Longwood University Professional Development Seminar Algebra, Number Sense, and Mathematical Connections in Grades 3-5
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Longwood University Professional Development Seminar Algebra, Number Sense, and Mathematical Connections in Grades 3-5 Blanton, Maria, et. al. Developing Essential Jacob, Bill, and Catherine Twomey Fosnot. Understanding of Algebraic Thinking: Grades 3-5. Reston, Va.: NCTM, 2011 The California Frog-Jumping Contest: Algebra. Portsmouth, NH: Heinemann, 2007 Russell, Susan Jo, Deborah Schifter, & Virginia Bastable. Connecting Arithmetic to Algebra. Portsmouth, NH: Heinemann, 2011 Cuevas, Gilbert and Karol Yeatts. Navigating through Algebra in Grades 3-5. Reston, VA: NCTM, 2001 Wickett, Maryann, et. al. Lessons for Algebraic Thinking: Grades 3-5. Sausalito, CA: Math Solutions, 2002 Von Rotz, Leyani and Marilyn Burns. Lessons for Algebraic Thinking: Grades K-2. Sausalito, CA: Math Solutions, 2002 Bamberger, Honi J. and Christine Oberdorf. 2010 Collins, Anne and Linda Dacey. Xs and Whys Activities to Undo Math Misconceptions, Grades 3-5. Portsmouth, NH: Heineman, of Algebra: Key Ideas and Common Misconceptions. Portland, ME: Stenhouse, 2011 Mirra, Amy. Focus in Grades 3-5: Teaching with Curriculum Focal Points. Reston, VA: NCTM, 2008 Subtraction problems that help students think about what happens when they add two odd numbers. There is no other decision that teachers make that has a greater impact on students’ opportunity to learn and their perceptions about what mathematics is than the selection or creation of the tasks with which the teacher engages students in studying mathematics. ---Glenda Lappan & Diane Briars, 1995 1. 2. 3. Conceptual Phase ◦ Explores topic with concrete models; ◦ Invents own strategies and solutions. Connecting Phase ◦ Builds relationships between language, concrete models, and written symbols and procedures. Symbolic Phase ◦ Understands the connections between a procedure and underlying rationale. ---Baroody, A.J. with Coslick, R.T. (1998), Fostering Children’s Mathematical Power: An Investigative Approach to K-8 Mathematics Instruction, p. 3-8. A mathematical statement that uses an equal sign to show that two quantities are equivalent is called an equation. ---Blanton, et al., 2011, p. 25. What number might your students place in the box when asked to solve the following task? 9+3=+4 The equals sign is a symbol that represents a relationship of equivalence. --Blanton et al., 2011, p. 25. “The repetitive use of arithmetic tasks where children compute an expression then write their answers immediately after the = symbol can build a misconception in their thinking about what equality means. Many children fail to see the algebraic role of = as signaling a relationship between quantities, such as 9 + 3 is equivalent to, or the same as + 4” (p. 23). --Blanton, 2008. Many students marked these equations as incorrect. Can you guess why? 7 = 5 + 2 7 = 7 4 + 6 = 3 + 7 When asking students to find a sum, instead of having them express the sum as one number, ask them to express it as the sum of two other numbers. 25 + 37 = + Make a matching game for students to form equations with equivalent expressions Make a concentration game with equivalent expressions Is This True? (Bamberger & Oberdorf, 2010, p. 51) Find as many ways as you can to partition the set of diamonds and record each pattern using an equation. For example, 4 + 4 + 4 + 4 + 9 = 25 What is the value of the left side of your equation? What is the value of the right side of your equation? How do you know that you have written a correct equation? Cuevas & Yeatts, 2001, pp. 48-50 Examine your patterns and the patterns of your partner and identify two equations that demonstrate a particular property. On your paper write each of your original equations. Then write a new equation which combines the two equations and demonstrates the property. Which property does your new equation demonstrate? How do you know? Under your new equation include the drawings you partitioned that match with each side of your new equation. Explain how you know your new equation is true. “Two quantities can relate to each other in one of three ways: ◦ (1) they can be equal, ◦ (2) one quantity can be larger than the other , or ◦ (3) one quantity can be smaller than the other” (p. 39). --Blanton et al., 2011 < and >, = and ≠ Greater than, less than, equal to and not equal to You and your partner each grab two handfuls of cubes. When you grab your cubes put each handful on a separate plate. Record the number of cubes in each handful. Von Rotz & Burns, 2002 pp. 138-156 Each partner then writes an expression for the number of cubes they grabbed. ◦ (For example: 15 + 22, if you grabbed 15 cubes and then 22 cubes) Write an appropriate equation or inequality that represents the relationship between the number of cubes you grabbed and the number your partner grabbed. (e.g., 15+22 >13 + 