research—best practices putting research into practice · contents planning research & math...
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Research & Math BackgroundContents Planning
Dr. Karen C. Fuson, Math Expressions Author
ReseaRch—Best PRactices
Putting Research into Practice
From Our Curriculum Research Project: Math Talk Is Important
A significant part of the collaborative classroom culture in Math Expressions is the frequent exchange of problem-solving strategies, or Math Talk. The benefits of Math Talk are multiple. Describing one’s methods to another person can clarify one’s own thinking as well as clarify the matter for others. Another person’s approach can supply a new perspective, and frequent exposure to different approaches tends to engender flexible thinking. Math Talk creates opportunities to understand errors and permits teachers to assess students’ understanding on an ongoing basis. It encourages students to develop their language skills, both in math and in everyday English. Finally, Math Talk enables students to become active helpers and questioners, creating student-to-student talk that stimulates engagement and community.
From Current Research: Models of Fractions
During Grades 3–5, students should build their understanding of fractions as parts of a whole and as division. They will need to see and explore a variety of models of fractions, focusing primarily on familiar fractions such as halves, thirds, fourths, fifths, sixths, eighths, and tenths.
By using an area model in which part of a region is shaded, students can see how fractions are related to a unit whole, compare fractional parts of a whole, and find equivalent fractions.
Students should develop strategies for ordering and comparing fractions, often using benchmarks such as 1 _ 2 and 1. For example, fifth graders can compare fractions such as 2 _ 5 and 5 _ 8 by comparing each with 1 _ 2 ; one is a little less than 1 _ 2 , and the other is a little more.
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Beckman, S., Fuson, K. C., SanGiovanni, J., & Adams, T. L. Focus in Grade 5: Teaching with Curriculum Focal Points. Reston, VA: NCTM, 2009.
Kilpatrick, Jeremy, Jane Swafford, Bradford Findell, eds. Adding It Up: Helping Children Learn Mathematics. Mathematics Learning Study Committee, National Research Council. Washington, DC: National Academy Press, 2001. (especially Chapter 7: Developing Proficiency with Other Numbers).
Mack, Nancy K. “Connecting to Develop Computational Fluency with Fractions.” Teaching Children Mathematics 11.4 (Nov. 2004): pp. 226–232.
National Council of Teachers of Mathematics. Making Sense of Fractions, Ratios, and Proportions (2002 Yearbook). Reston, VA: NCTM, 2002.
By using parallel number lines, each showing a unit fraction and its multiples (see Fig. 5.1), students can see fractions as numbers, note their relationship to 1, and see relationships among fractions, including equivalence. They should also begin to understand that between any two fractions, there is always another fraction.
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Fig. 5.1. Parallel number lines with unit fractions and their multiplesNational Council of Teachers of Mathematics. Principles and Standards for School
Mathematics (Number and Operations Standard for Grades 3–5). Reston: NCTM, 2000. p. 150
Other Useful References: Fractions
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Research & Math BackgroundContents Planning
Getting Ready to Teach Unit 1Using the Common Core Standards for Mathematical PracticeThe Common Core State Standards for Mathematical Content indicate what concepts, skills, and problem solving students should learn. The Common Core State Standards for Mathematical Practice indicate how students should demonstrate understanding. These Mathematical Practices are embedded directly into the Student and Teacher Editions for each unit in Math Expressions. As you use the teaching suggestions, you will automatically implement a teaching style that encourages students to demonstrate a thorough understanding of concepts, skills, and problems. In this program, Math Talk suggestions are a vehicle used to encourage discussion that supports all eight Mathematical Practices. See examples in Mathematical Practice 6.
Mathematical Practice 1 Make sense of problems and persevere in solving them.
Students analyze and make conjectures about how to solve a problem. They plan, monitor, and check their solutions. They determine if their answers are reasonable and can justify their reasoning.
TeaCher ediTion: examples from Unit 1
MP.1 Make Sense of Problems Approach Problem 19 strategically so students don’t add together every possible pair of numbers to see if the sum is 10 tons or less. Break the class into Small Groups and ask them to brainstorm for strategies to make solving the problem easier. Have each group share its ideas with the class.
Lesson 9
MP.1 Make Sense of Problems Check Answers Discuss how we can check that 12 11 __ 12 cups is a reasonable answer. Here is a possible method.
→ Round to the Nearest Whole Number Round 2 3 _ 4 up to 3 and round 4 1 _ 3 down to 4: 20 - (3 + 4) = 13 (or equivalently,20 - 3 - 4 = 13). The answer should be close to 13 cups. So, 12 11 __ 12 cups is a reasonable answer.
Lesson 12
Mathematical Practice 1 is integrated into Unit 1 in the following ways:
Analyze the ProblemCheck Answers
MathBoard ModelingRepresent the Problem
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Mathematical Practice 2Reason abstractly and quantitatively.
Students make sense of quantities and their relationships in problem situations. They can connect diagrams and equations for a given situation. Quantitative reasoning entails attending to the meaning of quantities. In this unit, this involves understanding and generating equivalent fractions and comparing, adding, and subtracting fractions and mixed numbers.
TeACHeR eDITION: examples from Unit 1
MP.2 Reason Abstractly and Quantitatively Connect Symbols and Words It may help students if they write the unit fractions as word names.
one third + one third + one third = three thirds, or 1one third + one third + one third = three thirds, or 1one third + one third = two thirds
eight thirds = two and two thirds
Lesson 5
MP.2 Reason Abstractly and Quantitatively Connect Symbols and Models Have students look at the fraction bar at the top of Student Book page 17. Let students lead the discussion as much as possible.
