Selected as the Michigan Council of Teachers of Mathematics winter book club book!
Rich tasks, collaborative work, number talks, problem-based learning, direct instruction…with so many possible approaches, how do we know which ones work the best? In
Visible Learning for Mathematics, six acclaimed educators assert it’s not about which one—it’s about when—and show you how to design high-impact instruction so all students demonstrate more than a year’s worth of mathematics learning for a year spent in school.
That’s a high bar, but with the amazing K-12 framework here, you choose the right approach at the right time, depending upon where learners are within three phases of learning: surface, deep, and transfer. This results in ‘visible’ learning because the
effect is tangible. The framework is forged out of current research in mathematics combined with John Hattie’s synthesis of more than 15 years of education research involving
300 million students.
Chapter by chapter, and equipped with video clips, planning tools, rubrics, and templates, you get the inside track on which instructional strategies to use at each phase of the learning cycle:
Surface learning phase: When—through carefully constructed experiences—students explore new concepts and make connections to procedural skills and vocabulary that give shape to developing conceptual understandings.
Deep learning phase: When—through the solving of rich high-cognitive tasks and rigorous discussion—students make connections among conceptual ideas, form mathematical generalizations, and apply and practice procedural skills with fluency.
Transfer phase: When students can independently think through more complex mathematics, and can plan, investigate, and elaborate as they apply what they know to new mathematical situations.
To equip students for higher-level mathematics learning, we have to be clear about where students are, where they need to go, and what it looks like when they get there.
Visible Learning for Math brings about powerful, precision teaching for K-12 through intentionally designed guided, collaborative, and independent learning.
Tabla de materias
List of Figures
List of Videos
About the Teachers Featured in the Videos
Foreword
About the Authors
Acknowledgments
Preface
Chapter 1. Make Learning Visible in Mathematics
Forgetting the Past
What Makes for Good Instruction?
The Evidence Base
Meta-Analyses
Effect Sizes
Noticing What Does and Does Not Work
Direct and Dialogic Approaches to Teaching and Learning
The Balance of Surface, Deep, and Transfer Learning
Surface Learning
Deep Learning
Transfer Learning
Surface, Deep, and Transfer Learning Working in Concert
Conclusion
Reflection and Discussion Questions
Chapter 2. Making Learning Visible Starts With Teacher Clarity
Learning Intentions for Mathematics
Student Ownership of Learning Intentions
Connect Learning Intentions to Prior Knowledge
Make Learning Intentions Inviting and Engaging
Language Learning Intentions and Mathematical Practices
Social Learning Intentions and Mathematical Practices
Reference the Learning Intentions Throughout a Lesson
Success Criteria for Mathematics
Success Criteria Are Crucial for Motivation
Getting Buy-In for Success Criteria
Preassessments
Conclusion
Reflection and Discussion Questions
Chapter 3. Mathematical Tasks and Talk That Guide Learning
Making Learning Visible Through Appropriate Mathematical Tasks
Exercises Versus Problems
Difficulty Versus Complexity
A Taxonomy of Tasks Based on Cognitive Demand
Making Learning Visible Through Mathematical Talk
Characteristics of Rich Classroom Discourse
Conclusion
Reflection and Discussion Questions
Chapter 4. Surface Mathematics Learning Made Visible
The Nature of Surface Learning
Selecting Mathematical Tasks That Promote Surface Learning
Mathematical Talk That Guides Surface Learning
What Are Number Talks, and When Are They Appropriate?
What Is Guided Questioning, and When Is It Appropriate?
What Are Worked Examples, and When Are They Appropriate?
What Is Direct Instruction, and When Is It Appropriate?
Mathematical Talk and Metacognition
Strategic Use of Vocabulary Instruction
Word Walls
Graphic Organizers
Strategic Use of Manipulatives for Surface Learning
Strategic Use of Spaced Practice With Feedback
Strategic Use of Mnemonics
Conclusion
Reflection and Discussion Questions
Chapter 5. Deep Mathematics Learning Made Visible
The Nature of Deep Learning
Selecting Mathematical Tasks That Promote Deep Learning
Mathematical Talk That Guides Deep Learning
Accountable Talk
Supports for Accountable Talk
Teach Your Students the Norms of Class Discussion
Mathematical Thinking in Whole Class and Small Group Discourse
Small Group Collaboration and Discussion Strategies
When Is Collaboration Appropriate?
Grouping Students Strategically
What Does Accountable Talk Look and Sound Like in Small Groups?
Supports for Collaborative Learning
Supports for Individual Accountability
Whole Class Collaboration and Discourse Strategies
When Is Whole Class Discourse Appropriate?
What Does Accountable Talk Look and Sound Like in Whole Class Discourse?
Supports for Whole Class Discourse
Using Multiple Representations to Promote Deep Learning
Strategic Use of Manipulatives for Deep Learning
Conclusion
Reflection and Discussion Questions
Chapter 6. Making Mathematics Learning Visible Through Transfer Learning
The Nature of Transfer Learning
Types of Transfer: Near and Far
The Paths for Transfer: Low-Road Hugging and High-Road Bridging
Selecting Mathematical Tasks That Promote Transfer Learning
Conditions Necessary for Transfer Learning
Metacognition Promotes Transfer Learning
Self-Questioning
Self-Reflection
Mathematical Talk That Promotes Transfer Learning
Helping Students Connect Mathematical Understandings
Peer Tutoring in Mathematics
Connected Learning
Helping Students Transform Mathematical Understandings
Problem-Solving Teaching
Reciprocal Teaching
Conclusion
Reflection and Discussion Questions
Chapter 7. Assessment, Feedback, and Meeting the Needs of All Learners
Assessing Learning and Providing Feedback
Formative Evaluation Embedded in Instruction
Summative Evaluation
Meeting Individual Needs Through Differentiation
Classroom Structures for Differentiation
Adjusting Instruction to Differentiate
Intervention
Learning From What Doesn’t Work
Grade-Level Retention
Ability Grouping
Matching Learning Styles With Instruction
Test Prep
Homework
Visible Mathematics Teaching and Visible Mathematics Learning
Conclusion
Reflection and Discussion Questions
Appendix A. Effect Sizes
Appendix B. Standards for Mathematical Practice
Appendix C. A Selection of International Mathematical Practice or Process Standards
Appendix D- Eight Effective Mathematics Teaching Practices
Appendix E. Websites to Help Make Mathematics Learning Visible
References
Index
Sobre el autor
Sara Delano Moore is an independent mathematics education consultant at SDM Learning. A fourth-generation educator, her work focuses on helping teachers and students understand mathematics as a coherent and connected discipline through the power of deep understanding and multiple representations for learning. Sara has worked as a classroom teacher of mathematics and science in the elementary and middle grades, a mathematics teacher educator, Director of the Center for Middle School Academic Achievement for the Commonwealth of Kentucky, and Director of Mathematics & Science at ETA hand2mind. Her journal articles appear in Mathematics Teaching in the Middle School, Teaching Children Mathematics, Science & Children, and Science Scope.