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Using Visualization to Develop Children's Number Sense and Problem Solving Skills in Grades K-3 Mathematics (Part 2) . LouAnn Lovin, Ph.D. Mathematics Education James Madison University. The Cookie Problem.
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Using Visualization to Develop Children's Number Sense andProblem Solving Skills in Grades K-3 Mathematics (Part 2) LouAnn Lovin, Ph.D. Mathematics Education James Madison University
The Cookie Problem Kevin ate half a bunch of cookies. Sara ate one-third of what was left. Then Natalie ate one-fourth of what was left. Then Katie ate one cookie. Two cookies were left. How many cookies were there to begin with? Lovin NESA Spring 2012
Different visual depictions of problem solutions for the Cookie Problem: Sara Sol 1 Kevin Natalie Katie Sol 2 Sol 3 2 Katie Natalie Sara Kevin Lovin NESA Spring 2012
Visual and Graphic Depictions of Problems Research suggests….. It is not whether teachers use visual/graphic depictions, it is how they are using them that makes a difference in students’ understanding. • Students using their own graphic depictions and receiving feedback/guidance from the teacher (during class and on mathematical write ups) • Discussions about why particular representations might be more beneficial to help think through a given problem or communicate ideas. • Graphic depictions of multiple problems and multiple solutions. (Gersten & Clarke, NCTM Research Brief) Lovin NESA Spring 2012
Supporting Students • Discuss the differences between pictures and diagrams. • Ask students to • Explain how the diagram represents various components of the problem. • Emphasize the the importance of precision in the diagram. • Discuss their diagrams with one another to highlight the similarities and differences in various diagrams that may represent the same problem. • Discuss which diagrams are most appropriate for particular kinds of problems. Katie Natalie Sara Kevin Lovin NESA Spring 2012
A Student’s Guide to Problem Solving Lovin NESA Spring 2012
Summary of A Common “Approach” for Learners to Solve Word Problems Randomly combine numbers without trying to make sense of the problem. Lovin NESA Spring 2012
Key Words • This strategy is useful as a rough guide but limited because key words don't help students understand the problem situation (i.e. what is happening in the problem). • Key words can also be misleading because the same word may mean different things in different situations. • There are 7 boys and 21 girls in a class. How many more girls than boys are there? • Wendy has 3 cards. Her friend gives her 8 more cards. How many cards does Wendy have now? Lovin NESA Spring 2012
Real problems do not have key words! Lovin NESA Spring 2012
Teaching Mathematical Concepts and Skills through Word Problems Contextual (Word) Problems • Introduce procedures and concepts using contextual problems (e.g., subtraction; multiplication). • Makes learning more concrete by presenting abstract ideas in a familiar context. • AVOIDs the sole reliance on key words. Lovin NESA Spring 2012
Visual and Graphic Depictions of Word Problems Quantitative Analysis Visual models (like Singapore Math, VandeWalle) • Helps children to get past the words by visualizing and illustrating word problems with simple diagrams. • Emphasis is on modeling the quantities and their relationships. • Difference between pictures and diagrams. Lovin NESA Spring 2012
Visual and Graphic Depictions of Problems Ben has 5 cats and his cousin, Jerry, has 3 cats. How many cats do they have together? How would you write this computation as an equation? Jerry 3 5 Ben Jerry has 3 cats. Ben has 5 more cats than his cousin Jerry. How many cats does Ben have? Lovin NESA Spring 2012
Visual and Graphic Depictions of Problems Jerry has 3 cats. Ben has 5 more cats than his cousin Jerry. How many cats does Ben have? 8 Ben 5 Jerry 3 How would you write this computation as an equation? Lovin NESA Spring 2012
Visual and Graphic Depictions of Problems Meilinsaved $184. She saved $63 more than Betty. How much did Betty save? How would you write this computation? (Primary Mathematics volume 3A, page 21, problem 7.) $184 Meilin Betty ? $63 Lovin NESA Spring 2012
Solve these problems: • Jacob had 8 cookies. He ate 3 of them. How many cookies does he have now? • Jacob has 3 dollars to buy cookies. How many more dollars does he need to earn to have 8 dollars? • Nathan has 3 dollars. Jacob has 8 dollars. How many more dollars does Jacob have than Nathan? How did you find your answer?
Perspectives Most adults think 8 – 3 = 5, because it’s the most efficient way to solve these tasks. Young children see these as 3 different problems and use the action or situation in the problem to solve it – so they solve each of these using different strategies. (Unfortunately, too often children are told to subtract – because that’s how we interpret the problem.)
