp. 476–508, 2008.
[26]
P. L. Schmidt and J. M. Conrad, “Capstone 101: a framework for implementation of an ABET-compliant capstone sequence,” in Proceedings of the ASEE Annual Conference and Exposition, 2012.
[27]
R. J. Fornaro, M. R. Heil, and A. L. Tharp, “Reflections on 10 years of sponsored senior design projects: students win-clients win!,” Journal of Systems and Software, vol. 80, no. 8, pp. 1209–1216, 2007.
[28]
G. S. Shrivastava, “ASCE Vision 2025 and the Capstone Design Project,” Journal of Professional Issues in Engineering Education and Practice, vol. 139, no. 1, pp. 5–11, 2013.
[29]
M. M. AlMadany, “On engineering education in the new century,” in Proceedings of the 2nd International Conference on Engineering Education & Training, Kuwait City, Kuwait, April 2007.
[30]
R. M. Felder and R. Brent, “Designing and teaching courses to satisfy the ABET engineering criteria,” Journal of Engineering Education, vol. 92, no. 1, pp. 7–25, 2003.
[31]
R. M. Leicht, J. I. Messner, and U. Poerschke, “INVOLVE: developing interactive workspaces that impact communication 25 and task performance when using virtual prototypes”.
[32]
C. W. Swan, K. Paterson, O. Pierrakos, A. R. Bielefeldt, and B. A. Striebig, “ISES—A Longitudinal Study to measure the impacts of service on engineering students,” in Proceedings of the 118th ASEE Annual Conference and Exposition, June 2011.
[33]
A. Sripakagorn and K. Maneeratana, “Design as the priority for engineering education: an implementation in a senior project course,” in Proceedings of the ASEE Annual Conference and Exposition, June 2010.
[34]
O. J. Helweq, “Teaching values in engineering ethics,” in Proceedings of the 4th Christian Engineering Conference, pp. 37–41, The Presbyterian College, June 2002.
[35]
Y. A. Khulief, “Ethics education for engineering students,” in Proceedings of the 2nd Conference on Planning & Development of Education and Scientific Research in the Arab States, February 2008.
[36]
C. B. Fleddermann, Engineering Ethics, Pearson Prentice Hall, 2004.
[37]
B. Karagzo?lu, “Educating the ethical dimension of engineering to a muslim engineer,” Journal of King Saud University—Engineering Sciences, vol. 18, no. 2, pp. 3–16, 2007.
[38]
O. O. Khalifa, M. Hrairi, and A. Albagul, “Ethics in computer and information engineering education: case study,” in Proceedings of the 2nd International Conference on Engineering Education & Training, Kuwait City, Kuwait, April 2007.
[39]
P. M. Griffin, S. O. Griffin, and D. C. Llewellyn, “The impact of group size and project duration on capstone design,” Journal of Engineering Education, vol. 93, no. 3, pp. 185–193, 2004.
[40]
S. C. Handrasekaran, A. M. T. Oo, A. Stojcevski, and G. Littlefair, “Best assessment practices of final year engineering projects in Australia,” in Proceedings of the International Engineering and Technology Education Conference (IETEC'13), Ho Chi Minh City, Vietnam, 2013.
[41]
M. Steiner, J. Kanai, C. Hsu, R. Alben, and L. Gerhardt, “Holistic assessment of student performance in multidisciplinary engineering capstone design projects,” International Journal of Engineering Education, vol. 27, no. 6, pp. 1259–1272, 2011.
[42]
M. Steiner, J. Kanai, R. Alben, L. Gerhardt, and C. Hsu, “A holistic approach for student assessment in project-based multidisciplinary engineering capstone design,” in Proceedings of the ASEE Annual Conference and Exposition, June 2010.
[43]
M. Khandaker, P. Orono, and S. Ekwaro-Osire, “Undergraduate engineering team projects: is there any correlation between presentation and participation?” in Proceedings of the ASEE Annual Conference and Exposition, June 2008.