• The first bar shows 1 _ 2 + 1 _ 3 . Does it tell us what the total is called? No.
• How can we decide what to call the total? Divide the bar, using a fraction that can rename halves and thirds, a unit fraction that can make 1 _ 2 and also 1 _ 3 .
• How can we find a fraction that does that? Multiply the two denominators: 2 × 3.
Lesson 7
Mathematical Practice 2 is integrated into Unit 1 in the following ways:
Connect Symbols and ModelsConnect Symbols and Words
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Mathematical Practice 3 Construct viable arguments and critique the reasoning of others.
Students use stated assumptions, definitions, and previously established results in constructing arguments. They are able to analyze situations and can recognize and use counterexamples. They justify their conclusions, communicate them to others, and respond to the arguments of others.
Students are also able to distinguish correct logic or reasoning from that which is flawed, and—if there is a flaw in an argument—explain what it is. Students can listen or read the arguments of others, decide whether they make sense, and ask useful questions to clarify or improve the arguments.
MATH TALK is a conversation tool by which students formulate ideas and analyze responses and engage in discourse. See also MP.6 Attend to Precision.
TeaCher ediTion: examples from Unit 1
MP.3, MP.6 Construct Viable arguments/Critique reasoning of others Puzzled Penguin Give students a minute or two to read the Puzzled Penguin letter and think about how they would respond. Choose volunteers to share their responses and discuss them as a class. The letter emphasizes the need to multiply both parts of a fraction by the same number in order to find an equivalent fraction.
Lesson 3
MP.3 Construct Viable arguments Compare Strategies For each problem, choose a pair to present the solution. Then ask if anyone solved the problem a different way. If so, ask them to present the strategy they used.
Lesson 12
Mathematical Practice 3 is integrated into Unit 1 in the following ways:
Compare MethodsCompare StrategiesPuzzled Penguin
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Mathematical Practice 4 Model with mathematics.
Students can apply the mathematics they know to solve problems that arise in everyday life. This might be as simple as writing an equation to solve a problem. Students might draw diagrams to lead them to a solution for a problem.
Students apply what they know and are comfortable making assumptions and approximations to simplify a complicated situation. They are able to identify important quantities in a practical situation and represent their relationships using such tools as diagrams, tables, graphs, and formulas.
TeACHeR eDITION: examples from Unit 1
MP.1, MP.4 Make Sense of Problems/Model with Mathematics MathBoard Modeling Write this problem on the board:
Nina has 5 _ 6 yard of fabric. She uses 2 _ 3 yard of it. How much fabric is left?
Elicit from students that the answer can be found by solving the subtraction problem 5 _ 6 – 2 _ 3 . Write this problem on the board. Tell students we will use fraction bars to model this problem.
On their MathBoards, instruct students to circle 5 _ 6 on the sixths fraction bar.
Sixths
Then challenge them:
• Try to subtract 2 _ 3 . How can you do it without using the thirds fraction bar?
Lesson 8
MP.4 Model with Mathematics Write an Equation Ask if anyone wrote an equation to represent their calculations, and discuss the two equations below. In both, f represents the amount of flour left in the bag. Be sure students understand that, in the first equation, the parentheses indicate that we do the addition first and then we subtract the result from 20.
f = 20 - (2 3 _ 4 + 4 1 _ 3 ) f = 20 - 2 3 _ 4 - 4 1 _ 3
Lesson 12
Mathematical Practice 4 is integrated into Unit 1 in the following ways:
Describe a MethodMathBoard ModelingRepresent the ProblemWrite an Equation
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Mathematical Practice 5Use appropriate tools strategically.
Students consider the available tools and models when solving mathematical problems. Students make sound decisions about when each of these tools might be helpful. These tools might include paper and pencil, a straightedge, a ruler, or the MathBoard. They recognize both the insight to be gained from using the tool and the tool’s limitations. When making mathematical models, they are able to identify quantities in a practical situation and represent relationships using modeling tools such as diagrams, grid paper, tables, graphs, and equations.
Modeling numbers in problems and in computations is a central focus in Math Expressions lessons. Students learn and develop models to solve numerical problems and to model problem situations. Students continually use both kinds of modeling throughout the program.
Teacher ediTion: examples from Unit 1
MP.5 Use appropriate Tools MathBoard Modeling Be sure to include the following points in a class discussion about the MathBoard:
→ The top bar shows one whole. The other bars show this same whole divided into different numbers of equal parts.
→ The bars are labeled halves, thirds, fourths, and so on to indicate how the bars are divided.
→ The number of parts increases with each bar, while the size of the parts decreases.
Unit Fractions Ask students what fraction each part of the halves bar represents. 1 _ 2 Students should label the first part with this fraction as shown. Explain that students can think of 1 _ 2 as 1 of 2 equal parts.
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MP.5 Use appropriate Tools Model the Mathematics You might draw, or have a student draw, fraction-bar models to illustrate 4 _ 5 is greater than 3 _ 5 .
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Lesson 4
Mathematical Practice 5 is integrated into Unit 1 in the following ways:
Draw a DiagramMathBoard ModelingModel the Mathematics
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Mathematical Practice 6 Attend to precision.
Students try to communicate precisely to others. They try to use clear definitions in discussion with others and in their own reasoning. They state the meaning of the symbols they choose. They are careful about specifying units of measure to clarify the correspondence with quantities in a problem. They calculate accurately and efficiently, expressing numerical answers with a degree of precision appropriate for the problem context. Students give carefully formulated explanations to each other.
TeACHeR eDITION: examples from Unit 1
MP.6 Attend to Precision Describe a Method Write the fraction 9 _ 4 on the board, and ask students to change it to a mixed number. Send several volunteers to the board while the others work at their seats. Encourage other students to contribute to the explanations or to ask questions.
