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1. Promoting Inclusivity in Computing (PINC) via Computing Application Minor

   Yoon, I; Pennings, P.; Kulkarni, A.; Okada, K; Domingo, C. (January 2018, 2018 CoNECD - The Collaborative Network for Engineering and Computing Diversity Conference)

   We aimed to build a new educational pathway that would provide basic training in computer science for women and students from underrepresented (UR) groups who otherwise may not take computer science classes in college. Specifically, this on-going project focused on creating a 2-year Computer Science (CS) program consisting of exciting new courses aimed at biology majors. Biology traditionally attracts large numbers of women, a significant number of students from UR groups, and has compelling needs for CS technology. The interdisciplinary program is training the next generation of innovators in the biological sciences who will be prepared to cross disciplinary boundaries. The program consists of the following: (1) computer science courses with content related to biology, (2) cohorts of students that progress through the program together, and (3) a small group peer mentoring environment, and (4) facilitated interdisciplinary research projects. Graduates from this program, referred to as "PINC" - Promoting INclusivity in Computing - will receive a “Minor in Computing Applications” in addition to their primary science degree in Biology. The program is now in its second year and thus far 60 students have participated. Among them, 73% are women and 51% are underrepresented minorities (URM). The majority of students in the PINC program stated that they would not have taken CS courses without the structured support of the PINC program. Here we present the data collected during this two year period as well as details about the Computing Application minor and programmatic components that are having a positive impact on student outcomes. 

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2. Supporting Elementary Teacher's Reflections on Equity in CS Education: A Case Study Approach

   https://doi.org/10.1145/3291279.3341208  

   Sullivan, Florence; Tulungen, Catherine; Veeragoudar, Sneha; Pektas, Emrah (August 2019, Proceedings of the 2019 ACM Conference on International Computing Education Research)

   The dearth of women and people of color in the field of computer science is a well-documented phenomenon. Following Obama's 2016 declaration of the need for a nationwide CS for All movement in the US, educators, school districts, states and the US-based National Science Foundation have responded with an explosion of activity directed at developing computer science learning opportunities in K-12 settings. A major component of this effort is the creation of equitable CS learning opportunities for underrepresented populations. As a result, there exists a strong need for educational research on the development of equity-based theory and practice in CS education. This poster session reports on a work-in-progress study that uses a case study approach to engage twenty in-service elementary school teachers in reflecting on issues of equity in CS education as part of a three-day CS professional development workshop. Our work is unfolding in the context of a four-year university/district research practice partnership in a mid-sized city in the Northeastern United States. Teachers in our project are working to co-design integrated CS curriculum units for K-5 classrooms. We developed four case studies, drawn from the first year of our project, that highlight equity challenges teachers faced in the classroom when implementing the CS lessons. The case studies follow the "Teacher Moments" template created by the Teaching Systems Lab in Open Learning at MIT. The case study activity is meant to deepen reflection and discussion on how to create equitable learning opportunities for elementary school students. We present preliminary findings. 

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3. X+CS: A Computing Pathway for Non-Computer Science Majors

   Mitchell, S; Cole, K; Joshi, A (March 2020, ASEE Mid Atlantic Section Spring Conference, 2020)

