More Like this

1. A Gamified Pedagogical Method for Teaching Construction Scheduling through Active Exploration

   Ilbeigi, Mohammad; Ehsani, Romina; Bairaktarova, Diana (January 2023, 59th Annual Associated Schools of Construction International Conference)

   Previous studies have convincingly shown that active and collaborative instructions, coupled with effective means to encourage student engagement, invariably lead to better learning outcomes. However, despite significant potentials for experiential learning, standard educational programs in construction engineering and management are rigid systems that offer little opportunity for students to engage in active learning that can help them gain first-hand experience and guide them toward discovering solutions. This study aims to address this need by designing and empirically assessing the performance of a novel gamified pedagogical method that teaches construction scheduling through guided active exploration in a digital game environment. The proposed pedagogical approach and its game are designed based on the constructivism learning theory. A scenario-based interactive game, called Zebel, was developed using the Unity game engine. Using a series of pre- and post-assessment instruments, the proposed method was implemented and evaluated in a graduate-level course for construction planning and scheduling to collect empirical data. The outcomes indicated that the proposed pedagogy was able to successfully guide students with no background and prior knowledge in construction scheduling to discover the fundamental concepts and systematic solutions for the problems. 

   more » « less
2. Usable STEM: Student Outcomes in Science and Engineering Associated with the Iterative Science and Engineering Instructional Model

   https://doi.org/10.3390/educsci14111255  

   Songer, Nancy B; Calabrese, Julia E; Cordner, Holly; Aina, Daniel (November 2024, Education Sciences)

   While our world consistently presents complicated, interdisciplinary problems with STEM foundations, most pre-university curricula do not encourage drawing on multidisciplinary knowledge in the sciences and engineering to create solutions. We developed an instructional approach, Iterative Science and Engineering (ISE), that cycles through scientific investigation and engineering design and culminates in constructing a solution to a local environmental challenge. Next, we created, revised, and evaluated a six-week ISE curricular program, Invasive Insects, culminating in 6th–9th-grade students building traps to mitigate local invasive insect populations. Over three Design-Based Research (DBR) cycles, we gathered and analyzed identical pre and post-test data from 554 adolescents to address the research question: what three-dimensional (3D) science and engineering knowledge do adolescents demonstrate over three DBR cycles associated with a curricular program following the Iterative Science and Engineering instructional approach? Results document students’ significant statistical improvements, with differential outcomes in different cycles. For example, most students demonstrated significant learning of 3D science and engineering argument construction in all cycles—still, students only significantly improved engineering design when they performed guided reflection on their designs and physically built a second trap. Our results suggest that the development, refinement, and empirical evaluation of an ISE curricular program led to students’ design, building, evaluation, and sharing of their learning of mitigating local invasive insect populations. To address complex, interdisciplinary challenges, we must provide opportunities for fluid and iterative STEM learning through scientific investigation and engineering design cycles. 

   more » « less
3. Developing Engineering for Social Impact Beliefs among Migratory High School Students Through a Culturally Responsive Engineering Design Activity

   Wells, Timothy; Verdín, Dina (June 2025, American Society for Engineering Education)