Lesson 5
MP.6 Attend to Precision Explain a Solution Have Small Groups work on the exercises on Student Book page 23. Then discuss the answers to Exercises 10–12 as a class. Allow students to explain in their own words how they found a common denominator for the fractions in each group. Encourage other students to ask questions if an explanation is unclear to them.
Lesson 10
MATH TALK Choose volunteers to explain how they determined which fraction is greater. Encourage students to use the idea of unit fractions in their explanations. Students should understand that the unit fractions for both fractions are the same size (specifically, both are fifths). Because 4 _ 5 has 4 unit fractions ( 1 _ 5 + 1 _ 5 + 1 _ 5 + 1 _ 5 ) and 3 _ 5 has only 3 unit fractions ( 1 _ 5 + 1 _ 5 + 1 _ 5 ), 4 _ 5 is greater.
Lesson 4
MATH TALKin ACTION
Students describe Puzzled Penguin’s error and explain how to correct it.
What is the mistake in Puzzled Penguin’s work?
Zander: The ungrouping is not right. Puzzled Penguin should have changed the 5 to a 4.
Mica: Yes, to get 7 _ 5 , you have to take 5 _ 5 , which is 1 whole, from the 5. That means you have to change the 5 to a 4.
Alice: I would tell Puzzled Penguin to add some more steps. That’s what I do.
Alice, can you explain what you would do?
Alice: I would write 5 as 4 + 5 _ 5 and then add the 2 _ 5 .
Will you come to the board and show us?
Lesson 6
Mathematical Practice 6 is integrated into Unit 1 in the following ways:
Describe a Method Explain a Solution
Puzzled PenguinVerify Solutions
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Mathematical Practice 7 Look for and make use of structure.
Students analyze problems to discern a pattern or structure. They draw conclusions about the structure of the relationships they have identified.
Teacher ediTion: examples from Unit 1
MP.7 Look for Structure Look for a Pattern Introduce the term simplify: to produce an equivalent fraction with lesser numerator and denominator. Students should complete Exercises 7–11 on Student Book page 5. Then ask them to cover the whole page to the right of 1 _ 3 .
• How many fifteenths are grouped together to make 1 _ 3 ? 5
• How can you find the number of thirds in 10 __ 15 ? Divide 10 and 15 by 5.
• How many twelfths are grouped together to make 1 _ 3 ? 4
• How can you find the number of thirds in 8 __ 12 ? Divide 8 and 12 by 4.
• How many ninths are grouped together to make 1 _ 3 ? 3
• How can you find the number of thirds in 6 _ 9 ? Divide 6 and 9 by 3.
Lesson 2
MP.7 Look for Structure Identify Relationships During the discussion, call attention to the ways in which the denominators in each pair of fractions are related.
For 3 _ 4 and 5 _ 8 ,
→ One denominator is a factor of the other (4 is a factor of 8).
→ The greater denominator, 8, is the least denominator that will work as the common denominator.
→ Using 8 as the common denominator requires us to rewrite only one of the fractions.
For 4 _ 5 and 5 _ 7 ,
→ 1 is the only number that is a factor of both denominators.
→ The product of 5 and 7 is the least denominator that will work as the common denominator.
For 7 _ 9 and 5 _ 6 ,
→ 3 is a factor of both denominators.
→ 18, which is less than the product of the denominators, will work as a common denominator.
Lesson 4
Mathematical Practice 7 is integrated into Unit 1 in the following ways:
Identify RelationshipsLook for a Pattern
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► Math and Bird HotelsHave you ever seen a birdhouse? Birdhouses offer birds a place to rest and keep their eggs safe from predators.
Purple martins are birds that nest in colonies.Purple martin birdhouses, like the one at the right, are sometimes called bird hotels.
Suppose that a fifth grade class has decided to build a two-story purple martin bird hotel. Each story of the hotel will have six identical compartments. One story is shown below.
The bird hotel will be made from wood, and each story will have the following characteristics.
→ The inside dimensions of each compartment measure 7 1 __
2 in. by 7 1 __
2 in. by 7 1 __
2 in.
→ The wood used for exterior walls is 5 __ 8 -in. thick.
→ The wood used for interior walls is 1 __ 4 -in. thick.
Calculate the length, width, and height of one story. Do not include a floor or ceiling in your calculations.
Name Date
Show your work.
1. length in.
2. width in.
3. height in.
24 1 __ 4
16 1 __ 2
7 1 __ 2
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► Math and Bird Hotels (continued)The bird hotel will have these additional characteristics.
→ Each story has a fl oor that creates an overhang of 1 inch in all directions.
→ The roof is fl at and creates an overhang of 1 inch in all directions.
→ The wood used for the fl oors and roof is 3 __ 4 -in. thick.
Calculate the total length, width, and height of the hotel. Include floors and a roof in your calculations.
Purple martins migrate great distances, spending winter in South America and summer in the United States and Canada. A diet of flying insects supplies purple martins with the energy they need to complete such long flights.
Suppose a purple martin migrates about 4,150 miles to South America each fall and about 4,150 miles back to North America each spring. Also suppose the purple martin performs this round trip once each year for three years.
7. At the Equator, the distance around Earth is about 24,900 miles. About how many times around Earth would the purple martin described above fly during its migrations?
Name Date
4. length in.
5. width in.
6. height in.
Show your work.
1 time
26 1 __ 4
18 1 __ 2
17 1 __ 4
30 UNIT 1 LESSON 13 Focus on Mathematical Practices
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STUDeNT eDITION: LeSSON 13, pAGeS 29–30
Mathematical practice 8 Look for and express regularity in repeated reasoning.
