An official website of the United States government
While computational thinking has gained popularity in K-12 schools to increase access to computing tools and practices, there is still limited understanding on how to broaden participation of students with disabilities in computational thinking (CT). One approach to increasing access to computing to students with disabilities is to educate future special education teachers to bring CT into their instruction. This study examined the influence of integrating CT into assistive technology course for special education pre-service teachers. Our results suggest that integrating CT into special educa- tion teacher preparation coursework can have a positive impact on how pre-service teachers see the value of bringing computational practices to students with disabilities.
more »
« less
Measuring Teacher Self-Efficacy for Integrating Computational Thinking in Science (T-SelECTS)
With computational thinking (CT) emerging as a prominent component of 21st century science education, equipping teachers with the necessary tools to integrate CT into science lessons becomes increasingly important. One of these tools is confidence in their ability to carry out the integration of CT. This confidence is conceptualized as self-efficacy: the belief in one’s ability to perform a specific task in a specific context. Self-reported self-efficacy in teaching has shown promise as a measure of future behavior and is linked to teacher performance. Current measures of teacher self-efficacy to integrate CT are limited, however, by narrow conceptualizations of CT, oversight of survey design research, and limited evidence of instrument validity. We designed a valid and reliable measure of Teacher Self-Efficacy for integrating Computational Thinking in Science (T-SelECTS) that fits a single latent factor structure. To demonstrate the instrument’s value, we collected data from 58 pre-service teachers who participated in a CT module within their science methods course at a large Mid-Atlantic university. We found evidence of significant development in pre-service teachers’ self-efficacy for integrating CT into science instruction. We discuss how the T-SelECTS instrument could be used in teacher education courses and professional development to measure change in self-efficacy.
more »
« less
- Award ID(s):
- 1639891
- PAR ID:
- 10342533
- Date Published:
- Journal Name:
- Educational Innovations and Emerging Technologies
- Volume:
- 1
- Issue:
- 1
- ISSN:
- 2737-5315
- Page Range / eLocation ID:
- 3 to 14
- Format(s):
- Medium: X
- Sponsoring Org:
- National Science Foundation
More Like this
-
-
Gresalfi, M. and (Ed.)The importance of integrating computational thinking (CT) into existing school structures, like core content domains, has emerged from efforts to improve computer science education in the U.S. In the past, computer science has often been treated as an elective or enrichment activity, which limits students’ exposure to foundational computing ideas, especially in underserved schools. However, given the ubiquity technology plays in our lives, it is imperative that all students have access to CT. Few studies have focused on how pre-service teachers (PSTs) learn about CT. Some researchers argue that CT integration into K-12 education belongs in teacher preparation programs and that teacher educators should develop courses aimed at supporting PSTs’ understanding of CT in the context of schools. This paper explores the ways in which PSTs begin to understand CT and how they work to integrate CT into their core subject areas.more » « less
-
Despite the increasing attention to infusing CT into middle and high school content area classrooms, there is a lack of information about the most effective practices and models to support teachers in their efforts to integrate disciplinary content and CT principles. To address this need, this paper proposes the Code, Connect and Create (3C) professional development (PD) model, which was designed to support middle and high school content area teachers in infusing computational thinking into their classrooms. To evaluate the model, we analyzed quantitative and qualitative data collected from Infusing Computing PD workshops designed for in-service science, math, English language arts, and social studies teachers located in two Southeastern states. Drawing on findings from our analysis of teacher-created learning segments, surveys, and interviews, we argue that the 3C professional development model supported shifts in teacher understandings of the role of computational thinking in content area classrooms, as well as their self-efficacy and beliefs regarding CT integration into disciplinary content. We conclude by offering implications for the use of this model to increase teacher and student access to computational thinking practices in middle and high school classrooms.more » « less
-
Abstract In‐service teachers implementing a science, technology, engineering, and math (STEM) curriculum centered on computational thinking (CT) work with unique content and pedagogical experiences. Understanding how curriculum design and teacher professional development affect curriculum implementation can help researchers understand the critical aspects of supporting the teacher in “just right” ways to learn and teach an embedded CT curriculum. We qualitatively analyzed 22 teachers' discourse through a case study approach. We identified how CT is afforded and constrained through curriculum design and teacher professional development support. Teachers expressed that the supports that were critical to their confidence and perceived ability to teach CT were (a) a program that provides “just right” support, (b) a program that provides options and individualization, (c) an internal personal identity that embraces continual innovation and learning, and (d) an educational system that is encouraging and supportive of the effort and creativity it requires to implement innovative and intensive embedded CT programs. These findings can inform how to support teachers to integrate CT within existing STEM curricula as a core scientific and mathematical practice and to foster student interest in computer science.more » « less
-
Integrating computational thinking (CT) in the science classroom presents the opportunity to simultaneously broaden participation in computing, enhance science content learning, and engage students in authentic scientific practice. However, there is a lot more to learn on how teachers might integrate CT activities within their existing curricula. In this work, we describe a process of co-design with researchers and teachers to develop CT-infused science curricula. Specifically, we present a case study of one veteran physics teacher whose conception of CT during a professional development institute changed over time. We use this case study to explore how CT is perceived in physics instruction, a field that has a long history of computational learning opportunities. We also discuss how a co-design process led to the development of a lens through which to identify fruitful opportunities to integrate CT activities in physics curricula which we term computational transparency–purposefully revealing the inner workings of computational tools that students already use in the classroom.more » « less
- Free Publicly Accessible Full Text
-
Accepted Manuscript1.0
- Journal Article:
- https://doi.org/10.35745/eiet2021v01.01.0002
