Abstract
In this paper, we report on a project concerned with the role of cognition during problem solving. We specifically explore the categories of mental representations that students work with during problem solving of different representational task formats. The sample, consisting of 19 engineering students taking a calculus-based physics course, attempted tasks from the topics of kinematics and work. Profiles were designed to capture the overall actions and reasoning of individual students across the various tasks. Two main profiles emerged from each topic under consideration. They were related to the Johnson-Laird cognitive framework to infer about the kinds of mental constructs. The results indicate that, for both topics, students work primarily at the level of propositional mental representation. When handling the kinematics tasks, a few students construct mental images and none of them can be categorized as using a mental model. In contrast, in the context of work, none of the participants generated a mental image while a minority of the sample was classified as using a mental model. Moreover, a comparison across the two topics indicates the predominance of propositional mental representation.
Highlights
In recent years, physics education has placed much emphasis on the application of a model-based approach for teaching and learning
When handling the nondirected kinematics tasks, we found that about 58% of the cohort (11 in 19) constructed a propositional mental representation while 42% of the cohort generated a mental image
For the topic on work, the results indicate that most of the students generated propositional mental representation (79%, 15 in 19), a minority of the sample constructed a mental model (21%, four in 19), while none of the students were classified with a mental image
Summary
Physics education has placed much emphasis on the application of a model-based approach for teaching and learning. Instructional strategies based on a modeling approach have been used to facilitate conceptual understanding in physics [1,2,3]. The model deployment phase includes the application of these models to new situations. This phase may lead to changes or refinement in the model previously constructed by the student.
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