Algebra Tiles . . . Get Them out Dust Them Off
Algebra Tiles. . . Get Them out Dust Them Off Connie Schlimme Sanderson High Wake Co. [email protected] 1 Algebra Tiles. . . Get Them out Dust Them Off Adapted from REL HYBIRD ALGEBRA RESEARCH PROJECT which was adapted from David McReynolds, AIMS PreK-16 Project and Noel Villarreal, South Texas Rural Systemic Initiative November , 2007 Algebra Tiles • Manipulatives used to enhance student understanding of concepts traditionally taught at symbolic level. • Provide access to symbol manipulation for students with weak number sense. • Provide geometric interpretation of symbol manipulation. 3 Algebra Tiles • Support cooperative learning, improve discourse in classroom by giving students objects to think with and talk about. • When I listen, I hear. • When I see, I remember. • But when I do, I understand. 4 Algebra Tiles • Algebra tiles can be used to model operations involving integers. • Let the small yellow square represent +1 and the small red square (the flip-side) represent -1. The yellow and red squares are additive inverses of each other. 5 Algebra Tiles • Algebra tiles can be used to model operations involving variables. • Let the green rectangle represent +1x or x and the red rectangle (the flip-side) represent -1 x or -x . The green and red rods are additive inverses of each other. 6 Algebra Tiles • Let the blue square represent x2. The red square (flip-side of blue) represents -x2. • As with integers, the red shapes and their corresponding flip-sides form a zero pair. 7 YOU MAY HAVE AN EARLIER VERSION THAT LOOK LIKE THIS: These will work just as well. . . with a little alteration - - 8 Zero Pairs • Called zero pairs because they are additive inverses of each other. • When put together, they model zero. • Don’t say “cancel out” for zeroes! Instead say “they form a zero pair” or “they add up to zero.” 9 10 Addition of Integers • Addition is ―combining.‖ • Combining involves the forming and removing zero pairs. • For each of the given examples, use algebra tiles to model the addition. • Draw pictorial diagrams which show the modeling. • Write the manipulation performed. 11 Addition of Integers (+3) + (+1) = • Combined like objects to get four positives (-2) + (-1) = • Combined like objects to get three negatives 12 Addition of Integers (+3) + (-1) = +2 • Make a zero pair, two positives remain. (+3) + (-4) = -1 • Make three zero pairs, one negative remains. • Have students practice applying the concept with larger integers. Fade away the manipulatives. 13 Subtraction of Integers • Subtraction is ―taking away.‖ • If we do not have enough positive or negative tiles to take away, we represent the number in a different form by adding zero pairs. • For each of the given examples, use algebra tiles to model the subtraction. • Draw pictorial diagrams which show the modeling process. • Write a description of the actions taken. 14 Subtraction of Integers (+5) – (+2) = +3 • Take away two positives, three positives remain (-4) – (-3) = -1 • Take away three negatives, one negative remains 15 Subtracting Integers (+3) – (-5) = +8 Add some zero pairs, take away five negatives, eight positives remain (-4) – (+1)= -5 Add some zero pairs, take away one positive, five negatives remain 16 Subtracting Integers (+3) – (-3)= • After students have seen many examples, students will begin to see the pattern that subtracting gives the same result as adding the opposite. (+3) – (-3) has the same value as 3 + 3 17 Addition/Subtraction of Integers Try These: • (+1) + (+ 3) • (-3) + (-4) • (+4) + (-6) • (-7) – (-2) 18 Multiplication of Integers • Multiplication is repeated addition – we are combining sets of tiles. • The first factor tells us the number of sets needed. • The second factor tells the size of the set (how many tiles) and the kind of numbers/tiles to use (positive or negative). • If the first factor is negative, we interpret that as ―the opposite of.