Background: Research has shown that active learning promotes student learning and increases retention rates of STEM undergraduates. Yet, instructors are reluctant to change their teaching approaches for several reasons, including a fear of student resistance to active learning. This paper addresses this issue by building on our prior work which demonstrates that certain instructor strategies can positively influence student responses to active learning. We present an analysis of interview data from 17 engineering professors across the USA about the ways they use strategies to reduce student resistance to active learning in their undergraduate engineering courses. Results: Our data reveal that instructor strategies for reducing student resistance generally fall within two broad types: explanation and facilitation strategies. Explanation strategies consist of the following: (a) explain the purpose, (b) explain course expectations, and (c) explain activity expectations. Facilitation strategies include the following: (a) approach non-participants, (b) assume an encouraging demeanor, (c) grade on participation, (d) walk around the room, (e) invite questions, (f) develop a routine, (g) design activities for participation, and (h) use incremental steps. Four of the strategies emerged from our analysis and were previously unstudied in the context of student resistance. Conclusions: The findings of this study have practical implications for instructors wishing to implement active learning. There is a variety of strategies to reduce student resistance to active learning, and there are multiple successful ways to implement the strategies. Importantly, effective use of strategies requires some degree of intentional course planning. These strategies should be considered as a starting point for instructors seeking to better incorporate the use of active learning strategies into their undergraduate engineering classrooms.
Background Calls for the reform of education in science, technology, engineering, and mathematics (STEM) have inspired many instructional innovations, some research based. Yet adoption of such instruction has been slow. Research has suggested that students' response may significantly affect an instructor's willingness to adopt different types of instruction.Purpose We created the Student Response to Instructional Practices (StRIP) instrument to measure the effects of several variables on student response to instructional practices. We discuss the step-by-step process for creating this instrument.Design/Method The development process had six steps: item generation and construct development, validity testing, implementation, exploratory factor analysis, confirmatory factor analysis, and instrument modification and replication. We discuss pilot testing of the initial instrument, construct development, and validation using exploratory and confirmatory factor analyses.Results This process produced 47 items measuring three parts of our framework. Types of instruction separated into four factors (interactive, constructive, active, and passive); strategies for using in-class activities into two factors (explanation and facilitation); and student responses to instruction into five factors (value, positivity, participation, distraction, and evaluation). ConclusionsWe describe the design process and final results for our instrument, a useful tool for understanding the relationship between type of instruction and students' response.
Background Despite the evidence supporting the effectiveness of active learning in undergraduate STEM courses, the adoption of active learning has been slow. One barrier to adoption is instructors’ concerns about students’ affective and behavioral responses to active learning, especially student resistance. Numerous education researchers have documented their use of active learning in STEM classrooms. However, there is no research yet that systematically analyzes these studies for strategies to aid implementation of active learning and address students’ affective and behavioral responses. In this paper, we conduct a systematic literature review and identify 29 journal articles and conference papers that researched active learning, affective and behavioral student responses, and recommended at least one strategy for implementing active learning. In this paper, we ask: (1) What are the characteristics of studies that examine affective and behavioral outcomes of active learning and provide instructor strategies? (2) What instructor strategies to aid implementation of active learning do the authors of these studies provide? Results In our review, we noted that most active learning activities involved in-class problem solving within a traditional lecture-based course (N = 21). We found mostly positive affective and behavioral outcomes for students’ self-reports of learning, participation in the activities, and course satisfaction (N = 23). From our analysis of the 29 studies, we identified eight strategies to aid implementation of active learning based on three categories. Explanation strategies included providing students with clarifications and reasons for using active learning. Facilitation strategies entailed working with students and ensuring that the activity functions as intended. Planning strategies involved working outside of the class to improve the active learning experience. Conclusion To increase the adoption of active learning and address students’ responses to active learning, this study provides strategies to support instructors. The eight strategies are listed with evidence from numerous studies within our review on affective and behavioral responses to active learning. Future work should examine instructor strategies and their connection with other affective outcomes, such as identity, interests, and emotions.
is an Associate Professor of Engineering Education at Virginia Tech, where she also serves as co-Director of the VT Engineering Communication Center (VTECC). Her research interests include interdisciplinary collaboration, design education, communication studies, identity theory and reflective practice. Projects supported by the National Science Foundation include exploring disciplines as cultures, interdisciplinary pedagogy for pervasive computing design; writing across the curriculum in Statics courses; as well as a CAREER award to explore the use of e-portfolios to promote professional identity and reflective practice.
Background Recent research has demonstrated the importance of entrepreneurship education programs (EEPs) in the professional development of engineering students. Numerous universities have adopted various forms of EEPs which are typically offered as elective programs. To create suitable programs that will encourage students to seek out EEPs, it is critical to understand the factors that influence student participation in EEPs. Using qualitative research methods, we examined the question “What influences engineering students’ participation in entrepreneurship education programs?” The purpose of our work is to identify and understand the factors impacting engineering student participation in EEPs. Results Analysis of 20 semi-structured interviews of undergraduate engineering students was conducted using the first and second cycle coding methods to determine key factors that inform students’ participation in EEPs. We found that student decisions to participate in EEPs are influenced by several factors: entrepreneurial self-efficacy, entrepreneurial intent, attitude, subjective norm, goals, academic transitions, information and resources, social capital, opportunities and challenges, and past participation in EEPs. Conclusions Findings demonstrate that students’ non-compulsory participation is not a result of a single act, but is regulated by multiple factors. Explication of these factors using our qualitative results provides actionable guidance for EEPs to encourage engineering students’ participation and offers directions for future research.
Engineering education research has empirically validated the effectiveness of active learning over traditional instructional methods. However, the dissemination of education research into instructional practice has been slow. Faculty workshops for current and future instructors offer a solution to promote the widespread adoption of active learning in engineering classrooms. However, most of the existing research has relied on faculty selfreporting to evaluate the success of engineering faculty workshops. Researchers have noted variations in self-reporting and the actual classroom implementation. In this paper, using classroom observations, faculty interviews, student surveys, and focus groups, the authors examine an engineering instructor's postworkshop implementation of active learning in an electrical engineering course. The findings demonstrate the influence of faculty conceptions of teaching in the selection and design of activities and the subsequent impact of these design choices on student engagement. The authors report the instructor's and students' responses to the active learning exercises and present recommendations for engineering faculty development.Index Terms-Active learning, engineering education, faculty development, student engagement. 0018-9359
Aileen is faculty in Engineering Education and Biomedical Engineering. Previously, Aileen was the Associate Director for Academics in the Center for Entrepreneurship and was responsible for building the Program in Entrepreneurship for UM undergraduates, co-developing the masters level entrepreneurship program, and launching the biomedical engineering graduate design program. Aileen has received a number of awards for her teaching, including the Thomas M. Sawyer, Jr. Teaching Award, the UM ASEE Outstanding Professor Award and the Teaching with Sakai Innovation Award. Prior to joining the University of Michigan faculty, she worked in the private sector gaining experience in biotech, defense, and medical device testing at large companies and start-ups. Aileen's current research areas include entrepreneurship engineering education, impact and engaged learning. Aileen has a Bachelor's of Science in Engineering from the University of Pennsylvania, a Doctorate of Philosophy from The Johns Hopkins University School of Medicine, and a Masters of Business Administration from the University of Michigan Ross School of Business. Aileen is also a member of Phi Kappa Phi and Beta Sigma Gamma.
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