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Inquiry In Instruction [I 3 ] HS-MASS III

Inquiry In Instruction [I 3 ] HS-MASS III. Michigan Mathematics & Science Center Network. History of HS-MASS High School Mathematics and Science Success. HS-MASS I 2006 – 2007 High School Content Expectations Michigan Merit Examination

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Inquiry In Instruction [I 3 ] HS-MASS III

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  1. Inquiry In Instruction [I3] HS-MASS III Michigan Mathematics & Science Center Network

  2. History of HS-MASSHigh School Mathematics and Science Success HS-MASS I 2006 – 2007 High School Content Expectations Michigan Merit Examination Teaching Strategies for Charts, Tables, and Graphs HS-MASS II 2007 – 2008 High School Clarification Documents Formative and Summative Assessment The Language of Mathematics (Vocabulary) HS-MASS III (I3) 2009 Inquiry In Instruction Creating a Classroom Culture of Inquiry Designing Mathematical Lessons to Foster Inquiry

  3. What has changed since HS-MASS I? 1. High School Content Expectations • First rolled out in 8/06, changes occurred & new version presented in11/07 • Clarification Documents: www.mi-math-companion.wikispaces.com 2. MME • Assessment Design • Contributing Components • AYP Targets • Pre & Post MME Algebra II HSCEs

  4. Inquiry In InstructionOutcomes • Identify key elements of an inquiry based approach to teaching. • Change current practices to become more inquiry based in nature. • Develop lessons and investigations that exemplify the key elements of inquiry instruction. • Implement knowledge and pedagogical skills related to formative assessment to support inquiry learning.

  5. Inquiry In Instruction Requirements of participants • Mathematics & Science teachers: 8 - 12 • Complete pre & post teacher survey • Develop lessons to be taught to at least one math class • Administer pre & post student assessment • Complete a questionnaire • Attend all I3 sessions

  6. Goals, Activities & Timeline Day 1 (2/18) Goal: Develop an understanding of math inquiry and how it looks in the classroom. Identify at least one target math lesson. Day 2 (3/3) Goal: Deepen the understanding of math inquiry. Develop one inquiry-based lesson to be implemented in at least one math class. Complete the lesson-design template to be shared with your colleagues. Day 3 (Evening Session – 4/22) Goal: Reflect upon the complexities of inquiry-based teaching and learning.

  7. Inquiry In Instruction (I³) Teacher Pre-Survey Student Packet - SAMPI Handouts-

  8. Inquiry in Instruction (I3) Growing the Innovators of Tomorrow: Michigan Students’ Thoughts on Learning Mathematics Melendy Lovett Educational & Productivity Solutions Texas Instruments Incorporated MCTM Luncheon Address October 15, 2005 - Video Clip - 8

  9. Inquiry In Instruction (I3) • What is Inquiry in Instruction ? • What does it look like in mathematics? • Where do I stand in the process? • How can I change my classroom practices?

  10. Describe or Define (in your own words): Facts/Characteristics: Non-Examples: Examples: Using the Frayer Model to Represent Inquiry • Complete with a partner • You will be revisiting/revising as needed Inquiry

  11. Inquiry Consensograph • Determine your “level” of understanding using information below: 1 – Have little understanding of Inquiry in Math instruction 2 – Understand Inquiry in Math instruction but not implemented in classroom. 3 – Have used inquiry in Math instruction 4 – Inquiry in Math instruction is regularly used in my classroom. • Place your level (using numbers 1 – 4) on a post-it • Place post-it on blank chart paper on the wall

  12. Introduction to Inquiry

  13. Engage Evaluate Explore Elaborate Explain The 5E Learning Cycle Learning involves making sense of 1) prior experiences, and 2) new first-hand explorations.

  14. Essential Components of Inquiry (5E Model) • Engage • Stimulate student thinking to access prior knowledge • Explore • Students scaffold new knowledge, investigate, and organize • Explain • Students analyze their data • Students support ideas with evidence • Elaborate or Extend • Students draw conclusions based on information they acquire • Evaluate • Students defend their conclusions • Students dialogue with other students and the teacher in learning

  15. The 5-E Learning Cycle: Match the Student Activity with the 5-E Stage: • Engage • Explore • Explain • Elaborate and • Evaluate ___ Student demonstrates an understanding of the concept or skill. ___ Student shows interest in the topic. ___ Student applies explanations and skills to a new but similar situation. ___ Student listens critically as other students explain their answers or solutions. ___ Student records observations and ideas.

  16. The 5-E Learning Cycle: Match the Student Activity with the 5-E Stage: • Engage • Explore • Explain • Elaborate and • Evaluate _E_ Student demonstrates an understanding of the concept or skill. _A_ Student shows interest in the topic. _D_ Student applies explanations and skills to a new but similar situation. _C_ Student listens critically as other students explain their answers or solutions. _B_ Student records observations and ideas.

  17. The 5-E Learning Cycle: Match the Teacher Activity with the 5-E Stage: • Engage • Explore • Explain • Elaborate and • Evaluate ___ Teacher creates interest and generates curiosity. ___ Teacher expects students to use formal definitions and explanations provided previously. ___ Teacher asks students for justification (evidence) and clarification. ___ Teacher redirects students’ investigations by asking probing questions. ___ Teacher allows students to assess their own learning.