Students use repeated reasoning as they analyze patterns, relationships, and calculations to generalize methods, rules, and shortcuts. As they work to solve a problem, students maintain oversight of the process, while attending to the details. They continually evaluate the reasonableness of their intermediate results.
TeACHeR eDITION: examples from Unit 1
Mp.8 Use Repeated Reasoning Remind students that they found common denominators in Lesson 4 when they compared fractions. Explain that the strategies they used to rewrite fractions in that lesson can also be used to rewrite the fractions in an addition problem.
Lesson 7
Mp.8 Use Repeated Reasoning Generalize Summarize, or have a student summarize, a rule for comparing mixed numbers: If the whole number parts are different, the mixed number with the greater whole number part is greater. If the whole number parts are the same, the mixed number with the greater fraction part is greater. If you feel your students need practice, give them several pairs of mixed numbers to compare.
Lesson 9
Mathematical Practice 8 is integrated into Unit 1 in the following ways:
Generalize
Focus on Mathematical practices Unit 1 includes a special lesson that involves solving real world problems and incorporates all 8 Mathematical Practices. In this lesson, students use what they know about adding and subtracting fractions to compute the dimensions of a bird hotel.
Research & Math BackgroundContents Planning
Getting Ready to Teach Unit 1Learning Path in the Common Core StandardsIn this unit, students study fractions and mixed numbers. They find equivalent fractions, compare fractions, and add and subtract fractions and mixed numbers.
Students apply their understanding of fractions and fraction models to represent the addition and subtraction of fractions with unlike denominators as equivalent problems with like denominators. They make reasonable estimates of the sums and differences.
Visual models and real world situations are used throughout the unit to illustrate important fraction concepts.
Help Students Avoid Common ErrorsMath Expressions gives students opportunities to analyze and correct errors, explaining why the reasoning was flawed.
In this unit, we use Puzzled Penguin to show typical errors that students make. Students enjoy teaching Puzzled Penguin the correct way, and explaining why this way is correct and why the error is wrong. The following common errors are presented to students as letters from Puzzled Penguin and as problems in the Teacher Edition that were solved incorrectly by Puzzled Penguin.
→ Lesson 3: Generating an equivalent fraction by multiplying only one part of the fraction
→ Lesson 5: Interpreting a mixed number as a whole number times a fraction
→ Lesson 6: When ungrouping a mixed number to subtract, forgetting to reduce the whole number part by 1
→ Lesson 7: Adding fractions by adding numerators and adding denominators
→ Lesson 9: Adding mixed numbers by adding numerators and adding denominators; when subtracting mixed numbers, subtracting the lesser fraction from the greater fraction, even though the lesser fraction is in the minuend
→ Lesson 11: Not checking answers for reasonableness
In addition to Puzzled Penguin, there are other suggestions listed in the Teacher Edition to help you watch for situations that may lead to common errors. As a part of the Unit Test Teacher Edition pages, you will find a common error and prescription listed for each test item.
Math Expressions VOCABULARY
As you teach this unit, emphasize
understanding of these terms:
• unsimplify• n-split
See the Teacher Glossary
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from the Progressions for the Common Core state standards on nUmBer and oPerations—fraCtions
Unit fractions The goal is for
students to see unit fractions as the
basic building blocks of fractions,
in the same sense that the number
1 is the basic building block of the
whole numbers; just as every whole
number is obtained by combining
a sufficient number of 1s, every
fraction is obtained by combining a
sufficient number of unit fractions.
Build with Unit Fracti ons
Lesson
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Unit fractions The fraction bars on the MathBoard are used to discuss unit fractions. A unit fraction has the form 1 _ n , where n is the number of equal parts the whole is divided into. Students recall that a unit fraction represents one of those parts of a whole. For example, the unit fraction 1 _ 5 represents one of five equal parts of a whole.
The MathBoard fraction bars allow students to observe that unit fractions with greater denominators represent smaller parts of a whole. For example, 1 _ 5 is smaller than 1 _ 3 . Students can reason that this makes sense because the more parts the same whole is divided into, the smaller each part must be.
non-Unit fractions Fraction bars allow students to see how a whole and other non-unit fractions are built by combining (adding) unit fractions.
→ Any fraction that is not a unit fraction can be built by adding unit fractions. For example, 3 _ 5 = 1 _ 5 + 1 _ 5 + 1 _ 5 . This can also be expressed as 3 _ 5 = 3 × 1 _ 5 .
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→ The denominator of a fraction tells the number of unit fractions in the whole. For example, for 3 _ 5 , the whole is made up of five unit fractions (specifically, five fifths, or five 1 _ 5 s).
→ The numerator of a fraction tells the number of unit fractions in the fraction. For example, the fraction 3 _ 5 is made up of three unit fractions—in this case, three fifths, or three 1 _ 5 s.
Viewing non-unit fractions as sums of unit fractions helps students avoid common errors in adding and subtracting fractions (including adding numerators and denominators, not just numerators).
3 __ 7 + 2 __ 7 = 1 __ 7 + 1 __ 7 + 1 __ 7 + 1 __ 7 + 1 __ 7 = 5 __ 7
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Research & Math BackgroundContents Planning
Equivalent Fractions
Lessons
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Fraction Bars Students begin their work with equivalent fractions by looking at the portion of each fraction bar that is equivalent to 1 _ 2 . They consider what we must do both to the fraction-bar model for 1 _ 2 and to the numerical fraction 1 _ 2 to form equivalent fractions. For example, to go from the model for 1 _ 2 to the model for 3 _ 6 , we must divide each half into three equal
parts. (We say we must 3-split 1 _ 2 .) To get
from the numerical fraction 1 _ 2 to 3 _ 6 , we must multiply both the numerator and the denominator by 3.