   Broadening participation in engineering needs to be different from filling the pipeline or national competitiveness. We should seek to empower students to use engineering knowledge and skills to create social change, address injustices, or develop problem-solving skills that can help transform lives. This study examined how migratory high school students developed beliefs about engineering’s capacity for social impact through participation in an activity where they learned how the engineering design process could be used to solve a need impacting agricultural workers. Specifically, we investigated how students' interest in engineering, their self-efficacy in applying engineering concepts, and the development of an identity as a future engineer influence the formation of their beliefs about their capacity to act purposefully and effectively using engineering practices. Migratory high school students represent an overlooked and underserved segment of students in U.S. schools. These students, often from Latinx backgrounds, remain underrepresented in engineering fields. To investigate the development of “engineering for social impact” among migratory high school students, we designed and implemented a culturally responsive and gamified engineering design activity. The activity aimed to connect engineering concepts to students’ cultural backgrounds and experiences while leveraging game-based learning elements to increase engagement. We administered pre- and post-surveys to measure changes in students’ engineering impact, interest, self-efficacy, and identity (n = 235). We used a multiple linear regression model to examine the relationships. Our results show that migratory students’ engineering interest and self-efficacy significantly supported the development of their belief that engineering could be a tool for social impact. Specifically, as students’ engineering interest increased, their perception that engineering could be used as a practice to address injustices significantly increased by 0.335 points. Similarly, as students’ engineering self-efficacy beliefs increased, that led to a significant increase of 0.346 points in their social impact beliefs. However, being recognized as someone who can do engineering (i.e., recognition beliefs) did not have a significant effect. The model explains approximately 46.7% of the variance in students’ beliefs about engineering as a tool for social impact. Our findings suggest that students’ engineering for social impact beliefs develop through experiences that enable them to see themselves as engineers and use engineering knowledge in meaningful ways. Our culturally responsive and gamified approach positively influenced students’ beliefs by fostering both interest and self-efficacy in engineering contexts. The results underscore the importance of creating learning environments and activities that not only spark interest in engineering but also build students’ confidence in their abilities to engage in engineering practices. For migratory Latinx high school students who face unique challenges in their educational journeys, cultivating engineering for social impact may be particularly crucial in garnering interest in the field. This study contributes to the growing body of research on the importance of connecting engineering to social and cultural context and provides insights into effective strategies for supporting underrepresented students in engineering. Future work should explore the longitudinal effects of such interventions and investigate additional factors that may influence the development of students’ social impact beliefs among migratory students. 

   more » « less
4. NSF RED: Supporting Convergence Development through Structural Changes to an ECE Program

   Cheville, R. A.; Appelhans, S. E.; Thomas. R.; Thomas, S.; Nickel, R. M.; Thompson, M. S. (January 2022, American Society for Engineering Education Annual Conference and Exhibition)

   This NSF Grantees poster discusses an early phase Revolutionizing Engineering Departments (RED) project which is designed to address preparing engineering students to address large scale societal problems, the solutions of which integrate multiple disciplinary perspectives. These types of problems are often termed “convergent problems”. The idea of convergence captures how different domains of expertise contribute to solving a problem, but also the value of the network of connections between areas of knowledge that is built in undertaking such activities. While most existing efforts at convergence focus at the graduate and post-graduate levels, this project supports student development of capabilities to address convergent problems in an undergraduate disciplinary-based degree program in electrical and computer engineering. This poster discusses some of the challenges faced in implementing such learning including how to decouple engineering topics from societal concerns in ways that are relevant to undergraduate students yet retain aspects of convergence, negotiations between faculty on ways to balance discipline-specific skills with the breadth required for systemic understanding, and challenges in integrating relevant projects into courses with different faculty and instructional learning goals. One of the features of the project is that it builds on ideas from Communities of Transformation by basing activities on a coherent philosophical model that guides theories of change. The project has adopted Amartya Sen’s Development as Freedom or capabilities framework as the organizing philosophy. In this model the freedom for individuals to develop capabilities they value is viewed as both the means and end of development. The overarching goal of the project is then for students to build personalized frameworks based on their value systems which allow them to later address complex, convergent problems. Framework development by individual students is supported in the project through several activities: modifying grading practices to provide detailed feedback on skills that support convergence, eliciting self-narratives from students about their pathways through courses and projects with the goal of developing reflection, and carefully integrating educational software solutions that can reduce some aspects of faculty workload which is hypothesized to enable faculty to focus efforts on integrating convergent projects throughout the curriculum. The poster will present initial results on the interventions to the program including grading, software integration, projects, and narratives. The work presented will also cover an ethnographic study of faculty practices which serves as an early-stage baseline to calibrate longer-term changes. 

   more » « less
5. Why is engineering design important for all leaners?

   https://doi.org/10.56367/OAG-038-10193  

   Butler Songer, Nancy (January 2023, Open Access Government)

   Why is engineering design important for all leaners? Engineering design systematically identifies needs, wants, and problems and then devises solutions to address them. A central component of our work is guiding students in the engineered design of solutions to local environmental problems. Science in society and schools must be for all citizens. Reasons include the desire to prepare citizens with the tools and knowledge to address local and global problems. With funding from the U.S. National Science Foundation, we foster sustained learning of Science, Technology, Engineering, and Mathematics (STEM) for students from primary school through university. 

   more » « less