   With computing impacting most every professional field, it has become essential to provide pathways for students other than those majoring in computer science to acquire computing knowledge and skills. Virtually all employers and graduate and professional schools seek these skills in their employees or students, regardless of discipline. Academia currently leans towards approaches such as double majors or combined majors between computer science and other non-CS disciplines, commonly referred to as “CS+X” programs. These programs tend to require rigorous courses gleaned from the institutions’ courses for computer science majors. Thus, they may not meet the needs of majors in disciplines such as the social and biological sciences, humanities, and others. The University of Maryland, Baltimore County (UMBC) is taking an approach more suitably termed “X+CS” to fulfill the computing needs of non-CS majors. As part of a National Science Foundation (NSF) grant, we are developing a “computing” minor specifically to meet their needs. To date, we have piloted the first two of the minor’s approximately six courses. The first is a variation on the existing Computer Science I course required for majors but restricted to nonmajors. Both versions of the course use the Python language and cover the same programming content, but with the non-majors assigned projects with relevance to non-CS disciplines. We use the same student assessment measures of homework, projects, and examinations for both courses. After four semesters, results show that non-CS majors perform comparably to majors. Students also express increased interest in computing and satisfaction with being part of a non- CS major cohort. The second course was piloted in fall 2019. It is a new course intended to enhance and hone programming skills and introduce topics such as web scraping, HTML and CSS, web application development, data formats, and database use. Students again express increased interest in computing and were already beginning to apply the computing skills that they were learning to their non-CS courses. As a welcome side effect, we experienced a significant increase in the number of women and under-represented minorities (URMs) in these two courses when compared with CS-major specific courses. Overall, women comprised 52% of the population, with URMs following a similar upward trend. We are currently developing the third course in the computing minor and exploring options for the remaining three. Possibilities include electives from our Information Systems major. We will also be working with our science, social science, and humanities departments to utilize existing courses in those disciplines that apply computing. The student response that we have received thus far provides us with evidence that our computing minor will be popular among UMBC’s non-CS population, providing them with a more suitable and positive computing education than existing CS+X efforts. 

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4. Increase Performance in CS 2 via a Spiral Redesign of CS 1

   https://doi.org/10.1145/3478431.3499339  

   Lionelle, Albert; Ghosh, Sudipto; Say, Benjamin; Beveridge, J. Ross (February 2022, SIGCSE 2022: Proceedings of the 53rd ACM Technical Symposium on Computer Science Education)

   Computer Science (CS 1) offerings in most universities tend to be notoriously difficult. Over the past 60 years about a third of the students either fail or drop out of the course. Past research has focused on improving teaching methods through small changes without changing the overall course structure. The premise of our research is that restructuring the CS 1 course using a Spiral pedagogy based on principles for improving memory and recall can help students learn the information and retain it for future courses. Using the principles of Spacing, Interleaving, Elaboration, Practiced Retrieval, and Reflection, we fundamentally redesigned CS 1 with a complete reordering of topics. We evaluated the newly designed CS 1 by comparing the students with those coming from a traditional offering in terms of (1) CS 1 performance, (2) retention of students between CS 1 and 2, and (3) CS 2 performance. We demonstrate that the Spiral method helped students outperform those who learn via the traditional method by 9% on final exam scores in CS 1. Retention is increased between CS 1 and CS 2 with a 19.2% increase for women, and 9.2% overall. Furthermore, students continue to do better in CS 2 with increased grades across all assessments and show a 15% increase in passing grades. We provide a framework for the Spiral methodology so that others may replicate the design. Our results lead us to consider evaluating and improving the underlying methodology with which we teach Computer Science. 

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5. CS@Mines Successful S-STEM Scholarship Ecosystem for Low-Income and Underrepresented Students

   Camp, T.; Liebe, C.; Thiry, H. (April 2021, 52nd ACM Technical Symposium on Computer Science Education (SIGCSE '21))

   null (Ed.)

   The primary purpose of PATHS (Path Ambassadors to High Success), an NSF-funded S-STEM scholarship program, is to create new pathways and strengthen existing pathways for academically talented, low-income Colorado high school and community college students to study computer science (CS) at Colorado School of Mines (Mines). PATHS has achieved the following major project goals: 1) Increase number of academically talented, low-income students studying CS in Colorado; 4) Increase retention of these students; 3) Establish an active on-campus community to support PATHS scholars and similar students; 4) Engage scholars to perform CS recruitment and outreach at area high schools and community colleges; 5) Evaluate PATHS activities through comparative analysis to provide new insights on best practices for attracting and retaining academically talented, low-income CS students; 6) Broaden participation of historically underrepresented groups in CS; and 7) Develop a new flexible degree program combining other STEM fields and CS. PATHS students are diverse (e.g., 40.8% from under- represented groups in computing) and academically successful (e.g., mean GPA is 3.4). Thus far, the program has awarded scholarships to 49 students and retained 93.9% of the students. Of the 49 students, six have graduated and three of the six have also pursued a CS Master’s degree. 

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