1. NCTM Principles to Actions: Turning Standards into Learning
Diane J. Briars
President
National Council of Teachers of Mathematics
2015 Leadership Seminar on Mathematics Professional Development
March 18, 2015

2. Electronic copies of slides are available
FYI
Electronic copies of slides are available
by request

3. National Council of Teachers of Mathematics www.nctm.org

4. National Council of Teachers of Mathematics www.nctm.org
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5. National Council of Teachers of Mathematics www.nctm.org
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6. NCTM Conferences www.nctm.org
2015 Annual Meeting and Exposition April 15–18, 2015 Boston 2016 Annual Meeting and Exposition April 13–16, 2016 San Francisco

7. NCTM Interactive Institutes www.nctm.org
Algebra Readiness for Every Student July 20-22, 2015, Chicago, IL
Connecting Number and Operations in Classrooms July 23-25, 2015, Chicago, IL
Engaging Students in Learning: Mathematical Practices, July 27-July 29, 2015, Anaheim, CA
Engaging Students in Learning: Mathematical Practices and Process Standards July 30-August 1, 2015, Anaheim, CA

8. NCTM Regional Conferences www.nctm.org
Atlantic City, NJ October 21-23, 2015
Minneapolis, MN November 11-13, 2015
Nashville, TN November 18-20, 2015

9. Agenda
Discuss key shifts in instructional practice required to implement Common Core State Standards for Mathematics.
Read and analyze a short case of a teacher (Mr. Harris or Ms. Culver) who is attempting to support his/her students’ learning.
Discuss selected effective teaching practices as described in NCTM’s Principles to Actions: Ensuring Mathematical Success for All, and relate them to the case.
Discuss next steps you will take to promote effective teaching practices in your setting.

10. High Quality Standards Are Necessary, but Insufficient, for Effective Teaching and Learning

11. Principles to Actions: Ensuring Mathematical Success for All
Describes the supportive conditions, structures, and policies required to give all students the power of mathematics
Focuses on teaching and learning
Emphasizes engaging students in mathematical thinking
Describes how to ensure that mathematics achievement is maximized for every student
Is not specific to any standards; it’s universal

12. Key Features of CCSS-M
Focus: Focus strongly where the standards focus.
Coherence: Think across grades, and link to major topics
Rigor: In major topics, pursue conceptual understanding, procedural skill and fluency, and application
Standards for Mathematical Practice

13. Key Features of CCSS-M
Focus: Focus strongly where the standards focus.
Coherence: Think across grades, and link to major topics
Rigor: In major topics, pursue conceptual understanding, procedural skill and fluency, and application
Standards for Mathematical Practice

14. Phil Daro, 2010 14

15. Phil Daro, 2010 15

16. Other “Butterflies”? FOIL Cross multiplication
Keep-change-flip, KFC, etc.
Keep-change-change
Key words
Does McDonalds Sell Cheese Burgers?

17. Key Instructional Shift
From emphasis on: How to get answers To emphasis on: Understanding mathematics

18. Standards for Mathematical Practice
Make sense of problems and persevere in solving them.
Reason abstractly and quantitatively.
Construct viable arguments and critique the reasoning of others.
Model with mathematics.
Use appropriate tools strategically.
Attend to precision.
Look for and make use of structure.
Look for and express regularity in repeated reasoning.

19. Implementing CCSS-M Requires
Instructional practices that promote students’ development of conceptual understanding and proficiency in the Standards for Mathematical Practice.

20. We Must Focus on Instruction
Student learning of mathematics “depends fundamentally on what happens inside the classroom as teachers and learners interact over the curriculum.”
(Ball & Forzani, 2011, p. 17)
“Teaching has 6 to 10 times as much impact on achievement as all other factors combined ... Just three years of effective teaching accounts on average for an improvement of 35 to 50 percentile points.”
Schmoker (2006, p.9) 

21. for School Mathematics
Guiding Principles
for School Mathematics
Teaching and Learning
Effective teaching is the non-negotiable core that ensures that all students learn mathematics at high levels.