Number Lines On a number line, students see that they can make equivalent fractions by dividing each interval into smaller intervals (that is, by dividing each unit fraction into smaller unit fractions). For example, by dividing each third into two equal intervals to make sixths, we can see that 2 _ 3 is equivalent to 4 _ 6 . Dividing each interval in two parts is mathematically equivalent to multiplying both the numerator and denominator of 2 _ 3 by 2.
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equivalent Fractions Students
can use area models and number
line diagrams to reason about
equivalence. They see that the
numerical process of multiplying
the numerator and denominator
of a fraction by the same number,
n, corresponds physically to
partitioning each unit fraction
piece into n smaller equal pieces.
The whole is then partitioned into
n times as many pieces, and there
are n times as many smaller unit
fraction pieces as in the original
fraction.
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We 2-split to make . 1 × 2 = 22 × 2 4
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We 3-split to make . 1 × 3 = 32 × 3 6
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= 12
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We 4-split to make . 1 × 4 = 42 × 4 8
510
510
12
= 12
We 5-split to make . 1 × 5 = 5 2 × 5 10
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Students also make equivalent fractions on the number line by grouping intervals to make larger intervals (in other words, by grouping unit fractions to make greater unit fractions). For example, making groups of 5 fifteenths makes thirds. The fraction 10 __ 15 becomes the equivalent fraction 2 _ 3 . This is equivalent to dividing the numerator and denominator by 5.
10 ÷ 5 ______ 15 ÷ 5 = 2 __ 3
In Math Expressions, we use simplify to refer to the process of creating an equivalent fraction by dividing both parts of a fraction by the same number. We use unsimplify to refer to the process of creating an equivalent fraction by multiplying both parts by the same number. For example, we can simplify 9 __ 12 by dividing both parts by 3 to get 3 _ 4 . We can unsimplify 2 _ 5 by multiplying both parts by 3 to get 6 __ 15 .
Multiplication Table Lesson 3 solidifies the role of the multiplier in generating equivalent fractions. Students learn how equivalent fractions can be seen in the multiplication table. We can choose any two rows of the table. If we consider the numbers in one row to be numerators and the corresponding numbers in the other row to be denominators then we can make a chain of equivalent fractions.
The multipliers needed to make each fraction from the first fraction are in the top row of the table. For example, to get 18 __ 30 from 3 _ 5 , we must use the multiplier 6, which is at the top of the column that contains both 18 and 30.
Using the multiplication table helps students answer questions like these: If I need a fraction equivalent to 4 _ 7 with a denominator of 56, what will the numerator be? If I need a fraction equivalent to 4 _ 7 with a numerator of 24, what will the denominator be?
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Compare Fractions
Lesson
4
In Lesson 4, students explore a variety of strategies for comparing fractions.
Like Denominators If two fractions have the same denominator, then they are made from the same-size unit fraction. The fraction with the greater numerator—that is, the fraction with the greater number of unit fractions—is visually larger and therefore the greater fraction.
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Like Numerators If two fractions have the same numerator, then they are made from the same number of unit fractions. The fraction with the lesser denominator—that is, the fraction made from the greater unit fractions—is visually larger and therefore the greater fraction.
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from the PRogRessioNs foR the CoMMoN CoRe state staNDaRDs oN NUMBeR aND oPeRatioNs—fRaCtioNs
Comparing fractions They see
that for fractions that have the
same denominator, the underlying
unit fractions are the same size,
so the fraction with the greater
numerator is greater because it
is made of more unit fractions.
Students also see that for unit
fractions, the one with the
larger denominator is smaller, by
reasoning, for example, that in
order for more (identical) pieces to
make the same whole, the pieces
must be smaller. From this they
reason that for fractions that have
the same numerator, the fraction
with the smaller denominator is
greater.
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Unlike Denominators To compare two fractions with different denominators, we can rewrite them as equivalent fractions with a common denominator. For example, to compare 5 _ 8 and 7 __ 12 , we can use the common denominator 24.
5 __ 8 = 5 × 3 _____
8 × 3 = 15 ___ 24
7 ___ 12
= 7 × 2 ______ 12 × 2
= 14 ___ 24
Because 15 __ 24 > 14 __ 24 , we know that 5 _ 8 > 7 __ 12 .
When finding a common denominator, students consider the following three cases; however, Lesson 4 emphasizes that we can always use the product of the denominators as the common denominator.
→ One denominator is a factor of the other. In this case, we can use the greater denominator as the common denominator. For example, for 3 _ 5 and 7 __ 10 , we can use 10 as the common denominator.
→ The denominators have no common factors except 1. In this case, we can use the product of the denominators as the common denominator. For example, for 4 _ 5 and 5 _ 7 , we can use 35 as the common denominator.
→ The denominators have a common factor greater than 1. In this case, we can find a common denominator that is less than the product of the denominators. For example, for 5 __ 12 and 4 _ 9 , we can use 36 as a common denominator.
Special Cases Students learn that in some special situations, we can compare fractions by using reasoning.
→ If both fractions are close to 1 _ 2 , we can compare both to 1 _ 2 . If one fraction is greater than 1 _ 2 and the other is less than 1 _ 2 , then the fraction greater than 1 _ 2 is greater. For example, because 5 _ 8 > 1 _ 2 and 2 _ 5 < 1 _ 2 , we can conclude that 5 _ 8 > 2 _ 5 .
