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1. Variation in Engagement Behaviors among Student-Centered Pedagogies

   https://doi.org/10.1145/3641554.3701894  

   Campbell, Patricia B; Kussmaul, Clif; Mayfield, Chris; Hu, Helen H; Campbell-Mortman, Seth (February 2025, ACM)

   Numerous studies have shown that active learning and student-centered pedagogies lead to better student outcomes, such as higher grades, enhanced self-efficacy, and an increased sense of belonging. These outcomes are closely linked to higher levels of student engagement. To better understand the relationship between student engagement and pedagogical approach, our research documents what actually happens in CS1 classes that implement active learning. This paper presents a case study of two instructors, at different undergraduate institutions, teaching with Process Oriented Guided Inquiry Learning (POGIL) and Interactive Lectures. Using structured classroom observations and student surveys, we measure the engagement of the same students in different class periods taught by the same instructor. Our study investigates the differences and similarities in self-reported and observed student behaviors, as well as observed instructor behaviors. We examine how instructor behavior impacts student behavior. The results show significant differences in observed instructor and student behaviors based on the pedagogical approach. In class periods where instructors spoke more, students were more inclined to watch or listen rather than actively work or discuss, coupled with higher levels of student distraction. Our results provide insight into how specific teaching practices can lead to more engaging classrooms and better student outcomes. 

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2. Engaging CS1 Students with Audio Themed Assignments

   Mcquaigue, Matthew; Larson, Mack; Smith, Philip; Melech, Sydney; Subramanian, Kalpathi; Saule, Erik (April 2024, Journal of computing sciences in colleges)

   ACM (Ed.)

   Early computer science courses (CS1, CS2) are the cornerstone of student understanding of computer science. These courses introduce the foundational knowledge of computer science needed to understand more complex topics and to be successful in follow-on courses. It is thus important to introduce CS concepts in an engaging and easy-to-understand manner to increase student interest and retention. This paper presents a new approach to teaching the Computer Science 1 (CS1) course through our BRIDGES system. This approach aims to increase student engagement and improve learning outcomes by using audio-based assignments that they can manipulate and process audio signal information, as well as visualize and play them. We explain how to design and implement audiobased assignments and connect them to fundamental programming constructs such as variables, control flow, and simple data structures, such as arrays. These assignments encourage and engage students by using audio data they are interested in to write code, promoting problem-solving and improvements in their critical thinking skills. 

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3. Confirmatory factor analysis of the framing agency survey.

   https://doi.org/10.18260/1-2--42737  

   Wilson-Fetrow, M.; Svihla, V.; Olewnik, A. (July 2023, Proceedings of the ASEE Annual Conference and Exhibition)

   In this research paper, we investigate the structure and validity of survey data related to students’ framing agency. In order to promote increased opportunities for students to engage in and learn to frame design problems that are innovative and empathetic, there is a need for instruments that can provide information about student progress and the quality of learning experiences. This is a complex problem because, compared to problem solving, design problem framing is less studied and harder to predict due to the higher levels of student agency involved. To address this issue, we developed a survey to measure framing agency, which is defined as opportunities to frame and reframe design problems and learn in the process. This study extends past research which focused on the construct of framing agency and developing an instrument to measure it following best practices in survey design, including using exploratory factor analysis of pilot data, which recovered six factors related to shared and individual consequentiality, problem structure and constrainedness, and learning. However, as a pilot, the sample limited generalizability; the current study addresses this limitation. We used a national cohort that included multiple engineering disciplines (biomedical, mechanical, chemical, electrical, computer, aerospace), types of formal design projects (e.g., first-year, design-spine, senior capstone) and institution types, including private religious; Hispanic-serving; public land-grant; and research flagship institutions (N=449). We report sample characteristics and used confirmatory factor analysis (CFA) to provide validity evidence, reporting the chi-square and standardized root mean square residual as estimates of fit. We report Cronbach’s alpha as a measure of internal consistency. We found that overall, the CFA aligned with the prior exploratory results, in this case, recovering four factors, measured on a seven-point scale: shared consequentiality (the extent to which the student identifies that their understanding of the problem changed as result of a teammate’s decision, M = 6.15; SD = 1.13); learning as consequentiality (the extent to which the student identifies learning as the result of decisions, M = 5.88; SD = 0.98); constrainedness (the extent to which the student reports the ability to make decisions despite design constraints, M = 4.95; SD = 1.49); and shared tentativeness (the extent to which the student identifies uncertainty about the problem and solution, M = 4.02; SD = 1.76). This suggests the survey can provide valid data for instructional decisions and further research into how students learn to frame engineering design problems and what role framing plays in their professional formation. 

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4. Self-Efficacy Study in Computing Among College Freshmen

   Ghimire, Amrita; Lee, S.; Lineberry, L. (July 2020, ASEE Annual Conference proceedings)

   Computer Science (CS) is not introduced equitably across K-12 schools, yet it is increasingly a necessary skill regardless of vocational pathway. Co-curricular activities such as summer camps have become a popular way to introduce CS to K-12 students. Researchers at our institution, through partnerships with other educational institutions and practitioners, developed a transdisciplinary approach of teaching CS in K-12 informal learning environments. Building on positive results in the K-12 informal learning environment, researchers are exploring the applicability of the transdisciplinary modules in formal instruction for early college learners in CS0 and CS1 courses. This paper explores self-efficacy data collected from multiple CS0 and CS1 courses. Learners include freshmen in computing majors and in non-computing majors. We compare their self efficacy growth in computing across race and gender, considering their formal or informal CS education experiences prior to entering college. This work is a part of a larger effort to redesign CS0 and CS1 courses to introduce more complex concepts and important design concepts such as parallel and distributed computing earlier in the curriculum. The authors’ longer-term goal is to investigate active learning strategies that will introduce higher level computer science topics early in the curriculum to enable students to recognize content applicability earlier in their college pathway. 

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5. A Flexible Formative/Summative Grading System for Large Courses

   https://doi.org/10.1145/3545945.3569810  

   Lionelle, Albert; Ghosh, Sudipto; Moraes, Marcia; Winick, Tran; Nielsen, Lindsey (March 2023, SIGCSE 2023: Proceedings of the 54th ACM Technical Symposium on Computer Science Education)

   Students in entry level CS courses come from diverse backgrounds and are learning study and time management skills. Our belief for their success is that they must master a growth mindset and that the final grade should represent their final mastery of topics in the course. Traditional grading systems tend to be too restrictive and hinder a growth mindset. They require strict deadlines that fail to easily account for student accommodations and learning differences. Furthermore, they run into averaging and scaling issues with 59% of a score counting as failing, making it difficult for students to redeem grades even if they later demonstrate mastery of topics. We designed a formative/summative grading system in our CS0 and CS1 classes for both on-campus and online students to support a structured growth mindset. Students can redo formative assignments and are provided flexible deadlines. They demonstrate their mastery in summative assignments. While being inspired by other grading systems, our system works seamlessly with auto-grading tools used in large, structured courses. Despite the flexibility, the courses provided a level of rigor before allowing students to continue onto the next course. Overall, 65% of students resubmitted assignments increasing their scores, participated in ungraded assignments, and used formative assignments for additional practice without a distinction between race or gender. These students went to the traditional follow-on CS2 course and 94% passed compared with 71% who took CS1 with a traditional grading system. 

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