22. for School Mathematics
Guiding Principles
for School Mathematics
Teaching and Learning
Access and Equity
Curriculum
Tools and Technology
Assessment
Professionalism
Essential Elements
of Effective Math
Programs

23. For Each Principle Productive and Unproductive Beliefs are Listed
Obstacles to Implementing the Principle are Outlined
Overcoming the Obstacles
Taking Action
Leaders and Policymakers
Principles, Coaches, Specialists, Other School Leaders
Teachers

24. for School Mathematics
Guiding Principles
for School Mathematics
Teaching and Learning
Access and Equity
Curriculum
Tools and Technology
Assessment
Professionalism

25. Beliefs about Teaching and Learning?
Complete the survey (p. 1):
Rate the extent to which you agree with each statement.
Compare with others sitting near you.
How might these beliefs affect your work?
Who else’s beliefs about teaching and learning affects your work?
Provide handout

26. Unproductive vs Productive Beliefs about Teaching and Learning
Beliefs should not be viewed as good or bad.
Beliefs are unproductive when they hinder implementation of effective instructional practice or limit student access to important mathematics content and practices.
Provide handout

27. p. 4

28. Looking into the Classroom
Select a problem:
Band Concert—Grade 3
Pay It Forward—Algebra 1
Please work the problem as if you were a student.
When done, share your work with people at your table.
Discuss:
What mathematical content does this task support?
What mathematical practices did you engage in?

29. Standards for Mathematical Practice
Make sense of problems and persevere in solving them.
Reason abstractly and quantitatively.
Construct viable arguments and critique the reasoning of others.
Model with mathematics.
Use appropriate tools strategically.
Attend to precision.
Look for and make use of structure.
Look for and express regularity in repeated reasoning.

30. Looking into the Classroom
Read the case for your problem:
Mr. Harris (pp 3-4)
Ms. Culver (pp 5-6)
Make note of what the teacher did before or during instruction to support his/her students’ learning and understanding.
Talk with a neighbor about the actions and interactions that you identified as supporting student learning.

31. Principle on Teaching and Learning
An excellent mathematics program requires effective teaching that engages students in meaningful learning through individual and collaborative experiences that promote their ability to make sense of mathematical ideas and reason mathematically.

32. Mathematics Teaching Practices
Effective
Mathematics Teaching Practices
Establish mathematics goals to focus learning.
Implement tasks that promote reasoning and problem solving.
Use and connect mathematical representations.
Facilitate meaningful mathematical discourse.
Pose purposeful questions.
Build procedural fluency from conceptual understanding.
Support productive struggle in learning mathematics.
Elicit and use evidence of student thinking.

33. Establish Mathematics Goals
To Focus Learning
Learning Goals should:
Clearly state what it is students are to learn and understand about mathematics as the result of instruction;
Be situated within learning progressions; and
Frame the decisions that teachers make during a lesson.
Formulating clear, explicit learning goals sets the stage for everything else.
(Hiebert, Morris, Berk, & Janssen, 2007, p.57)

34. Goals to Focus Learning
Mr. Harris’ goal for students’ learning:
Students will extend their understanding of multiplication as equal groups to multiplying one-digit whole numbers by multiples of 10 using strategies based on place value and properties of operations.
Ms. Culver’s goal for students’ learning:
Students will understand that exponential functions grow by equal factors over equal intervals and that in the general equation y = bx, the exponent (x) tells you how many times to use the base (b) as a factor.
How does each goal align with this next teaching practice?

35. Implement Tasks that Promote Reasoning and Problem Solving
Mathematical tasks should:
Provide opportunities for students to engage in exploration or encourage students to use procedures in ways that are connected to concepts and understanding;
Build on students’ current understanding; and
Have multiple entry points.

36. Why Tasks Matter
Tasks form the basis for students’ opportunities to learn what mathematics is and how one does it;
Tasks influence learners by directing their attention to particular aspects of content and by specifying ways to process information;
The level and kind of thinking required by mathematical instructional tasks influences what students learn; and
Differences in the level and kind of thinking of tasks used by different teachers, schools, and districts, is a major source of inequity in students’ opportunities to learn mathematics.

37. Why Tasks Matter
Tasks form the basis for students’ opportunities to learn what mathematics is and how one does it;
Tasks influence learners by directing their attention to particular aspects of content and by specifying ways to process information;
The level and kind of thinking required by mathematical instructional tasks influences what students learn; and
Differences in the level and kind of thinking of tasks used by different teachers, schools, and districts, is a major source of inequity in students’ opportunities to learn mathematics.