→ If both fractions are close to 1 (and both are less than 1), we can compare the fractions to 1. The fraction closer to 1 is greater. For example, 5 _ 6 is 1 _ 6 away from 1. 6 _ 7 is 1 _ 7 away from 1. Because 1 _ 7 < 1 _ 6 , 6 _ 7 is closer to 1, so it is greater.
0 1–6
2–6
3–6
4–6
5–6
1
1–6
from 1
0 1–7
2–7
3–7
4–7
5–7
6–7
1
1–7
from 1
from the ProgreSSionS for the Common Core State StanDarDS on nUmBer anD oPerationS—fraCtionS
Using number Lines to
Compare As students move
towards thinking of fractions as
points on the number line, they
develop an understanding of order
in terms of position. Given two
fractions—thus two points on the
number line— the one to the left
is said to be smaller and the one to
the right is said to be larger. This
understanding of order as position
will become important in Grade 6
when students start working with
negative numbers.
UNIT 1 | Overview | 1EE
Research & Math BackgroundContents Planning
Fractions Greater Than 1 and Mixed Numbers
Lesson
5
Fractions Greater Than One The idea of building fractions from unit fractions is used to develop the ideas of fractions greater than 1 and mixed numbers. For example, the fraction 5 _ 4 is the sum of 5 fourths.
5 __ 4 = 1 __ 4 + 1 __ 4 + 1 __ 4 + 1 __ 4 + 1 __ 4
Students use a variety of representations to represent 5 _ 4 and show that it is greater than one whole.
5
4
5
4
Students can group unit fractions to show that 5 _ 4 is one whole ( 4 _ 4 ) and 1 _ 4 more.
1
4+ 1
4+ 1
4+ 1
4+ 1
4= 1 1
4
Convert Between Forms Students use their own methods to convert between mixed numbers and fractions. Many students will use some or all of the methods below.
2 3 __ 4 = 2 + 3 __ 4 = 1 + 1 + 3 __ 4 = 4 __ 4 + 4 __ 4 + 3 __ 4 = 11 ___ 4
Some students will see the shortcut of multiplying 2 × 4, to find that there are 8 fourths in 2, and then adding the 3 fourths.
To convert a fraction to a mixed number, students can reverse the thinking used above. Below is an example. Most students will not need to record all the steps.
17 ___ 5 = 5 __ 5 + 5 __ 5 + 5 __ 5 + 2 __ 5 = 1 + 1 + 1 + 2 __ 5 = 3 + 2 __ 5 = 3 2 __ 5
1FF | UNIT 1 | Overview
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Add and Subtract Like Mixed Numbers
Lesson
6
In Lesson 6, students add and subtract mixed numbers with like denominators. To add, most students will use one of the following methods:
→ Add whole number parts and fraction parts separately and regroup if needed.
Horizontally Vertically
1 2 __ 3 + 1 2 __
3 = (1 + 1) + ( 2 __
3 + 2 __
3 )
= 2 4 __ 3
= 3 1 __ 3
1 2 __ 3
+1 2 __ 3
_
2 4 __ 3
= 3 1 __ 3
→ Rewrite the mixed numbers as fractions and add.
1 2 __ 3 + 1 2 __
3 = 5 __
3 + 5 __
3 = 10 ___
3 = 3 1 __
3
To subtract, students are likely to use one of these methods:
→ Subtract the whole number parts and fraction parts separately, ungrouping first if needed.
6 6 __ 5
7 1 __ 5
- 2 4 __ 5
_
4 2 __ 5
→ Add on from the lesser number to the greater number.
1 __ 5 + 4 + 1 __ 5 = 4 2 __ 5
2 4 __ 5 to 3 to 7 to 7 1 __ 5
→ Rewrite the mixed numbers as fractions and subtract.
7 1 __ 5 - 2 4 _ 5 = 36 ___ 5 - 14 ___ 5 = 22 __ 5 = 4 2 __ 5
UNIT 1 | Overview | 1GG
Research & Math BackgroundContents Planning
Add and Subtract Unlike Fractions and Mixed Numbers
Lessons
7 8 9 10
Add Unlike Fractions In Lesson 7, students add numbers with unlike denominators. Fraction bars are used to illustrate why we must rewrite the fractions with a common denominator before adding. For example, the top bar below shows 1 _ 2 + 1 _ 3 , but we can’t tell what the total value is. The bottom bar shows that when we express each addend as a number of sixths, we can see that the sum is 5 _ 6 .
1–2
1–2
1–3
1–3
1–6
1–6
1–6
1–6
1–6
+
+
Subtract Unlike Fractions Students subtract unlike fractions in Lesson 8. Fraction bars are again used to illustrate why it is necessary to rewrite the fractions with a common denominator.
Sixths
Make . How can you subtract ?
Sixths
Change thirds into sixths and subtract.
56
56
-23
23
=56 -
46 =
16
Find Common Denominators Throughout Lessons 7 and 8, students use the strategies discussed in Lesson 4 to find common denominators. (See page 1EE for a list of these strategies.)
from the PRogReSSionS FoR the CoMMon CoRe StAte StAnDARDS on nUMBeR AnD oPeRAtionS—FRACtionS
Adding and Subtracting
Fractions Students express both
fractions in terms of a new
denominator. For example, in
calculating 2 _ 3 + 5 _ 4 , they reason that
if each third in 2 _ 3 is subdivided
into fourths, and if each fourth
in 5 _ 4 is subdivided into thirds, then
each fraction will be a sum of unit
fractions with denominator 3 × 4 =
4 × 3 = 12.
2 __ 3 + 5 __ 4 = 2 × 4 _____
3 × 4 + 5 × 3 _____
4 × 3 = 8 ___
12 + 15 ___
12 = 23 ___
12
In general two fractions can
be added by subdividing the
unit fractions in one using the
denominator of the other.