21) How do you know your equation or inequality is true? Can you explain without calculating the total number of cubes each of you grabbed? Can you write another equation or inequality that also represents the relationship between the number of cubes you grabbed and the number your partner grabbed. How do you know this equation or inequality is true? Equations can be used to represent problem situations. --Blanton et al., 2011, p. 30. “Using equations to reason about, represent, and communicate relationships between quantities is a cornerstone of algebra” (p. 25). “Writing equations that represent the situation in arithmetic problems builds a foundation for writing equations in algebra” (p. 31). ---Blanton, et al., 2011 Write a story context for 27 + 39. How does your story illustrate the meaning of addition? Solve your story in 2 different ways: use manipulatives, drawings, mental math, open number lines, and equations. Share and discuss your work with a partner. How can the story explain why 27 + 39 = 26 + 40? Justify how this equation represents a relationship of equivalence. Share and discuss your work with a partner. Write a story to model 54 – 18. How can the story explain why 54 – 18 = 56 – 20? Solve your story in 2 different ways: use manipulatives, drawings, mental math, open number lines, and equations. Number line representations for 54 – 18. 36 18 36 54 18 54 Equations can be reasoned about in their entirety rather than as a series of computations to execute. --Blanton et al., 2011, p. 26. Task: Make a conjecture Are these number sentences true? 2+5=3+4 19 + 6 = 20 + 5 How do you know they are equal? 27 + 34 and 30 + 31 2+5=3+4 19 + 6 = 20 + 5 If you add an amount to one number and subtract it from the other, the total doesn’t change. If you add an amount to one addend and subtract it from the other, the sum remains the same. If a + b = c, then (a + n) + (b – n) = c (a + n) + (b – n) = (a + b) Now try the same generalization with subtraction 9-3 = 8-4 Why doesn’t this work? Create a few more examples. Use one of the representations (drawings, cubes, or number lines) to talk about the conjecture in general; that is, use the representation, but do not use the numbers in the specific instances. Here are a few ways to express the conjecture: 1. If you take away more, you end up with less. 2. If you increase the second number in a subtraction expression, you decrease the difference by the same amount. 3. If (a – b) = c, then a – (b + n) = c – n 1. 2. 3. Use a specific problem and informal reasoning using the context of the problem. Make a general statement or conjecture. Use formal algebraic notation – variables and equations. ---Blanton, et al., 2011, p. 18 “There is much, much more to the development of the ability to solve equations than moving up step by step” --- Fosnot & Jacob, 2010, p. 94. Nonstandard strategies for solving equations are “ particularly relevant to algebra in grades 3-5 because they allow students to reason intuitively about an equation in its entirety” ---Blanton, et al., 2011, p. 28 Video link Providing Create regular routines to set up habits for math explanations. variations within routines to highlight various aspects of a claim or to call attention to an unstated assumption. Giving students multiple opportunities to clarify for themselves the ideas they are working to express. Encouraging representations such as cubes, diagrams, drawings, and story contexts to provide tools for expressing ideas. (continued…) Insisting Giving students explain what they mean by ‘it’ or ‘this.’ many students the opportunity to state a claim in their own words and how they do this: individually or in pairs, orally or in writing. Refining language and offering vocabulary as needed. ---Russell, Schifter, & Bastable, (2011), p. 49. Variables are versatile tools that are used to describe mathematical ideas in succinct ways. ---Blanton, et al., 2011, p. 32. What is a variable? How would you describe the role played by the variable t in each of the following: ◦ t + 4 = 3t – 6 ◦ y = tx + 2 ◦ 3 + (t + 5) = (3 + t) + 5 ---Blanton, et al., 2011, p. 34 A variable can represent: 1. a number in a generalized pattern. 2. a fixed but unknown number. 3. a quantity that varies, especially in relation to another quantity. 4. a parameter. 5. an arbitrary or abstract placeholder in an algebraic process. --Blanton et al., 2011, pp. 32-34. Make a conjecture that describes why all these examples are true. 2×6=4×3 5 × 16 = 10 × 8 32 × 50 = 16 × 100 If you double one factor in a multiplication expression and halve the other, the product remains the same. (a × 2) × (b ÷ 2) = a × b “Mathematical proofs are important because they provide insights into the mathematical relationships that underlie generalizations. By engaging in proof, students learn not just that claims are true, but why they are true… the types of proofs that elementary-aged students can construct are representationbased [for example: using a number line, objects, or a story context]” ---Russell, Schifter, & Bastable, (2011), p. 56. The meaning of the operation(s) involved in the conjecture is represented in diagrams, manipulatives, or story contexts. The representation can accommodate a class of instances (for example, all whole numbers). The conclusion of the conjecture follows from the structure of the representation; that is, the representation shows why the statement must be true. How would you prove 2x6=4x3? 