38. Compare Band Concert and
Pay It Forward to:
Find the product
5 x 20 =
6 x 80 =
4 x 70 =
3 x 50 =
9 x 20 =
2 x 60 =
8 x 30 =
Petoskey Population
The population of Petoskey, Michigan, was 6076 in 1990 and was growing at the rate of 3.7% per years. The city planners want to know what the population will be in the year Write and evaluate an expression to estimate this population.
6076 (1.037)t
21,671
Algebra 2
Holt, Rinehart and Winston, 2004
Page 415

39. Higher-Level Tasks Doing mathematics Procedures with connections
Band Concert
Pay It Forward
Procedures with connections
Using a 10 x 10 grid, identify the decimal and percent equivalents of 3/5.
Explain how the graph of y = -3x² + 7 compares to the graph of y = x². Sketch the graph of y = -3x² + 7.
Smith & Stein, 1998

40. Lower-Level Tasks Memorization Procedures without connections
What are the decimal equivalents for the fractions ½ and ¼?
Procedures without connections
Convert the fraction 3/8 to a decimal.
A rectangular carpet is 12 feet long and 9 feet wide. What is the area of the carpet in square feet?
Smith & Stein, 1998

41. p. 5

42. Mathematical Representations
Use and Connect
Mathematical Representations
Different Representations should:
Be introduced, discussed, and connected;
Focus students’ attention on the structure or essential features of mathematical ideas; and
Support students’ ability to justify and explain their reasoning.
Strengthening the ability to move between and among these representations improves the growth of children’s concepts.
Lesh, Post, Behr, 1987

43. How might students benefit from connecting representations?

44. How might students benefit from connecting representations?

45. Meaningful Mathematical Discourse
Facilitate
Meaningful Mathematical Discourse
Mathematical Discourse should:
Build on and honor students’ thinking;
Provide students with the opportunity to share ideas, clarify understandings, and develop convincing arguments; and
Advance the mathematical learning of the whole class.

46. Meaningful Mathematical Discourse
Facilitate
Meaningful Mathematical Discourse
Discussions that focus on cognitively challenging mathematical tasks, namely those that promote thinking, reasoning, and problem solving, are a primary mechanism for promoting conceptual understanding of mathematics (Hatano & Inagaki, 1991; Michaels, O’Connor, & Resnick, 2008).
Smith, Hughes, Engle & Stein, 2009, p. 549

47. Meaningful Discourse
What did Mr. Harris and Ms. Culver do (before or during the discussion) that may have positioned him/her to engage students in a productive discussion?

48. p. 6

49. Five Practices for Orchestrating Productive Discussions
Anticipating likely student responses
Monitoring students’ actual responses
Selecting particular students to present their mathematical work during the whole class discussion
Sequencing the student responses
Connecting different students’ responses—to each other and to key mathematical ideas.
Smith & Stein, 2011

50. Planning with the Student in Mind
Anticipate solutions, thoughts, and responses that students might develop as they struggle with the problem
Generate questions that could be asked to promote student thinking during the lesson, and consider the kinds of guidance that could be given to students who showed one or another types of misconception in their thinking
Determine how to end the lesson so as to advance students’ understanding
Stigler & Hiebert, 1997

51. Pose Purposeful Questions
Effective Questions should:
Reveal students’ current understandings;
Encourage students to explain, elaborate, or clarify their thinking; and
Make the mathematics more visible and accessible for student examination and discussion.

52. Pose Purposeful Questions
Teachers’ questions are crucial in helping students make connections and learn important mathematics and science concepts. Teachers need to know how students typically think about particular concepts, how to determine what a particular student or group of students thinks about those ideas, and how to help students deepen their understanding.
Weiss & Pasley, 2004

53. Pose Purposeful Questions
How did you get that?
How do you know that?
Can you explain your idea?
Why?
Can you convince us?
Did anyone get something else?
Can someone tell me or share with me another way?
Do you think that means the same things?
Is there another opinion about this?
Why did you say that, Justin?
Boaler, J., & Brodie, K. (2004)

54. Build Procedural Fluency from Conceptual Understanding
Procedural Fluency should:
Build on a foundation of conceptual understanding;
Result in generalized methods for solving problems; and
Enable students to flexibly choose among methods to solve contextual and mathematical problems.