1HH | UNIT 1 | Overview
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Add and Subtract Unlike Mixed Numbers In Lessons 9 and 10, students add and subtract mixed numbers with unlike denominators. Such computations can be quite complex. They require finding equivalent fractions, adding or subtracting the whole numbers and fractions separately, and ungrouping if necessary for subtraction. Then two kinds of simplifying may be required: simplifying a fraction to the simplest form and changing a fraction greater than 1 to a mixed number, which must be added to the whole number. By sharing and discussing solution methods, students can develop effective and efficient strategies for doing these computations. The following discussion is from Lesson 9, page 69.
MATH TALKin ACTION
When presenting their solutions, pairs should describe each step, with other students asking questions or helping to clarify. Below is a discussion of Exercise 5.
Eric and Max, please explain how you solved Exercise 5.
Eric: First, we renamed the fractions so they had the same denominator. The denominators are 3 and 15. 3 is a factor of 15, so 15 is a common denominator. We renamed 1 _ 3 as 5 __ 15 .
4 1 __ 3
-2 7 ___ 15
_
= 4 5 ___ 15
= 2 7 __ 15
Max: We couldn’t subract 7 __ 15 from 5 __ 15 because 5 __ 15 is smaller, so we had to ungroup. The 4 becomes a 3 because I’m giving a 1 to the fifteenths. One is the same as 15 __ 15 . Adding 15 __ 15 to 5 __ 15 , I get 20 __ 15 .
3 20 ___ 15
4 1 __ 3 = 4 5 ___ 15
-2 7 ___ 15 = 2 7 ___ 15
Eric: Then we just subtracted. We subtracted the whole numbers first: 3 - 2 = 1. Then we subracted the fractions: 20 __ 15 - 7 __ 15 = 13 __ 15 .
3 20 ___ 15
4 1 __
3 = 4 5 ___ 15
-2 7 ___ 15 = 2 7 ___ 15
___
1 13 ___ 15
UNIT 1 | Overview | 1II
Research & Math BackgroundContents Planning
Estimation and Reasonable Answers
Lessons
11 12
In Lesson 11, students discuss strategies for mentally estimating sums and differences of fractions and mixed numbers and for determining whether answers are reasonable. These strategies include the following:
→ Using benchmarks of 0, 1 _ 2 , and 1: For example, consider 4 _ 9 + 5 _ 6 . Because 4 _ 9 is closer to 1 _ 2 than to 0 and 5 _ 6 is closer to 1 than to 1 _ 2 , we know 4 _ 9 + 5 _ 6 is close to 1 _ 2 + 1, or 1 1 _ 2 .
→ Rounding to the nearest whole number: For example, consider 2 1 _ 3 + 5 3 _ 4 . Because 2 1 _ 3 rounds to 2 and 5 3 _ 4 rounds to 6, the sum should be about 8.
→ Using number sense and reasoning: For example, consider the (incorrect) equation 5 _ 8 + 1 _ 6 = 6 __ 14 . We can reason that because one of the addends, 5 _ 8 , is more than 1 _ 2 , it is impossible for the sum to be less than 1 _ 2 . Since 6 __ 14 < 1 _ 2 , 6 __ 14 is not a reasonable answer.
In Lesson 12, students apply what they have learned throughout the unit to solve one-step and multistep word problems involving addition and subtraction of fractions and mixed numbers. They must also describe how they know their answer is reasonable.
4. At a pizza party, the Mehta family ate 1 3 _ 8 pizzas in all. They ate 9 __ 12 of a cheese pizza and some pepperoni pizza. How much pepperoni pizza did they eat?
Equation and answer:
Why is the answer reasonable?
Focus on Mathematical Practices
Lesson
13
The Standards for Mathematical Practice are included in every lesson of this unit. However, there is an additional lesson that focuses on all eight Mathematical Practices. In this lesson, students use what they know about adding and subtracting fractions to compute the dimensions of a bird hotel.
from the PRogRessions foR the CoMMon CoRe state standaRds on nUMBeR and oPeRations—fRaCtions
estimating answers Students make
sense of fractional quantities when
solving word problems, estimating
answers mentally to see if they
make sense.
9 __ 12 + p = 1 3 _ 8 ; 5 _ 8 pizzas
9 __ 12 is close to 1 and 5 _ 8 is close to 1 _ 2 , so the total
should be close to 1 1 _ 2 .
1JJ | UNIT 1 | Overview
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Math Talk Learning Community Research In the NSF research project that led to the development of Math Expressions, much work was done with helping teachers and students build learning communities within their classrooms. An important aspect of doing this is Math Talk. The researchers found three levels of Math Talk that go beyond the usual classroom routine of students simply solving problems and giving answers and the teacher asking questions and offering explanations. It is expected that at Grade 5, students will engage in talk at all levels.
Math Talk Level 1 A student briefly explains his or her thinking to others. The teacher helps students listen to and help others, models fuller explaining and questioning by others, and briefly probes and extends student's ideas.
Math Talk Level 2 A student gives a fuller explanation and answers questions from other students. The teacher helps students listen to and ask good questions, models full explaining and questioning (especially for new topics), and probes more deeply to help students compare and contrast methods.
Math Talk Level 3 The explaining student manages the questioning and justifying. Students assist each other in understanding and correcting errors and in explaining more fully. The teacher monitors and assists and extends only as needed.
Summary Math Talk is important not only for discussing solutions to story problems but also for any kind of mathematical thinking students do, such as deciding how to choose an operation to solve a problem or adding and subtracting fractions.
