More Like this

1. Investigating Collaborative Problem Solving Behaviors during STEM+C Learning in Groups with Different Prior Knowledge Distributions

   https://doi.org/10.22318/cscl2024.231933  

   Snyder, Caitlin; Wen, Cai-Ting; Hutchins, Nicole M; Vatral, Caleb; Liu, Chen-Chung; Biswas, Gautam (June 2024, International Society for the Learning Sciences (ISLS))

   Clarke-Midura, J; Kollar, I; Gu, X; D’Angelo, C (Ed.)

   In collaborative problem-solving (CPS), students work together to solve problems using their collective knowledge and social interactions to understand the problem and progress towards a solution. This study focuses on how students engage in CPS while working in pairs in a STEM+C (Science, Technology, Engineering, Mathematics, and Computing) environment that involves open-ended computational modeling tasks. Specifically, we study how groups with different prior knowledge in physics and computing concepts differ in their information pooling and consensus-building behaviors. In addition, we examine how these differences impact the development of their shared understanding and learning. Our study consisted of a high school kinematics curriculum with 1D and 2D modeling tasks. Using an exploratory approach, we performed in-depth case studies to analyze the behaviors of groups with different prior knowledge distributions across these tasks. We identify effective information pooling and consensus-building behaviors in addition to difficulties students faced when developing a shared understanding of physics and computing concepts. 

   more » « less
2. Studying Synergistic Learning of Physics and Computational Thinking in a Learning by Modeling Environment

   Hutchins, N.; Biswas, G.; Conlin, L.; Emara, M.; Grover, S.; Basu, S. (November 2018, Proceedings of the 26th International Conference on Computers in Education. Philippines: Asia-Pacific Society for Computers in Education)

   Synergistic learning of computational thinking (CT) and STEM has proven to effective in helping students develop better understanding of STEM topics, while simultaneously acquiring CT concepts and practices. With the ubiquity of computational devices and tools, advances in technology,and the globalization of product development, it is important for our students to not only develop multi-disciplinary skills acquired through such synergistic learning opportunities, but to also acquire key collaborative learning and problem-solving skills. In this paper, we describe the design and implementation of a collaborative learning-by-modeling environment developed for high school physics classrooms. We develop systematic rubrics and discuss the results of key evaluation schemes to analyze collaborative synergistic learning of physics and CT concepts and practices. 

   more » « less
3. Instructor facilitation of STEM+CT discourse: engaging, prompting and guiding students’ computational modeling in physics

   Snyder, C. (June 2022, Computersupported collaborative learning)

   Chinn, C. (Ed.)

   The integration of computational modeling into instruction in science classrooms is complex in that it requires the synergistic application of students’ developing science and computational thinking knowledge. This is not only difficult for students, but teachers often find it hard to parse the science content from the computational constructs to guide students when they have difficulties. Leveraging past literature that highlights the beneficial impact instructors can have when they immerse themselves in group problem-solving discussions, this paper examines the instructors’ role in facilitating students’ construction of and problem-solving with computational models. We utilize a case study approach to analyze instructor-facilitated, synchronous group discussions during applications of synergistic learning processes to understand how instructors may elicit students’ knowledge, misunderstanding, and difficulties to help guide, prompt, and engage groups in this complex task for more productive integration in K-12 science classrooms. We hope that this will lead to better scaffolding of students' learning, and better support for teachers when they use such curricula in classrooms. 

   more » « less
4. “I Think We Should...”: Analyzing Elementary Students’ Collaborative Processes for Giving and Taking Suggestions

   Tsan, J.; Rodríguez, F; Boyer, K.; Lynch, C. (April 2018, Proceedings of the Annual SIGCSE Conference on Innovation and Technology in Computer Science Education)

   Collaboration plays an essential role in computer science. While there is growing recognition that learners of all ages can benefit from collaborative learning, little is known about how elementary age children engage in collaborative problem solving in computer science. This paper reports on the analysis of a dataset of elementary students collaborating on a programming project. We found that children tend to make several different types of suggestions. In turn, their partners address those suggestions in different ways such as by implementing them directly in code or by replying through dialogue. We observe that students regularly accept or reject suggestions without explanation or explicit acknowledgement and that it is often unclear whether they understand the substance of the suggestion. These behaviors may inhibit the development of a shared understanding between the partners and limit the value of the collaborative process. These results can inform instructional practice and the development of new adaptive tools that facilitate productive collaborative problem solving in computer science. 

   more » « less
5. Examining Synergistic Learning of Physics and Computational Thinking through Collaborative Problem Solving in Computational Modeling

   Grover, S.; Biswas, G.; Hutchins, N.; Snyder, C.; & Emara, M. (April 2019, Annual Meeting of the American Education Research Association)

   Computational modeling has been shown to benefit integrated learning of science and computational thinking (CT), however the mechanics of this synergistic learning are not well understood. In this research, we examine discourse during collaborative computational model building through the lens of a collaborative problem solving framework to gain insights into collaboration and synergistic learning of high school physics and CT. We pilot our novel approach in the context of C2STEM, a designed modeling environment, and examine collaboration and synergistic learning episodes in a video capture of a dyad modeling 2D motion with constant velocities. Our findings exhibit the promise of our approach and lay the foundation for guiding future automated approaches to detecting the synergistic learning of science and CT. 

   more » « less