Penn State University , Pennsylvania
July 28, 2019
July 28, 2019
July 30, 2019
FYEE Conference - Paper Submission
7
10.18260/1-2--33712
https://peer.asee.org/33712
381
Darlene Spracklin-Reid is a lecturer in the Faculty of Engineering and Applied Science at Memorial University. She received her B.Eng (Civil) from Memorial University of Newfoundland in 1995. After working as a geotechnical designer and a project manager in the construction industry, she earned a B.Ed (2004) and began a career in post-secondary education. She is currently the chair of Professional Engineers and Geoscientists of Newfoundland and Labrador, and has served on the board of the Canadian Engineering Education Association. She teaches courses that focus on professional skills, engineering practice and project management.
Geoff Rideout received his B.Eng. (Mechanical) from Memorial University of Newfoundland in 1993. After working in the manufacturing and building systems consulting industries, he earned his M.A.Sc. in Mechanical Engineering from Queen's University in Kingston, Ontario and his Ph.D. in Mechanical Engineering from the University of Michigan. He has lectured at the University of Michigan and at the Humber Institute for Advanced Technology and Applied Learning in Toronto. He is currently an Associate Professor at Memorial University, teaching mechanics and design. His research areas are automated modeling, vehicle dynamics and control, vibration-assisted drilling, and nondestructive testing of power transmission line poles.
In engineering programs with a common first year, students may feel like they are in Grade 13, rather than members of a fledgling community working towards entry into an exciting and impactful profession. Memorial University’s Engineering One first year has three goals: 1. Educate students about what engineering is, in contrast to pure math or science. Students with good judgement, communication skills, and emotional intelligence; but lower math/physics self-efficacy, should become reassured that they can thrive. High-performing math/science students should become informed of other skills they may need to develop. 2. Inform students about the various disciplines, one of which they must select and enter in second year. 3. Prepare students for departmental specialization, with readiness in areas such as numerical literacy, ability to use spreadsheets, presentation and interpretation of data in graphical form, and ability to critically reflect on results.
A course called “Thinking Like an Engineer” (TLE) has been designed, driven by a collection of case studies from different departments. We present big-picture engineering problems to students in an analytically tractable form. The case studies i) show how real-world needs are turned into quantitative engineering problems with constraints, ii) give global learners a sense of the problems they will be able to tackle with more depth as they move through the program and beyond, iii) provide a context in which to learn computer tools, especially Microsoft Excel, iv) provide opportunities to give formative feedback on graphical communication and data analysis, significant figures, estimation, basic statistical analysis, and so on. In contrast to “typical” first-year engineering courses, TLE is intended to connect course work to career goals for global learners and social conscience-driven students.
The following methodology is proposed for case study development: 1. Set top-level goals for case studies at the Core (or equivalent) department level. 2. Engage junior co-op student “engagement partners” in the search for topics and relevant literature. Such students have proximity to the target audience in terms of maturity and technical ability. 3. Canvass faculty members for department-specific topics, while seeking interdisciplinary connections. 4. Connect engagement partners with faculty experts for first-draft technical vetting. 5. Focus group the first official draft by having • Core faculty work through it, ensuring connection with desired course outcomes. • Engagement partners’ peers completing it, assessing time requirement and difficulty 6. Deliver within course, with reflection and continuous improvement enabled by student feedback.
Case studies are conducted in a small group setting, supported by online resources. The current complement of case studies include an analysis of engine shaking forces, electrical utility load leveling with renewable energy, optimization of solar panels for hot water heating, route selection for a proposed highway using mass diagrams, and a coffee manufacturing study with a hands-on component. Surveys are being conducted to assess students’ confidence in their understanding of the engineering approach to real-world problem solving, the technical areas related to the case studies, and their confidence and desire to persist in engineering.
Spracklin-Reid, D., & Rideout, G. (2019, July), Increasing first-year student motivation and core technical knowledge through case studies Paper presented at 2019 FYEE Conference , Penn State University , Pennsylvania. 10.18260/1-2--33712
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