1.What does each argument show that the student understands about proving the conjecture? 2. What more would the student need to do to move toward proving this conjecture? I figured out that 2 times 6 equals 4 times 3, and also 8 times 10 equals 4 times 20. So it works. Argument #2: I did a story context. I have 2 stacks of books, and each one has 6 books. That’s 12 books. Then I have 4 stacks of books, and each one only has 3 books. That’s 12, too. So they’re the same. Argument #3: I have 2 stacks of books, and each one has 6 books. But the stacks were too heavy to carry, so I put each stack in half. Now there are 4 stacks and each has 3 books. So when I doubled the number of stacks, there was only half of the books in a stack than there was before. Argument #4: See this is a 2 by 6, and this is a 4 by 3, and they both have 12. Argument #5: I cut the 2 by 6 in half, and I put one piece underneath. It’s half across the top, but now it’s twice as tall. It’s all the same stuff I started with, like if this was a carpet and I cut it and moved it around. 1. Draw an unknown amount as one ‘jump’ on a number line. Label it j. 2. If this is one jump, what does 3j look like? 3. How about one jump and seven steps? 4. What do three jumps and one step backward look like? Day One: Frog Jumping Lesson; Look at Appendices A & B; Complete Appendix C ‘Jump and step’ on classroom number line Draw ‘jumps and steps’ on an open number line for Appendix C activity 4j + 8 = 52 What if j + 7 = 23? How many steps are equal to one jump? Use an open number line to represent this equation. Solve for j. (Jacob & Fosnot, 2007, pp. 15-20) “Reasoning with properties of equality and of number and operations [p.16 properties] to solve equations with a single variable can provide a foundation for understanding how to solve more complex equations” --Blanton et al., p. 29 4 properties of equality: ◦ Addition property of equality ◦ Subtraction property of equality ◦ Multiplication property of equality ◦ Division property of equality + Reading Expressions Place some of the Algebra Tiles on the Basic Mat 1 1 1 1 X Combine like terms and read the algebraic expression. Answer X+4 _ National Library of Virtual Manipulatives http://nlvm.usu.edu/ + X 1 1 1 1 + = 1 1 1 1 1 1 1 1 1 1 1 1 _ What equation is modeled on the Equation Mat? Answer: _ X + 4 = 12 Model with Algebra Tiles 2X X+5 5–X 4X – 2X + 3 2(X+3) Write the expression for this Cup and Chip model. =X =1 Make connections between the symbols and algebra tiles to model the following: Model the 3 different balance scales using algebra tiles. Solve the equations using the tiles and write out the steps of your actions. NO PENCILS! (Collins & Dacey, 2011, p. A17) Teams of three teachers model at least 3 different equations using algebra tiles, Chips and Cups model, and balance model. Solve the equations using the manipulatives, and write out the steps of your actions. (Collins & Dacey, 2011, p. A20) http://www.borenson.com Make a conjecture that describes how the perimeter of a square varies with the length of the side of the square. 1cm In words: The perimeter of the square is 4 times the length of the side of the square. With symbols: p = 4s where p is the perimeter and s is the length of the side of the square. “A parameter can be thought of as a quantity whose value determines the characteristics or behaviors of other quantities” (p. 33). --Blanton et al., 2011 ◦ Every week Diondra’s Dad gives her money for helping with chores around the house. Diondra is saving her money to buy a bicycle. Write an equation that represents the amount of money Diondra saves (s) if her Dad gives her d (dollars) in w (weeks). How would this equation be different if Diondra’s Dad gives her $5 for helping with chores each week? How about $15? How about $20? (Of course she has to do more chores for more money.) If the bike Diondra wants costs $300, what is the fewest number of weeks Diondra must do chores in order to buy her new bike? Explain your thinking. 3 + (t + 5) = (3 + t) + 5 t is thought of as an abstract symbol that can be manipulated. It does not represent a particular number under a particular circumstance. 