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1. An Outdoor Project-Based Learning Program: Strategic Support and the Roles of Students with Visual Impairments Interested in STEM

   https://doi.org/10.1007/s10956-020-09874-0  

   Tsinajinie, G. (January 2021, Journal of science education and technology)

   null (Ed.)

   A qualitative study was conducted to understand how middle and high school students with visual impairments (VI) engage in Science, Technology, Engineering and Mathematics (STEM). The Readiness Academy, a Project-Based Learning (PBL) intervention, was designed to provide a week-long, immersive, outdoor, and inquiry-based science education program to students with VI. We analyzed 187 photographs, camp associate intern notes, and researcher memos first using emotion coding, followed by process coding to structure initial codes and categories into seven research activities. We used axial coding as a secondary cycle coding method to determine four consistent themes across all research activities: apprenticeship, collaboration, accessibility, and independence. We found that the inclusion of purposeful accessibility, such as assistive technology and multisensory experiences, supported how students with VI engaged in STEM education. The findings reflect how students dynamically fulfilled roles as apprentices, collaborative members, and independent researchers within the program’s context of PBL and outdoor science education. 

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2. A Study of Common Concerns Inhibiting Teacher Enactment of Computational Thinking into Project-based Mathematics and Career Technical Education.

   https://doi.org/10.5220/0009337403410349  

   Majumder, Subhrajit (May 2020, CSEDU)

   null (Ed.)

   Recent studies have shown that US high school students are not as prolific as other countries in terms of their performance in mathematics. One of the most effective solutions can be a change in the way mathematics subjects is taught in high school. The NSF-funded “Understanding How Integrated Computational Thinking, Engineering Design, and Mathematics Can Help Students Solve Scientific and Technical Problems in Career Technical Education (INITIATE) project is a collaboration of The University of Toledo and high schools in Toledo that aims to improve mathematics teaching. Project-based learning (PBL) and integrating math with career technology education (CTE) have been established as efficient ways to improve high school students’ understanding of mathematics. Nevertheless, implementation of new ways of teaching is not always easy for the teachers, and many factors may inhibit the teachers from implementing PBL methods. This research analyzes common concerns teachers experienced regarding enacting new teaching methodologies in their classroom. The Stages of Concern Questionnaire (SoCQ) was used to measure the teachers’ perceptions of and comfort with implementing computational thinking (CT) concepts PBL lessons. Possible relationships between teachers’ SoCQ CBAM score and other variables such as their understanding of PBL and CTE are examined and discussed. 

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3. Project-Based Software Engineering Curriculum for Secondary Students

   https://doi.org/10.1145/3605468.3605501  

   Gransbury, Isabella; Brock, Janet; Root, Emily; Catete, Veronica; Barnes, Tiffany; Grover, Shuchi; Ledeczi, Akos (September 2023, Proceedings of the 18th WiPSCE Conference on Primary and Secondary Computing Education Research)

   Background. Software Engineering (SE) is a new and emerging topic in secondary computer science classrooms. However, a review of the recent literature has identified an overall lack of reporting on the development of SE secondary curriculum. Previous studies also report low student engagement when teaching these concepts. Objectives. In this experience report, we discuss the development of a 9-week, project-based learning (PBL) SE curriculum for secondary students. During this curriculum, students create a socially relevant project in groups of two to three. We discuss displays of participant engagement with CS concepts through the PBL pedagogy and the SE curriculum. Method. We examine participant engagement through group artifact interviews about student experiences during a week-long, virtual summer camp that piloted activities from our curriculum. During this camp, students followed a modified SE life cycle created by the authors of the paper. Findings. Participants showed engagement with the curriculum through various aspects of PBL, such as autonomy, creativity, and personal interest in their project topic. Implications. The lessons learned from this experience report suggest that PBL pedagogy can increase student engagement when teaching CS concepts, and this pedagogy provides detail and structure for future secondary SE curriculum implementations to support educators in the classroom 