‖ 19 Multiplication of Integers number of sets size and kind of set (+2)(+3) = +6 (+3)(-4) = +12 Two sets of three positives Three sets of four negatives 20 Multiplication of Integers • If the first factor is negative it means ―the opposite of.‖ (-2)(+3) = -6 The opposite of two sets of three positives (-3)(-1) = +3 The opposite of three sets of one negative 21 Multiplication of Integers Let’s Practice • (+4)(+2) • (+5)(-3) • (-2)(+2) • (-3)(-3) 22 Multiplication of Integers • After students have seen many examples, students will begin to see the pattern for integer multiplication. • Have students practice applying the concept with larger integers. Fade away the manipulatives. 23 Division of Integers • Division is putting things into sets of equal size. • We start with a total number of tiles – either positive or negative. • The divisor tells us how many sets to make. • The answer is how many tiles are in each set. • If the divisor is negative, we interpret that as ―the opposite of.‖ 24 Division of Integers (+6)/(+2) = 3 • Put the tiles into two equal groups of 3 positives (-8)/(+2) = -4 • Put the tiles into two equal groups of 4 negatives 25 Division of Integers A negative divisor means ―take the opposite of‖ (flip-over) (+10)/(-2) = -5 • Divide ten tiles into two equal groups of +5 • Find the opposite of +5 26 Division of Integers (-12)/(-3) = +4 • Divide 12 negatives into 3 equal groups of -4. • Find the opposite of -4. 27 Division of Integers It’s Your Turn! • (+8)/(+4) • (+12)/(-3) • (-12)/(+6) • (-10)/(-5) 28 Polynomials and Algebra Tiles 29 Polynomials ―Polynomials are unlike the other ‗numbers‘ students learn how to add, subtract, multiply, and divide. They are not ‗counting‘ numbers. Giving polynomials a concrete reference (tiles) makes them real.‖ David A. Reid, Acadia University 30 Modeling Polynomials • Algebra tiles can be used to model expressions. • Model the simplification of expressions. • Add, subtract, multiply, divide, or factor polynomials. 31 Modeling Polynomials 2x2 4x 3 or +3 32 More Polynomials • Represent each of the given expressions with algebra tiles. • Draw a pictorial diagram of the process. • Write the symbolic expression. x+4 33 More Polynomials 2x + 3 4x – 2 34 More Polynomials • Examples from page 7 35 Zero Pairs • Called zero pairs because they are additive inverses of each other. • When put together, they model zero. • Don‘t say ―cancel out‖ for zeroes! Instead say ―they form a zero pair‖ or ―they add up to zero.‖ + - + 36 Find the Additive Inverse Model and find the additive inverse for: • 5x + 1 • 3x2 + 1 • -2 + 4x • -4x2 - 7 37 Simplifying Polynomials: Combining Like Terms • 4x – 4x + 1 • 3x – 4x – 1 • 5x2 + 2x – x • -5 + 6x2 -4x • 3x + 2x + 5x 38 Simplifying Polynomials: Distributive Property • Use the same concept that was applied with multiplication of integers: think of the first factor as the number of sets. • Consider the following: 3(x + 2) • We need three sets of x + 2 39 Distributive Property 3(x + 2)= 3·x + 3·2 = 3x + 6 We have three x‘s and three groups of +2 3x +6 40 Distributive Property Model each of the following: 1. 2(x + 2) 2. 4(x + 3) 3. 3(2x – 3) 4. -3(3x -2) 41 Adding and Subtracting Polynomials • Use algebra tiles to simplify each of the given expressions. Combine like terms. Look for zero pairs. Draw a diagram to represent the process. • Write the symbolic expression that represents each step. 42 More Polynomials 2x + 4 + x + 1 = 3x + 5 Combine like terms to get three x’s and five positives 43 More Polynomials 3x – 1 – 2x + 4 • This process can be used with problems containing x2. (2x2 + 5x – 3) + (-x2 + 2x + 5) (2x2 – 2x + 3) – (3x2 + 3x – 2) 44 Polynomials Background Knowledge Activity Background Knowledge (SIOP) “For maximum learning to occur, planning must produce lessons that enable students to make connections between their own knowledge and experience and new information being taught.” Echevarria, Jana, Vogt, MaryEllen, Short, Deborah. (2008) Making Content Comprehensible for English Learners. SIOP Model. Pearson. 