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Materials Similar to Nesting in graphical representations in physics

• 58%: Assessing students' ability to solve introductory physics problems using integrals in symbolic and graphical representations
• 57%: Student difficulties in translating between mathematical and graphical representations in introductory physics
• 56%: Is Instructional Emphasis on the Use of Non-Mathematical Representations Worth the Effort?
• 56%: Case Study: Students' Use of Multiple Representations in Problem Solving
• 56%: Expert and Novice Use of Multiple Representations During Physics Problem Solving
• 56%: Representing energy. II. Energy tracking representations
• 55%: Investigating graphical representations of slope and derivative without a physics context
• 55%: The Use of Representations in Evidence-Based and Non-Evidence-Based Physics Activities
• 49%: The Use of Multiple Representations and Visualizations in Student Learning of Introductory Physics: An Example from Work and Energy
• 49%: Student Interpretation of the Signs of Definite Integrals Using Graphical Representations
• 49%: Representation issues: Using mathematics in upper-division physics
• 48%: Representation use and strategy choice in physics problem solving
• 48%: Algebra-Based Students and Vector Representations: Arrow vs. ijk
• 48%: Network Analysis of Students' Representation Use in Problem Solving
• 46%: Just Math: A New Epistemic Frame
• 45%: Graphical representations of vector functions in upper-division E&M
• 45%: Using Johnson-Laird's cognitive framework of sense-making to characterize engineering students' mental representations in kinematics
• 44%: Assessment lessons from K-12 education research: Knowledge representation, learning, and motivation
• 44%: Role of Multiple Representations in Physics Problem Solving