55. Build Procedural Fluency from Conceptual Understanding
Students must be able to do much more than carry out mathematical procedures. They must know which procedure is appropriate and most productive in a given situation, what a procedure accomplishes, and what kind of results to expect. Mechanical execution of procedures without understanding their mathematical basis often leads to bizarre results.
Martin, 2009, p. 165

56. p. 7

57. Support Productive Struggle in Learning Mathematics
Productive Struggle should:
Be considered essential to learning mathematics with understanding;
Develop students’ capacity to persevere in the face of challenge; and
Help students realize that they are capable of doing well in mathematics with effort.

58. Support Productive Struggle in Learning Mathematics
The struggle we have in mind comes from solving problems that are within reach and grappling with key mathematical ideas that are comprehendible but not yet well formed
Hiebert et al., 1996
By struggling with important mathematics we mean the opposite of simply being presented information to be memorized or being asked only to practice what has been demonstrated.
Hiebert & Grouws, 2007, pp
Not talking about giving students impossible problems to.
CLICK ON QUOTE
Students need to be able to figure things out for themselves…it is through this process of figuring things own that they will develop authority and ownership of their own learning.

59. Mathematics Teaching Practices
Effective
Mathematics Teaching Practices
Establish mathematics goals to focus learning.
Implement tasks that promote reasoning and problem solving.
Use and connect mathematical representations.
Facilitate meaningful mathematical discourse.
Pose purposeful questions.
Build procedural fluency from conceptual understanding.
Support productive struggle in learning mathematics.
Elicit and use evidence of student thinking.

60. Promoting Productive Struggle

61. Students’ Beliefs about Their Intelligence Affect Their Academic Achievement
Fixed mindset:
Avoid learning situations if they might make mistakes
Try to hide, rather than fix, mistakes or deficiencies
Decrease effort when confronted with challenge
Growth mindset:
Work to correct mistakes and deficiencies
View effort as positive; increase effort when challenged
Dweck, 2007

62. Students’ Beliefs about Their Intelligence Affect Their Academic Achievement
When confronted with challenging school transitions or courses, students with growth mindsets outperform those with fixed mindsets, even when they enter with equal skills and knowledge.
Dweck, 2007

63. Students Can Develop Growth Mindsets
Teacher praise influences mindsets
Fixed: Praise refers to intelligence
Growth: Praise refers to effort, engagement, perseverance
Explicit instruction about the brain, its function, and that intellectual development is the result of effort and learning has increased students’ achievement in middle school mathematics.
Reading stories of struggle by successful individuals can promote a growth mindset

64. “Effort Praise” Promotes Growth Mindsets
“You really studied for your English test, and your improvement shows it. You read the material over several times, outlined it, and tested yourself on it. That really worked!”
“I like the way you tried all kinds of strategies on that math problem until you finally got it.”
“It was a long, hard assignment, but you stuck to it and got it done. You stayed at your desk, kept up your concentration, and kept working. That's great!”
“I like that you took on that challenging project for your science class. It will take a lot of work—doing the research, designing the machine, buying the parts, and building it. You're going to learn a lot of great things.”
Dweck, 2007

65. “Effort Praise” Promotes Growth Mindsets
What about a student who gets an A without trying?
“All right, that was too easy for you. Let‘s do something more challenging that you can learn from.”
What about a student who works hard and doesn't do well?
“I liked the effort you put in. Let's work together some more and figure out what you don't understand.”
Dweck, 2007

66. Elicit and Use Evidence
of Student Thinking
Evidence should:
Provide a window into students’ thinking;
Help the teacher determine the extent to which students are reaching the math learning goals; and
Be used to make instructional decisions during the lesson and to prepare for subsequent lessons.

67. This cartoon illustrates what assessment is really about.
Each student develops some concept of mathematics is. Our jobs as teachers and administrators is to figure out what is going on in our students heads.
What do they really understand about mathematics? Unfortunately we can’t just open up the kid’s head and look.
We are restricted to look at visible and tangible evidence---what they say and do. In classrooms, we have a wide variety of evidence available for us.
At the district level, we are often stuck with what kids actually do, often on on-demand types of test.
A critical question is how good are our inferences? To what extent are we actually developing a accurate perception of what kids actually know?
This is what we are call valid inferences. We are making inferences of what children know when our idea of what they know matches, as well as possible, to what they actually understand. We never want to assume that they know something that they don’t, and we also don’t want to assume that they don’t know something that they do.
Harold Asturias, 1996

68. Formative assessment is an essentially interactive process, in which the teacher can find out whether what has been taught has been learned, and if not, to do something about it. Day-to-day formative assessment is one of the most powerful ways of improving learning in the mathematics classroom.
Wiliam, 2007, pp. 1054; 1091

69. Elicit and Use Evidence of Student Thinking
Identify specific places during the lesson (cite line numbers) in which Mr. Harris or Ms. Culver elicited evidence of student learning.
Discuss how he or she used or might use that evidence to adjust his/her instruction to support and extend student learning.