A first grader… • Jacob has 8 cookies. He ate 3 of them. How many cookies does he have now? • Jacob has 3 dollars. How many more dollars does he need to earn to have 8 dollars? • Nathan has 3 dollars. Jacob has 8 dollars. How many more dollars does Jacob have than Nathan? X X X 1 2 3 4 5 1 2 3 4 1 2 5 6 3 4 7 5 8 1 2 3 4 5
Rekenrek While students can use the rekrenrek to generate different strategies for solving basic facts, they can also use it to solve story problems such as the ones below. Visualization is key to helping find a solution. Together, Claudia and Robert have 7 apples. Claudia has one more apple than Robert. How many apples do Claudia and Robert have? Claudia had 4 apples. Robert gave her some more. Now she has 7 apples. How many did Robert give her? Lovin NESA Spring 2012
Town Sports ordered 99 scooters. They have received 45 scooters. How many scooters is Town Sports waiting on? 45 ? 99 99 – 45 = ______ OR 45 + ____ = 99 Lovin NESA Spring 2012
Taiwan’s Cookie Problem Joining Physical Action Separate Part-part Whole No Physical Action Comparing Lovin NESA Spring 2012
Start Unknowns Bear Dog had some cookies. Taiwan gave him 8 more cookies. Then he had 13 cookies. How many cookies did Bear Dog have before Taiwan gave him any? ? 8 13 Lovin NESA Spring 2012
Multiplication A typical approach is to use arrays or the area model to represent multiplication. Why? 4 3×4=12 3 Lovin NESA Spring 2012
Use Real Contexts – Grocery Store (Multiplication) Lovin NESA Spring 2012
MultiplicationContext – Grocery Store How many plums does the grocer have on display? plums Lovin NESA Spring 2012
Multiplication - Context – Grocery Store apples lemons Groups of 5 or less subtly suggest skip counting (subitizing). tomatoes Lovin NESA Spring 2012
How many muffins does the baker have? Lovin NESA Spring 2012
Other questions • How many muffins did the baker have when all the trays were filled? • How many muffins has the baker sold? • What relationships can you see between the different trays? Lovin NESA Spring 2012
Video:Students Using Baker’s Tray (4:30) • What are the strategies and big ideas they are using and/or developing • How does the context and visual support the students’ mathematical work? • How does the teacher highlight students’ significant ideas? Video 1.1.3 from Landscape of Learning Multiplication mini-lessons (grades 3-5) Lovin NESA Spring 2012
Students’ Work Jackie Edward Lovin NESA Spring 2012
Students’ Work Sam Wendy Amanda Lovin NESA Spring 2012
Area ModelGrid Paper • Show a 2 x 3 rectangle • Show a 4 x 5 rectangle Lovin NESA Spring 2012
Open Array 12 5 Lovin NESA Spring 2012
Area/Array ModelProgression Area model using grid paper Open array Context (muffin tray, sheet of stamps, fruit tray) Lovin NESA Spring 2012
2 x 30 How do you think about determining what 2 x 30 is? What do we mean by “adding a zero”? Video 1 (:19) (1.1.5) and Video 2 (3:59) (1.1.6) Multiplication mini-lessons Lovin NESA Spring 2012
Take a minute and write down two things you are thinking about from this morning’s session. • Share with a neighbor. Lovin NESA Spring 2012
Take Aways • Help children create diagrams to represent the quantities and their relationships in problems. • Children can solve the same problem using different operations. • Take advantage of children’s tendencies to subitize (rekenreks and arrays) • Use real world contexts to introduce arrays (multiplication) Lovin NESA Spring 2012
Do you see what I see? An old man’s face or two lovers kissing? Cat or mouse? Not everyone sees what you may see. Lovin NESA Spring 2012
References • Carpenter, Fennema, Franke, Levi, Empson. (1999). Children’s Mathematics: Cognitively Guided Instruction. Heinemann: Portsmouth, NH. • Diesmann, C., & English, L. (2001). Promoting the use of diagrams as tools for thinking. In A. Cuoco & F. Curcio (Eds.), The Roles of Representation in School Mathematics, pp. 77-89. Reston, VA: NCTM. • Dolk, M., Liu, N., & Fosnot, C. (2008). The Double-Decker Bus: Early Addition and Subtraction. Portsmouth, NH: Heinemann. • Fosnot, C. & Dolk, M. (2001). Young Mathematicians at Work: Constructing Number Sense, Addition, and Subtraction. Portsmouth, NH: Heinneman. • Fosnot, C. (2008). Bunk Beds and Apple Boxes: Early Number Sense. Portsmouth, NH: Heinemann. • Fostnot, C. & Cameron, A. (2007). Games for Early Number Sense. Portsmouth, NH: Heinneman. • Gersten, R. & Clarke, B. (2007). Research Brief: Effective Strategies for Teaching Students with Difficulties in Mathematics. NCTM: Reston, VA. • Ministry of Education Singapore. (2009). The Singapore Model Method. Panpac Education: Singapore. • NCTM (2000). Principles and Standards of School Mathematics. NCTM: Reston, VA. • Parrish, S. (2010). Number Talks: Helping Children Build Mental Math and Computation Strategies. Math Solutions: Sausalito, CA. • Storeygard, J. (2009). My Kids Can: Making Math Accessible to All Learners. Heinemann: Portsmouth, NH. • Wright, R., Martland. J, Stafford, A., & Stanger, G. (2006). Teaching Number: Advancing Children’s Skills and Strategies. London: Sage. • Using the Rekenrek as a Visual Model for Strategic Reasoning in Mathematics by Barbara Blanke (www.mathlearningcenter.org/media/Rekenrek_0308.pdf) • VandeWalle, J. & Lovin, L. (2005). Teaching Student-Centered Mathematics: Grades K-3. Boston:Pearson. Lovin NESA Spring 2012
Cognitively Guided InstructionStrategies • Direct Modeling Strategies • Counting Strategies • Derived Number Facts • Known Number Facts (as in recall) return Lovin NESA Spring 2012