  18. The 5-E Learning Cycle: Match the Teacher Activity with the 5-E Stage: • Engage • Explore • Explain • Elaborate and • Evaluate _A_ Teacher creates interest and generates curiosity. _D_ Teacher expects students to use formal definitions and explanations provided previously. _C_ Teacher asks students for justification (evidence) and clarification. _B_ Teacher redirects students’ investigations by asking probing questions. _E_ Teacher allows students to assess their own learning.

  19. The 5-E Learning Cycle: Are the following examples of student behaviors … “C” Consistent with the 5-E Instructional Model, or “I” Inconsistent with the 5-E Instructional Model: ____ Student asks, “Is this the ‘right’ answer?” ____ Student works with little or no interaction with others. ____ Student discusses alternatives with others. ____ Student draws conclusions from “thin air,” i.e. ignores previous information. ____ Student accepts explanations without justification. ____ Student answers open-ended questions using evidence and previously accepted explanations. ____ Student uses previously-recorded observations in explanations. ____ Student asks “Why did this happen?” ____ Student offers only memorized definitions or explanations. ____ Student uses previous information to ask questions and propose solutions. ____ Student seeks and offers no more than one solution to a problem.

  20. The 5-E Learning Cycle: Are the following examples of student behaviors … “C” Consistent with the 5-E Instructional Model, or “I” Inconsistent with the 5-E Instructional Model: _I__ Student asks, “Is this the ‘right’ answer?” _I__ Student works with little or no interaction with others. _C_ Student discusses alternatives with others. _I__ Student draws conclusions from “thin air,” i.e. ignores previous information. _I__ Student accepts explanations without justification. _C_ Student answers open-ended questions using evidence and previously accepted explanations. _C_ Student uses previously-recorded observations in explanations. _C_ Student asks “Why did this happen?” _I__ Student offers only memorized definitions or explanations. _C_ Student uses previous information to ask questions and propose solutions. _I__ Student seeks and offers no more than one solution to a problem.

  21. The 5-E Learning Cycle: Are the following examples of teacher behaviors … “C” Consistent with the 5-E Instructional Model, or “I” Inconsistent with the 5-E Instructional Model: _____ Teacher provides premature answers to students’ questions and states conclusions. _____ Teacher encourages students to explain concepts in their own words. _____ Teacher leads students step-by-step to a solution. _____ Teacher acts as a “consultant” for students. _____ Teacher generates interest and curiosity, and raises questions. _____ Teacher does not solicit students’ explanations. _____ Teacher asks open-ended questions such as “What evidence do you have?” _____ Teacher lectures. _____ Teacher refers students to existing evidence and asks “What do you already know?” _____ Teacher tests vocabulary words and isolated facts. _____ Teacher reminds students of alternate explanations.

  22. The 5-E Learning Cycle: Are the following examples of teacher behaviors … “C” Consistent with the 5-E Instructional Model, or “I” Inconsistent with the 5-E Instructional Model: __I__ Teacher provides premature answers to students’ questions and states conclusions. __C_ Teacher encourages students to explain concepts in their own words. __I__ Teacher leads students step-by-step to a solution. __C_ Teacher acts as a “consultant” for students. __C_ Teacher generates interest and curiosity, and raises questions. __I__ Teacher does not solicit students’ explanations. __C_ Teacher asks open-ended questions such as “What evidence do you have?” __I__ Teacher lectures. __C_ Teacher refers students to existing evidence and asks “What do you already know?” __I__ Teacher tests vocabulary words and isolated facts. __C_ Teacher reminds students of alternate explanations.

  23. Essential Components of Mathematical Inquiry • Conjecturing • Students are presented with a problem and make predictions • Constructivism • Students scaffold new mathematical knowledge • Connections • Students make connections to prior knowledge • Students make connections to various mathematical principles • Conclusions • Students draw conclusions based on information they acquire • Communication • Students defend their conclusions • Students dialogue with other students and the teacher in learning 23

  24. Simplified Inquiry Model • Starts with a question • Involves an investigation • Results shared

  25. Another Model • Ask • Investigate • Create • Discuss • Reflect

  26. Inquiry Lesson Cycle • Introduce Lesson • Build the Foundation • Conduct Exploration • Analyze Data • Justify Conjectures/Solutions • Present Findings/Summarize Understandings Connect to Next Lesson

  27. Inquiry : “Families of Functions” Creating a Poster Your poster will include: • Your name • The equation • Word description of your equation • Table of values • Graph of your function • List of anything you notice

  28. Mathematics Inquiry : “Finding Proof” Case Study in a Geometry Classroom - Annenberg Video - www.learner.org

  29. Finding ProofSome Considerations • How does this approach to finding proof compare with traditional methods? • Value of extending a problem over several days? • Consider use of history in the study of mathematics. - Discuss with your group -

  30. Reminders for next session 1. Give the student pre-test. 2. Bring in the completed student pre-test. 3. Come with a lesson that you will modify at the next session.

  31. 3 – 2 – 1 Out On an index card from one of the boxes, please write down: 3 Things you learned today 2 Formative assessments used today 1 Question/Comment you have Please place the card on the table as you leave… Thank you!

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