70. Mathematics Teaching Practices
Effective
Mathematics Teaching Practices
Establish mathematics goals to focus learning.
Implement tasks that promote reasoning and problem solving.
Use and connect mathematical representations.
Facilitate meaningful mathematical discourse.
Pose purposeful questions.
Build procedural fluency from conceptual understanding.
Support productive struggle in learning mathematics.
Elicit and use evidence of student thinking.

71. “If your students are going home at the end of the day less tired than you are, the division of labor in your classroom requires some attention.”
Wiliam, D. (2011)

72. Your Feelings Looking Ahead?
Andy Isaacs, 2010

74. for School Mathematics
Guiding Principles
for School Mathematics
Teaching and Learning
Access and Equity
Curriculum
Tools and Technology
Assessment
Professionalism
Essential Elements
of Effective Math
Programs

75. Guiding Principles for School Mathematics
Professionalism
In an excellent mathematics program, educators hold themselves and their colleagues accountable for the mathematical success of every student and for their personal and collective professional growth toward effective teaching and learning of mathematics.  

76. Guiding Principles for School Mathematics
Professionalism
In an excellent mathematics program, educators hold themselves and their colleagues accountable for the mathematical success of every student and for their personal and collective professional growth toward effective teaching and learning of mathematics.  

77. Professionalism Obstacle
In too many schools, professional isolation severely undermines attempts to significantly increase professional collaboration … some teachers actually embrace the norms of isolation and autonomy. A danger in isolation is that it can lead to teachers developing inconsistencies in their practice that in turn can create inequities in student learning.
Principles to Actions, p. 100

78. Collaboration Team Work
An examination and prioritization of the mathematics content and mathematics practices students are to learn.
The development and use of common assessments to determine if students have learned the agreed-on content and related mathematical practices.
The use of data to drive continuous reflection and instructional decisions.
The setting of both long-term and short-term instructional goals.
Development of action plans to implement when students demonstrate they have or have not attained the standards.
Discussion, selection, and implementation of common research-informed instructional strategies and plans.
Principles to Actions, pp

79. for School Mathematics
Guiding Principles
for School Mathematics
Teaching and Learning
Access and Equity
Curriculum
Tools and Technology
Assessment
Professionalism
Essential Elements
of Effective Math
Programs

80. The Title is Principles to Actions
The Teaching and Learning Principle
Teacher Actions:
Consistently implement the eight Mathematics Teaching Practices.
Elicit, value, and celebrate varied approaches and solution paths that students take to solve mathematics problems, explain their thinking, and critique the arguments of others.

81. The Title is Principles to Actions
The Teaching and Learning Principle
Teacher Actions:
Give priority to the mathematical practices, including problem solving, reasoning, and constructing viable arguments in every aspect of classroom practice—including teaching, assessment, curriculum decisions, and the use of tools and technology.
Plan and implement units and lessons that promote positive dispositions toward the study of mathematics, including curiosity, self-confidence, flexibility, and perseverance.

82. The Title is Principles to Actions
The Teaching and Learning Principle
Principals, Coaches, Specialists, and Other School Leaders Actions:
Make the eight Mathematics Teaching Practices a school-wide focus that is expected for all teachers to strengthen learning and teaching for all students.
Provide professional development and training that makes the implementation of the Mathematics Teaching Practices a priority.
Observe lessons or engage in classroom walkthroughs, using the Mathematics Teaching Practices as the focus.

83. The Title is Principles to Actions
The Teaching and Learning Principle
Leaders and Policymakers in All Districts and States or Provinces Actions:
Make ongoing professional development that supports the implementation of the eight Mathematics Teaching Practices a priority.
Communicate the value of the Mathematics Teaching Practices to parents and the community and all educational stakeholders.
Align accountability measures for teachers and principals with the Mathematics Teaching Practices.

86. Reflection Guide

88. The Title Is Principles to Actions
Your Actions?

89. Diane Briars dbriars@nctm.org
Thank You!
Diane Briars