home - login - register

• Conferences
  • PERC 2026
  • FFPER: Puget Sound 2026
  • FFPER Series
  • Gordon Series
  • PERC Series
  • All Conferences
• Community
  • PER Programs
  • Community Events
  • Community Announcements
  • PER Jobs
  • For the Media
  • Wiki
  • PERTG & PERLOC
  • PER SOLO Group
  • PER Graduate Students
• Curriculum
  • Course Packages
  • Student Activities
  • Research Instruments
  • Pedagogy Guides
  • Browse All
  • Suggest a Material
• Research Articles
  • Browse
  • Advanced Search
  • Suggest an Article
• Dissertations
  • Browse
  • Suggest a Dissertation
• Serials
  • Reviews in PER
  • PERC Proceedings
  • PR-PER
  • AJP
  • Perticles

Materials Similar to Design tactics in curriculum development: Examples from the Paradigms in Physics ring cycle

• 40%: Research as a Guide for Curriculum Development: An Example from Introductory Electricity. Part II: Design of Instructional Strategies
• 38%: Design-based research as a model for systematic curriculum development: The example of a curriculum for introductory optics
• 30%: Research-based quantum instruction: Paradigms and Tutorials
• 29%: Investigating students’ mental models and knowledge construction of microscopic friction. II. Implications for curriculum design and development
• 29%: Paradigms in Physics: A new upper-division curriculum
• 29%: A framework for curriculum design to support mathematical sense making
• 29%: Research as a guide for curriculum development: An example from introductory spectroscopy. I. Identifying student difficulties with atomic emission spectra
• 28%: Research as a Guide for Curriculum Development: An Example from Introductory Electricity. Part I: Investigation of Student Understanding
• 28%: Research-design model for professional development of teachers: Designing lessons with physics education research
• 28%: Investigating students’ mental models and knowledge construction of microscopic friction. I. Implications for curriculum design and development
• 27%: Towards a research program in designing and evaluating teaching materials: An example from dc resistive circuits in introductory physics
• 26%: Learning about teaching and learning while learning physics: An analysis of 15 years of responsive curriculum development
• 26%: Examining the dynamics of decision making when designing curriculum in partnership with students: How should we proceed?
• 26%: Transforming the preparation of physics graduate teaching assistants: Curriculum development
• 25%: Interpretive Themes in Quantum Physics: Curriculum Development and Outcomes
• 25%: Design guidelines for adapting scientific research articles: An example from an introductory level, interdisciplinary program on soft matter
• 23%: Development and evaluation of large-enrollment, active-learning physical science curriculum
• 23%: Development and Evaluation of a Large-Enrollment, Active-Learning Physics Curriculum
• 23%: Curriculum development to improve student understanding of rolling motion