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4. Conducting the Pilot Study of Integrating AI: An Experience Integrating Machine Learning into Upper Elementary Robotics Learning (Work in Progress)

   Xu, G.; Zabner, D.; Cross, J.; Nadler, D.; Coxon, S.; Engelkenjohn, K. (June 2023, ASEE annual conference exposition proceedings)

   Artificial Intelligence (AI) enhanced systems are widely adopted in post-secondary education, however, tools and activities have only recently become accessible for teaching AI and machine learning (ML) concepts to K-12 students. Research on K-12 AI education has largely included student attitudes toward AI careers, AI ethics, and student use of various existing AI agents such as voice assistants; most of which has focused on high school and middle school. There is no consensus on which AI and Machine Learning concepts are grade-appropriate for elementary-aged students or how elementary students explore and make sense of AI and ML tools. AI is a rapidly evolving technology and as future decision-makers, children will need to be AI literate[1]. In this paper, we will present elementary students’ sense-making of simple machine-learning concepts. Through this project, we hope to generate a new model for introducing AI concepts to elementary students into school curricula and provide tangible, trainable representations of ML for students to explore in the physical world. In our first year, our focus has been on simpler machine learning algorithms. Our desire is to empower students to not only use AI tools but also to understand how they operate. We believe that appropriate activities can help late elementary-aged students develop foundational AI knowledge namely (1) how a robot senses the world, and (2) how a robot represents data for making decisions. Educational robotics programs have been repeatedly shown to result in positive learning impacts and increased interest[2]. In this pilot study, we leveraged the LEGO® Education SPIKE™ Prime for introducing ML concepts to upper elementary students. Through pilot testing in three one-week summer programs, we iteratively developed a limited display interface for supervised learning using the nearest neighbor algorithm. We collected videos to perform a qualitative evaluation. Based on analyzing student behavior and the process of students trained in robotics, we found some students show interest in exploring pre-trained ML models and training new models while building personally relevant robotic creations and developing solutions to engineering tasks. While students were interested in using the ML tools for complex tasks, they seemed to prefer to use block programming or manual motor controls where they felt it was practical. 

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5. Scholarship Program Initiative via Recruitment, Innovation, and Transformation

   https://doi.org/10.18260/p.24693  

   Ferguson, Chip; Yanik, Paul; Chang, Guanghsu; Kaul, Sudhir (June 2015, American Society for Engineering Education Annual Conference and Exposition)

   The National Science Foundation’s funded ($625,179) SPIRIT: Scholarship Program Initiative via Recruitment, Innovation, and Transformation at Western Carolina University creates a new approach to the recruitment, retention, education, and placement of academically talented and financially needy engineering and engineering technology students. Twenty-Seven new and continuing students were recruited into horizontally and vertically integrated cohorts that will be nurtured and developed in a Project Based Learning (PBL) community characterized by extensive faculty mentoring, fundamental and applied undergraduate research, hands-on design projects, and industry engagement. Our horizontal integration method creates sub-cohorts with same-year students from different disciplines (electrical, mechanical, etc.) to work in an environment that reflects how engineers work in the real world. Our vertical integration method enables sub-cohorts from different years to work together on different stages of projects in a PBL setting. The objectives of the SPIRIT program will ensure an interdisciplinary environment that enhances technical competency through learning outcomes that seek to improve critical skills such as intentional learning, problem solving, teamwork, management, interpersonal communications, and leadership. Support for the student scholars participating in this program incorporates several existing support services offered by the host institution and school, including a university product development center. This paper will discuss several aspects of the program including participant selection and initial cohort demographics; implementation of the vertical-based cohort model in PBL; program and student assessment models; and associated student activities and artifact collection used to foster student success in the program and after graduation. Successful implementation of the SPIRIT program will create a replicable model that will broadly impact 21st century engineering education and workforce preparedness. 

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