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1. Preliminary Results from a Study Investigating the Transition from Capstone Design to Industry

   Howe, Susannah; Rosenbauer, Laura; Ford, Julie Dyke; Alvarez, Nicholas; Paretti, Marie; Gewirtz, Christopher; Kotys-Schwarts, Daria; Knight, Daniel; Hernandez, Cristian (June 2018, 2018 Capstone Design Conference Proceedings)

   This study investigates engineering students’ transitions from academic to professional environments by examining the role capstone design courses play in preparing graduates for the workplace. To better understand how capstone design experiences contribute to graduates’ professional preparation, we are collecting data from participants from four different institutions with project-based capstone courses as they begin post-graduation positions in a variety of engineering workplaces. Through quantitative and qualitative methods, our study is designed to collect insights from participants in their first 12 months on the job. Currently we are collecting and analyzing data from the first of two planned cohorts of participants. Preliminary results for the participants in the first cohort point towards interesting trends regarding participants’ frequency of activities and perception of their preparedness. Professional skills such as team meetings were listed most frequently as activities engaged in by participants, and while there were particular areas such as budgeting where participants felt less prepared, overall their perception of preparedness indicates that capstone design courses and the larger engineering curriculum they are housed within are preparing students for professional careers. 

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2. Building Supports for Diversity through Engineering Teams

   Kirn, A.; Godwin, A.; Pearson, N.; Rodriguez-Simmonds, H.E.; Rohde, J.A.; Verdín, D.; Ross, M.S. (June 2017, ASEE Annual Conference proceedings)

   https://peer.asee.org/27918 Engineering has become a globally focused career with the need to work with people from diverse backgrounds. Researchers seeking to improve students’ teaming skills have found ways to assess team member effectiveness and development of teaming skills. Despite the emphasis on the importance of developing engineering students’ teaming skills, little research has been conducted on how students develop sensitivity for students from different cultures and backgrounds within teams in first-year engineering programs. Here we define diversity sensitivity as students’ multicultural openness and actions taken to incorporate diverse students. To address the lack of literature on diversity and teaming this work examines the following research questions: What changes occur in students’ diversity sensitivity, multicultural effectiveness, and engineering practices as a result of working in diverse teams? How do students’ perceptions of diversity, affect, and engineering practices change as a result of working on diverse teams? The focus of this paper is on the first phase of this three phase project, in which students’ multicultural openness, diversity sensitivity, and teaming effectiveness were measured quantitatively. Additionally, results from qualitative in-depth interviews further develop emerging trends in the quantitative portions of the work. Survey data were collected from participants enrolled in first semester first-year engineering programs at two institutions (n = 1206) as well as data from the Comprehensive Assessment of Team Member Effectiveness (n = 2763 inclusive of survey participants). We used linear modeling, advanced clustering techniques, and pre-post comparisons to understand underlying student attitudes as well as the ways in which students’ attitudes may shift over the course of the semester. Preliminary results indicate that students’ awareness of diversity increased over the semester; however, unwillingness to take action to support diverse groups also increased. We also found that student attitudes towards teaming are ‘sticky’ and difficult to shift over a single-semester experience even when teaming effectiveness and diversity are explicitly taught in the classroom. Additionally, five teams were observed throughout the course of the semester. These observations were conducted to understand how students interact in ways both explicit and implicit. that may or may not improve belongingness in engineering during teaming activities. Students from teams were interviewed individually after completion of their project to understand their perceptions of diversity. Initial trends indicate a valuing of diversity but a lack of adaptation for diverse individuals due to the demands of engineering tasks. Results of this quantitative and qualitative work were used to further refine instruments and data collection protocols for replication in the subsequent phases of the project. 

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3. Studying the Formation of Engineers: A Case Study of a Higher-education Learning Ecology

   Korte, Russell; LeBlanc, Saniya (July 2021, ASEE Annual Conference proceedings)

   null (Ed.)