UNIT 1 | Overview | 1KK
The Learning Community
Learning Community—Best PracticesMATH TALK Aspire to make your classroom a place where all students listen to understand one another. Explain to students that this is different from just being quiet when someone else is talking. This involves thinking about what a person is saying so that you could explain it yourself or help them explain it more clearly. Also, students need to listen so that they can ask a question or help the explainer. Listening can also help them learn more about a concept.
Beginning the Year Setting Up a Learning Community
If students have used Math Expressions before, ask them to describe important aspects of a math class that uses Math Expressions. Include the following points if the students do not raise them. If students are new to Math Expressions, go over these structures to begin to create a Learning Community for the year.
Building Concepts We understand mathematical aspects of situations (we mathematize) by seeing and making math drawings to visualize the mathematics and relate these to our explanations.
MATH TALK Students explain their thinking in an instructional conversation focused on the math. Math Talk helps everyone understand better. The teacher monitors and extends student Math Talk as needed, helping students learn to talk directly to each other rather than to the teacher.
A key structure of Math Talk is called Solve and Discuss. The teacher selects several students to go to the board and solve a problem, using any method they choose. Students love solving at the board, and the teacher can easily see their solving process. The other students work at the same problem at their desks. Then the teacher asks the students at the board to explain their methods.
An explaining student relates his or her solution to a math drawing, asks if there are any questions, and responds to questions. Listeners are encouraged to ask questions when they do not understand and also to ask lead-in questions that focus on the mathematics that are key to understanding the solution to the problem. Students can also suggest edits to the explanation or solution. So this is actually a Solve, Explain, Question, and Justify structure called Solve and Discuss for short.
During Solve and Discuss, teachers can stand at the side or back of the classroom to help students interact more directly with each other. Teachers say that it is necessary for them to “bite their tongue” to keep from doing all of the talking; student voices and explanations will emerge if you wait. For new topics, teachers may need to model explaining so that students learn to use new vocabulary, but some students can explain even for a new topic.
Usually only two students will explain their solution during Solve and Discuss because listening to many similar explanations is not fruitful. It is better to go on to the next problem to engage students in a new situation to Solve and Discuss. If there are particularly interesting solutions or someone at the board needs a turn at explaining, more than two students should explain their solutions.
1LL | UNIT 1 | Beginning the Year
Learning Community—Best PracticesHelping Community Create a classroom where students are not competing, but desire to collaborate and help one another. Communicate often that your goal as a class is that everyone understands the math you are studying. Tell students that this will require everyone working together to help each other. Assign helping partners as needed.
Helping Community Everyone is a learner and a teacher and helps each other understand and explain. This is a safe community in which there is no making fun of anyone ever. A student can always ask for help, and it is brave to ask for help or say, I don’t understand. Everyone makes mistakes, and we thank people who make mistakes because it helps us all learn how to recognize and correct mistakes.
Quick Practice Quick Practice starts each lesson. These activities help everyone become fluent in core content. Student Leaders usually lead the Quick Practice.
Student Leaders Everyone is expected to be a leader in this class. Volunteers will lead Quick Practices at first, and eventually everyone will get a turn. Student Leaders also help their classmates understand or explain concepts and skills; everyone can be a Student Leader in class discussions or in small group or pair work.
In the first Quick Practice of Unit 1, students practice writing and comparing fractions. Six Student Leaders will lead the class in writing six fractions that are less than 1 _ 2 .
Posters The Grade 5 kit includes posters.
• Place Value Poster for reading and writing decimals and mixed decimals.
• Fraction Poster showing fraction models and operations with fractions.
• Geometry Poster showing the hierarchy of properties of two dimensional shapes.
UNIT 1 | Beginning the Year | 1MM
The Learning Community (continued)
MathBoards Students use a MathBoard as a tool for recording their thinking, relating their drawings to math language, and justifying their reasoning.
Whole
Halves
Thirds
Fourths
Fifths
Sevenths
Eighths
Ninths
Tenths
Sixths
Math Drawings These are drawings that focus on the mathematical aspects of a situation or of quantities. They may be generated by the student or teacher, or they may be research-based forms introduced in Math Expressions to help students understand and represent mathematical concepts, situations, and notation. Correct mathematical notation and vocabulary are always used in solutions and explanations, and these are related to the math drawings. But students also can use their own meaningful language to clarify concepts and make them memorable.
Mathematical Practices A Math Talk Learning Community often uses Mathematical Practices 1 through 7 in a Solve and Discuss of a problem. Mathematical Practice 8 often is used as students reason across different problems. Helping students consistently and clearly explain their reasoning, and relate different solutions for one problem or use the same solution across different problems, fosters all of the Mathematical Practices.
Learning Community—Best PracticesBuilding Concepts Students make math drawings to show their thinking. This supports understanding by the listeners and promotes meaning. This is very important for equity: less-advanced students and English learners are helped by the math drawing linked to the explanation by pointing.
Teaching NotesBasic Facts Fluency At this grade level, students should be able to recall multiplication and division facts. If some students are still struggling with basic multiplication and division, you can use the diagnostic quizzes in the Teacher’s Resource Book (M1 and M2) to assess their needs. Follow-up practice sheets are also provided. These practice sheets are structured so students can focus on a small group of multiplication and division facts on one sheet. There are also blank multiplication tables and scrambled multiplication tables to help students develop instant recall.
Grade Level Fluency In this grade, students work toward fluency with multidigit multiplication [CC.5.NBT.5]. Practice is provided in Student Book lessons, in Remembering pages, and in a special set of 12 Fluency Checks that are located in the Assessment Guide. A Fluency Check is referenced at the end of each Big Idea, beginning with Unit 4.
PATH toFLUENCY
1NN | UNIT 1 | Beginning the Year