3 x 5 + 3 x 6 = 3(5 + 6) Cherry Orange Base 10 12 12 17 21 X x x x 3 14 23 23 and Algebra Tiles 17 * 23 = (10 + 7) x (20 +3) = 10 (20 +3) + 7(20+3) = (10x20) + (10x3) + (7x20)+ (7x3) = 200 + 30 + 140 + 21 = 391 Model with your base ten blocks to see the four partial products; build a 17 x 23 rectangle. Now try 12 x 22: write the equation that shows the distributive property, build the rectangular model, draw a sketch, and state the product. For each of the following expressions use the distributive property to find an equivalent expression. Then model with algebra tiles or Hands-on-Equations, make a sketch, and write an equation that shows the two expressions are equal. a) 3(x - 2) b) 4(x + 3) 1. Draw one jump and 2 steps. What else could it look like? 2. So how about two jumps and four steps? 3. What about 2(j + 2) on the same double number line, with the previous problem. 4. What about 3(j + 2)? 5. What about 3j + 6 on the same double number line? --- Fosnot and Jacob (2010). Young mathematicians at work: Constructing algebra. Portsmouth, NH: Heinemann. (p.166) Use a double open HUMAN number line to show why the following is an equation. (3 x 2) + (3 x 5) = 3 (2 + 5) Use a double open number line to show why the following is an equation. (12 x 4) - (12 x 3) = 12 (4 - 3) “Regardless of what interpretation is given to a variable, it is important to develop an appreciation for the complexity associated with a thorough understanding of variables” (p. 36). --Blanton et al., 2011 “The same variable used more than once in the same equation must represent identical values in all instances, but different variables may represent the same value.” (p.37). --Blanton et al., 2011 Be sure to use the term equation when working with things that are = Be sure to use the term inequality when working with things that are >, <, or ≠ Equations and Inequalities are both types of mathematical sentences. 8+4=5+7 5=4+1 6X0=6 Who would like to explain their thinking about the first sentence? How about the second equation? How could we rewrite the third sentence to make it a true sentence? ---Wickett, et al., 2002, p. 29 Take the next few minutes to think of at least one example of a mathematical sentence that is true and one that is false. Make two columns on the board, one for true sentences and one for false sentences. Take turns sharing your sentences and discussing why they are true or false. What about this one… 6 x 3 ÷ 2 = 4 + 5? ---Wickett, et al., 2002, p. 32 5 + = 13 What could we put in the box to make this statement a true statement? is called an open sentence because it is not true or false. This Is there anything else we could put in the box to make it a true statement? ---Wickett, et al., 2002, p. 33 Would 7 x 6 = be an open sentence? Can anyone think of a value for the that would make the statement true? Can anyone think of a value for the that would make the statement false? How about 4 + = 12? ---Wickett, et al., 2002, p. 34 It is an open sentence if whether or not it is true or false depends on the what is in the box. Now think of three open sentences that you can share with the class. Share the sentences and decide if they are open sentences or not. For the open sentences decide what has to be in the box for the statement to be true. What about - 4 = 3? I think the following sentence is the same as the one above but different in another way. What am I thinking? What if I wrote - 4 =3? What if I wrote x – 4 = 3? Is this still an open sentence? Can you use any letter for the variable? ---Wickett, et al., 2002, p. 35 How is this open sentence different from the others we have been discussing? + = 10 Is it still an open sentence if it has more than one box? What could we put in the boxes to make this a true statement? When you use a variable in more than one place in a sentence, it has to take on the same value. ---Wickett, et al., 2002, p. 36 How could I make this open sentence false and still use the rule that the box has to stand for the same value? X =16 What could I place in the box to make the sentence true? =8 ---Wickett, et al., 2002, p. 37 You can have more than one variable. What values will make this open sentence true? + = 10 The variables are different so they do not have to be the same value. It is possible that the different variables have the same value. ---Wickett, et al., 2002, p. 37 What value for the variable will make this open sentence true? ( x 5) + 3 – 20 = 8 ---Wickett, et al., 2002, p. 41 Share explanations of how you decided on the value of each shape. Can each of the circles have a different value? How do you know? Can the circle and the triangle have the same value? How do you know? -- (2009) Focus in Grades 3-5 Teaching with Curriculum Focal Points. Reston, VA: NCTM. Read: Do: ◦ Blanton et al. (2011): pp. 25-38 ◦ Jacob & Fosnot (2007) Day Two, pp. 21-26; and Day 6 and Day 7, pp. 45-53 ◦ Wickett et al. (2002): Read pages 38 - 42 and focus on the student work. The students were asked to write 5 open sentences and tell how to make the statement true. Steve had incorrect solutions to #3 and #5. What are the correct solutions? Justin has an error in his first equation. What is it? Choose one of Tessa’s equations and explain how you know her equation is true for the given value.