   The development of professional engineers for the workforce is one of the aims of engineering education, which benefits from the complementary efforts of engineering students, faculty, and employers. Typically, current research on engineering competencies needed for practice in the workplace is focused on the experiences and perspectives of practicing engineers. This study aimed to build on this work by including the perspectives and beliefs of engineering faculty about preparing engineering students, as well as the perspectives and beliefs of engineering students about preparing for the workplace. The overall question of the research was, “What and how do engineering students learn about working in the energy sector?” Additional questions asked practicing engineers, “What is important to learn about your work and how did you learn what was important when you started in this industry? For engineering faculty, we asked, “What is important for students to learn as they prepare for work as professionals in the energy industry?” We anticipated that the findings of triangulating these three samples would help us better understand the nature of the preparation of engineering students for work by exploring the connections and disconnections between engineering education in school and engineering practice in the workplace. The aim was to map out the complex ecosystem of professional learning in the context of engineering education and practice. The core concept framing this study is the development of competence for engineering practice—including the education of students in the context of higher education and the practical learning of newly hired engineers on the job. Initial findings of the work-in-progress describe the nature of instruction and learning in higher education, learning in the workplace, along with comparisons and contrasts between the two. As of this point, we have initially mapped the learning ecosystem in the workplace based on in-depth, qualitative interviews with 12 newly hired engineers in the target energy company. In addition, we are analyzing interviews with two managers in the company and three other experienced leaders in the energy industry (this sample is currently in process and will include interviews with more participants). Currently, we are analyzing and mapping the learning and experiences of students in their studies of energy engineering and the instructional goals of engineering faculty teaching and mentoring these students. The map of the higher education ecosystem will connect with the workplace ecosystem to portray a more longitudinal map of the learning and development of professional competence of engineering students preparing for their career in the energy sector. The findings of the analysis of the workplace emphasized the importance of the social and relational systems in the workplace, while very preliminary indications from the educational context (students and faculty) indicate initial awareness of the social context of energy practice and policy. There are also indications of the nature of important cultural differences between higher education and industry. We continue to collect data and work on the analysis of data with the aim of mapping out the larger learning and experience ecosystem that leading to professional competence. 

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4. Solarize Your School: A Solar Energy System Design Challenge

   Chao, J; Xie, C; Massicotte, J; Schimpf, C; Lockwood, J; Huang, X; & Beaulieu, C (January 2018, The Science teacher)

   As solar energy becomes increasingly affordable, many schools are considering installing new solar power systems. Can students contribute to the design, evaluation, and decision-making process in any way? Many students are familiar with solar power and energy, having researched solar energy on the internet, built solar cookers, inspected mini solar cells, gone on field trips to local solar farms, and so on. Well-informed and motivated, they are just one step away from taking responsibility for their own schools. In this article, we present Solarize Your School, an engineering project that gives students the opportunity to design and evaluate solar power solutions for their own schools. This STEM project requires students to learn and apply skills and practices related to solar energy and photovoltaic technology concepts, such as architectural measurement and modeling techniques, graphical interpretation and data analysis, budgeting and investing, scientific inquiry and engineering design, and collaboration and communication (see Next Generation Science Standards table, p. 47). Solarize Your School can be incorporated into environmental science, physical science, and engineering courses, and can be adapted to fit any curriculum scope and time frame. We suggest a 10-day sequence of learning activities. All the technologies and materials mentioned are freely available (see “On the web”). 

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5. Relationship Between Team-Building Activities and Capstone Team Performance and Student Experience

   https://doi.org/10.18260/1-2--46949  

   Godbole, Hrushikesh; DeBartolo, Elizabeth; Takai, Shun (June 2024, ASEE Conferences)

   Team building activities are popular interventions during early stages of team development. At RIT, in the multidisciplinary capstone course with an average cohort size of around 350, the students on a particular capstone project team may not be mutually acquainted and thus may benefit from such team building activities. Prior literature has studied the effectiveness of various instructor-directed team building activities on student teams. However, our students are generally eager to spend class time working on their projects and often see in-class activities as a distraction rather than an important part of their growth. Instead, the student teams are now allowed to choose an intervention based on team consensus. In this paper, the relationship between attributes of the chosen intervention and student performance, as measured using a series of AACU VALUE rubrics, was studied using statistical measures. The analysis revealed a statistically significant effect of type of team building activity on teamwork, oral communication, and design & problem solving scores of individual students on the team. Also, a statistically significant effect of location of team building activity (on or off campus) on design & problem solving score was observed. 

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