3rd Edition. P. 23 Ask Yourself What connections can I make with students to introduce Polynomials? Let‘s Build Background! Objective: Today you will write a definition for the following vocabulary words: Monomial Trinomial Binomial Polynomial Warm Up Warm up: With a shoulder buddy determine how many terms are in each expression? How do you count the terms? 7x + 2 4x3 9x4 + 11 + 3 2 1 3 A term is _________________________ Categorize Activity 1) Look at your expression and determine if it has 1 term, 2 terms, or 3 terms. 2) Go to the poster that represents your expression. 3) With your group determine what picture best represents your expressions and be ready to explain why. Polynomial (many terms) (A polynomial is a monomial or the sum or difference of two or more monomials ) 1 term 4x 9y2 -8cd2 9a -5x2y xy 2 terms 6c – 5 7x + 4 -a + 2xy 3 terms 4x2 + 2x +5 7x + 4 x-2 5x2 – 2x3 6c-5 5x2 – 2x + 3 t + 14 – xy 4x2 + 2x + 5 5x2 – 2x + 3 X2 + 5 + t monomial binomial A monomial is an expression with 1 term. (product, variables) A binomial is an expression with 2 terms. trinomial A trinomial is an expression with 3 terms. Write Your Definition Notes for Polynomials Directions: Write a definition and illustrate the word. A monomial is: A polynomial is: A binomial is: A trinomial is: Reflect • Did we introduce the concept of polynomials? • What was connection we made for our students? • Could you use this type of activity in your classroom? Polynomial Partner Practice! 54 Substitution • Algebra tiles can be used to model substitution. Represent original expression with tiles. Then replace each rectangle with the appropriate tile value. Combine like terms. 3 + 2x let x = 4 55 Substitution 3 + 2x = 3 + 2(4) = 3+8= 11 let x = 4 56 Solving Equations • Algebra tiles can be used to explain and justify the equation solving process. The development of the equation solving model is based on two ideas. • Equivalent Equations are created if equivalent operations are performed on each side of the equation. (Which means to use the additon, subtraction, mulitplication, or division properties of equality.) What you do to one side of the equation you must do to the other side of the equation. • Variables can be isolated by using the Additive Inverse Property ( & zero pairs) and the Multiplicative Inverse Proerty ( & dividing out common factors). The goal is to isolate the variable. 57 Solving Equations x+2= 3 -2 -2 x =1 •x and two positives are the same as three positives •add two negatives to both sides of the equation; makes zeroes •one x is the same as one positive 58 Solving Equations -5 = 2x ÷2 ÷2 2½ = x •Two x’s are the same as five negatives •Divide both sides into two equal partitions •Two and a half negatives is the same as one x 59 Solving Equations 1 x 2 · -1 · -1 1 x 2 •One half is the same as one negative x •Take the opposite of both sides of the equation •One half of a negative is the same as one x 60 Solving Equations x 2 3 • 3 •3 x = -6 •One third of an x is the same as two negatives •Multiply both sides by three (or make both sides three times larger) •One x is the same as six negatives 61 Solving Equations 2x+3=x–5 -x -x x + 3 = -5 + -3 + - 3 x = -8 •Two x’s and three positives are the same as one x and five negatives •Take one x from both sides of the equation; simplify to get one x and three the same as five negatives •Add three negatives to both sides; simplify to get x the same as eight negatives 62 Solving Equations 3(x – 1) + 5 = 2x – 2 3x – 3 + 5 = 2x – 2 3x + 2 = 2x – 2 – 2 or + -2 3x = 2x – 4 -2x -2x x = -4 “x is the same as four negatives” 63 Multiplying Monomials (2x)(3) Make 3 sets of two x’s 64 Multiplying Polynomials by Monomials x(x – 1) Fill in each section of the area model x2 – 1x 65 Multiplying Polynomials by Monomials x(2x + 3) = 2x2 + 3x Fill in each section of the area model 66 Dividing Monomials •4x/2x = 2x Find Zero Pairs and simplify 67 Round Robin Practice 68 Multiplication • Multiplication using ―area model‖ (12)(13) • Think of it as (10+2)(10+3) • Multiplication using the array method allows students to see all four subproducts. 