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Common Core High School Mathematics: Transforming Instructional Practice for a New Era. School Year Session 11: March 5, 2014 Similarity: Is it just “Same Shape, Different Size”?. 1. 1. Agenda. Similarity Transformations Circle similarity Break Engage NY assessment redux Planning time
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Common Core High School Mathematics:Transforming Instructional Practice for a New Era School Year Session 11: March 5, 2014 Similarity: Is it just “Same Shape, Different Size”? 1.1
Agenda • Similarity Transformations • Circle similarity • Break • Engage NY assessment redux • Planning time • Homework and closing remarks 1.2
Learning Intentions & Success Criteria Learning Intentions: We are learning similarity transformations as described in the CCSSM Success Criteria: We will be successful when we can use the CCSSM definition of similarity, and the definition of a parabola, to prove that all parabolas are similar
The Big Picture • Select a focus unit • Specify a set of learning intentions • Design or modify an assessment • Design a task for a focus lesson(s) within the unit • Teach the unit & lesson and collect evidence • Plan, Teach, Reflect project with lesson & assessment evidence • An approximate timeline January 22 February 19 March 5 March 5-19 By April 5 May 7 1.4
Someone in your group has recent experience • Do not “bonk with the big blocks” 1.5
Introducing Similarity Transformations Activity 1: • With a partner, discuss your definition of a dilation. 1.6
Introducing Similarity Transformations Activity 1: • (From the CCSSM glossary) A dilation is a transformation that moves each point along the ray through the point emanating from a common center, and multiplies distances from the center by a common scale factor. Figure source: http://www.regentsprep.org/Regents/math/geometry/GT3/Ldilate2.htm 1.7
Introducing Similarity Transformations Activity 1: (From the CCSSM Geometry overview) • Two geometric figures are defined to be congruent if there is a sequence of rigid motions (translations, rotations, reflections, and combinations of these) that carries one onto the other. • Two geometric figures are defined to be similar if there is a sequence of similarity transformations (rigid motions followed by dilations) that carries one onto the other. 1.8
Introducing Similarity Transformations Activity 1: • Read G-SRT.1 • Discuss how might you have students meet this standard in your classroom? 1.9
Circle Similarity Activity 2: • Consider G-C.1: Prove that all circles are similar. • Discuss how might you have students meet this standard in your classroom? 1.10
Circle Similarity Activity 2: Begin with congruence • On patty paper, draw two circles that you believe to be congruent. • Find a rigid motion (or a sequence of rigid motions) that carries one of your circles onto the other. • How do you know your rigid motion works? • Can you find a second rigid motion that carries one circle onto the other? If so, how many can you find? 1.11
Circle Similarity Activity 2: Congruence with coordinates • On grid paper, draw coordinate axes and sketch the two circles x2 + (y – 3)2 = 4 (x – 2)2 + (y + 1)2 = 4 • Why are these the equations of circles? • Why should these circles be congruent? • How can you show algebraically that there is a translation that carries one of these circles onto the other? 1.12
Circle Similarity Activity 2: Turning to similarity • On a piece of paper, draw two circles that are not congruent. • How can you show that your circles are similar? 1.13
Circle Similarity Activity 2: Similarity with coordinates • On grid paper, draw coordinate axes and sketch the two circles x2 + y2 = 4 x2 + y2 = 16 • How can you show algebraically that there is a dilation that carries one of these circles onto the other? 1.14
Circle Similarity Activity 2: Similarity with a single dilation? • If two circles are congruent, this can be shown with a single translation. • If two circles are not congruent, we have seen we can show they are similar with a sequence of translations and a dilation. • Are the separate translations necessary, or can we always find a single dilation that will carry one circle onto the other? • If so, how would we locate the centre of the dilation? 1.15
Engage NY Redux Activity 3: • Last time, we left unanswered the question: • “Is the parabola with focus point (1,1) and directrixy = -3 similar to the parabola y = x2?” • Answer this question, using the CCSSM definition of similarity. 1.17
Engage NY Redux Activity 3: • Are any two parabolas similar? • What about ellipses? Hyperbolas? 1.18
Learning Intentions & Success Criteria Learning Intentions: We are learning similarity transformations as described in the CCSSM Success Criteria: We will be successful when we can use the CCSSM definition of similarity, and the definition of a parabola, to prove that all parabolas are similar
Planning Time Activity 4: • Find someone who is teaching similar content to you, and work as a pair. • Think about the unit you are teaching, and identify one key content idea that you are building, or will build, the unit around. • Identify a candidate task that you might use to address your key idea, and discuss how that task is aligned to the frameworks (cognitive demand/SBAC claims) we have seen in class. • We will ask you to share out at 7:45. 1.20
Homework & Closing Remarks Activity 5: • Homework: • Prepare to hand in your assessment and task modification homework on March 19. You should include both the original and the modified versions of both tasks (the end-of-unit assessment and the classroom task), your assessment rubric, and your reflections on the process and the results. • Begin planning your selected lessons. You will have time to discuss your ideas with your colleagues in class on March 19. • Bring your lesson and assessment materials to class on March 19. 1.21