69 Multiplication using “Area Model” (12)(13) = (10+2)(10+3) = 100 + 30 + 20 + 6 = 156 10 x 10 = 102 = 100 10 10xx22==20 20 10 x 3 = 30 2x3=6 70 Multiplying Polynomials (x + 2)(x + 3) Fill in each section of the area model Combine like terms x2 + 2x + 3x + 6 = x2 + 5x + 6 71 Multiplying Polynomials (x – 1)(x +4) Fill in each section of the area model Make Zeroes or combine like terms and simplify x2 + 4x – 1x – 4 = x2 + 3x – 4 72 Multiplying Polynomials (x + 2)(x – 3) (x – 2)(x – 3) (x + 4)(x – 2) 73 Factoring Polynomials • Algebra tiles can be used to factor polynomials. Use tiles and the frame to represent the problem. • Use the tiles to fill in the array so as to form a rectangle inside the frame. • Be prepared to use zero pairs to fill in the array. • Draw a picture. 74 Factoring Polynomials 3x + 3 = 3 · (x + 1) 2x - 6 = 2 * (x – 3) Note the two are positive, this needs to be developed 75 Factoring Polynomials x2 + 6x + 8 = (x + 2)(x +4) 76 Factoring Polynomials x2 – 5x + 6 = (x – 2)(x – 3) 77 Factoring Polynomials x2 – x – 6 = (x + 2)(x – 3) 78 Factoring Polynomials x2 + x – 6 x2 – 1 x2 – 4 2x2 – 3x – 2 2x2 + 3x – 3 -2x2 + x + 6 79 X-box Factoring Filling in the X Trinomial ax2 + bx + c 1) Place the product of a and c at the top of the x. 2) Place the coefficient b at the bottom of the x. 3) Fill the 2 empty sides with 2 numbers that are factors of the product on the top and add to give you the value of b on the bottom. Product of a&c b Filling in the X x2 + 9x + 20 1∙20= 20 5 Fill the 2 sides with numbers that are factors of 20 that add to give you 9. 4 9 Filling in the X 2x2 -x - 21 2(-21)= -42 6 Fill the sides with two numbers that are factors of -42 that add to give you -1. -7 -1 X-box Factoring • This is a guaranteed method for factoring quadratic equations—no guessing necessary! • We will learn how to factor the trinomial using the x-box method. LET‘S TRY IT! Objective: Students will be able to use the x-box factoring method to factor nonprime trinomials. Factor the X-box way Example: Factor x2 -3x -10 (1)(-10)= x -10 -5 x x2 -5x GCF +2 2x -10 GCF 2 -3 GCF x2 -3x -10 = (x-5)(x+2) -5 GCF Factor the X-box way y = ax2 + bx + c First and Last Coefficients Product GCF 1st column GCF 2nd column 1st Term Factor Factor Last term ac GCF 1st Factor row Factor b Sum Middle coefficient GCF 2nd row Factor the X-box way Example: Factor 3x2 -13x -10 x -5 3x 3x2 -15x +2 2x -10 -30 2 -15 -13 3x2 -13x -10 = (x-5)(3x+2) Examples Factor using the x-box method. 1. x2 + 4x – 12 a) b) -12 6 -2 4 x x x2 +6 6x -2 -2x -12 Solution: x2 + 4x – 12 = (x + 6)(x - 2) Examples continued 2. x2 - 9x + 20 a) 20 -4 -5 -9 b) x x -4 x2 -4x -5 -5x 20 Solution: x2 - 9x + 20 = (x - 4)(x - 5) Examples continued 3. 2x2 - 5x - 7 a) -14 -7 2 -5 2x b) -7 x 2x2 -7x +1 2x -7 Solution: 2x2 - 5x – 7 = (2x - 7)(x + 1) Examples continued 3. 15x2 + 7x - 2 a) b) -30 10 -3 7 3x 5x +2 15x2 10x -1 -3x -2 Solution: 15x2 + 7x – 2 = (3x + 2)(5x - 1) Extra Practice 1. x2 +4x -32 2. 4x2 +4x -3 3. 3x2 + 11x – 20 Reminder!! Don‘t forget to check your answer by multiplying! Dividing Polynomials • Algebra tiles can be used to divide polynomials. • Use tiles and frame to represent problem. Dividend should form array inside frame. Divisor will form one of the dimensions (one side) of the frame. • Be prepared to use zero pairs in the dividend. 95 Dividing Polynomials x2 + 7x +6 = (x + 6) x+1 96 Dividing Polynomials x2 + 7x +6 x+1 2x2 + 5x – 3 x+3 x2 – x – 2 x–2 x2 + x – 6 x+3 97 Conclusion • Algebra tiles can be made using the Ellison (die-cut) machine. • On-line reproducible can be found by doing a search for algebra tiles. • Virtual Algebra Tiles at HRW http://my.hrw.com/math06_07/nsm edia/tools/Algebra_Tiles/Algebra_ Tiles.html National Library of Virtual Manipulatives http://nlvm.usu.edu/en/nav/topic_t _2.html 98 Resources • David McReynolds AIMS PreK-16 Project • Noel Villarreal South Texas Rural Systemic Initiative • Jo Ann Mosier & Roland O‘Daniel Collaborative for Teaching and Learning • Partnership for Reform Initiatives in Science and Mathematics 99
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