Download Grade 5 Algebraic Thinking

Algebra and
Operational
Thinking
In Grade 5
Overview
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5th Grade Content is preparation for Expressions
and Equations
Students begin working more formally with
expressions (5.OA.1 and 5.OA.2)
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Exploratory rather than for attaining mastery
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Write expressions
Evaluate and Interpret Expressions
Should be no more complex than expressions using
associative and distributive properties
Students prepare for studying proportional
relationships and functions in middle school
(5.OA.3)
Progression – 5.OA.1 and 5.OA.2
4th
5th
6th
•4.OA.1 Interpret a multiplication equation as a comparison, e.g., interpret 35=5x7 as a
statement that 35 is 5 times as many as 7 and 7 times as many as 5. Represent verbal
statements of multiplicative comparisons as multiplication equations.
•5.OA.1 Use parentheses, brackets, or braces in numerical expressions, and evaluate
expressions with these symbols.
•5.OA.2 Write simple expressions that record calculations with numbers, and interpret
numerical expressions without evaluating them.
•6.EE.5 Understand solving an equation or inequality as a process of answering a
question: which values from a specified set, if any, make the equation or inequality
true? Use substitution to determine whether a given number in a specified set makes
an equation or inequality true
Progression- 5.OA.3
4th
5th
6th
•4.OA.5 Generate a number or shape pattern that follows a given rule. Identify apparent
features of the pattern that were not explicit in the rule itself.
•5.OA.3 Generate two numerical patterns using two given rules. Identify apparent relationships
between corresponding terms from the two patterns, and graph the ordered pairs on a
coordinate plane.
•6.EE.9 Use variables to represent two quantities in a real-world problem that change in
relationship to one another; write an equation to express one quantity, thought of as the
dependent variable, in terms of the other quantity, thought of as the independent variable.
Analyze the relationship between the dependent and independent variables using graphs
and tables, and relate these to the equation.
5.OA.1
Use
parentheses, brackets, or
braces in numerical
expressions, and evaluate
expressions with these symbols.
Instructional Strategies
 start
with expressions that do not involve
any grouping symbols and have two
different operations
Ex: 4 X 5 + 7
 switch the operations around and discuss
why the solutions are different
Ex: 4 X 5 + 7 and 4 + 5 x 7
PEMDAS
 Introduce
the rules that must be followed,
noting that multiplication and division, as well
as addition and subtraction should be solved
left to right
 PEMDAS
 P = Parenthesis
 E= exponents
 MD= multiplication and division (whichever is
first, from left to right)
 AS= addition and subtraction (whichever is
first, from left to right)

http://www.amathsdictionaryforkids.com/dictionary.html
Strategies
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Have students place parentheses around the
multiplication or division part in the expression and
discuss the similarities and differences
After students have solved multiple expressions
without grouping symbols begin presenting
problems with parentheses, then with brackets
and/or braces
Give students an expression and solution and they
must fill in the appropriate operations in order to
get the given solution.
Ex: 7 _ 8 _ 3 _ 2=17
More complex you could ask them to insert
parentheses, brackets, or braces
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Give students a solution and they must come up
with the expression
Ex: I wrote an equation using parentheses and all
four operations with an answer of 25. What might
the equation be?
Write a matching story to fit the expression. This will
provide insight to whether or not they fully
understand the order of operations.
Have students solve expressions using a calculator
and have them decide what operation the
calculator did first in order to get the same answer
Common Misconceptions with
5.OA.1
 Students
may believe the order in which a
problem with mixed operations is written is
the order to solve the problem.
 Allow students to use calculators to
determine the value of the expression,
and then discuss the order the calculator
used to evaluate the expression.

Do this with four-function and scientific calculators
Misconceptions about
PE MD AS
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These mnemonics Do not replace the need to
understand the meaning of the order. Students
continue to do poorly on order of operations items
on high-stakes assessments, and this is due to a
lack of understanding. What part of the order of
operations is due to convention, it is largely due to
the meaning of the operations. Because
Multiplication represents repeated addition, It
must be figured first before adding on more.
Because exponents represent repeated
multiplication these multiplications must be
considered before multiplying or adding.
Misconceptions about
PE MD AS Continued

A common misconception with exponents is
to think of the two values as factors so 5 to the
3rd is thought of as 5×3 rather than correct
equivalent expression of 5×5×5 this is further
problematic when students hear things like it is
5 three times since the word times indicates
Multiplication. Avoid confusing language,
and spend significant time having students
state and write Equivalent expressions. When
experiencing difficulty with exponents,
students should write or include parentheses
to indicate explicit groupings.
5.OA.2
 Write
simple expressions that record
calculations with numbers, and interpret
numerical expressions without evaluating
them.
Student Thinking
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Students will understand that the word “then”
implies one operation happens after another
and parentheses are used to indicate the
order of operations. Example: “Add 8 and 7,
then multiply by 2” can be written as (8 + 7) x
2.
http://www.youtube.com/watch?v=swHuC9o
JVZo
Students will understand how to write a realworld problem as an expression.
Real World Application
 Students
will generate expressions
for word problems.
Edwin buys school supplies for the beginning of the
school year. On his first trip to the store he purchases
10 pencils. Edwin realizes he needs to make a second
trip to the store to purchase 20 more. Every year for
he last 6 years he has followed this pattern. Write an
expression that matches Edwin’s story.
Student Thinking Cont.
 Students
will recognize that 3 × (18,932 +
921) is three times as large as the sum of
18,932 + 921, without having to solve.
 Students
will make the connection that
3(18,932 + 921) is the same thing as 3 x (18,
932 + 921).
Teaching Approaches
 Visual
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Models 4 x (9 +2)
Set model
Area model
Teaching Approaches
 Creating
problem context for a given
expression
Your turn! Heads together, create a word
problem that would match the following
expression; 8 x (3 + 5)
Misconceptions
 The
need of grouping symbols
 Expression vs. Equation
Literature Connections
 Alexander,
Sunday
Who Used to Be Rich Last
Judith Viorst
 The
Grapes of Math
Greg Tang
Games

http://illuminations.nctm.org/ActivityDetail.aspx?ID=173
5.OA.3
Analyze patterns and relationships
 CCSS.Math.Content.5.OA.B.3 Generate two numerical patterns using two given rules. Identify apparent
relationships between corresponding terms. Form ordered pairs consisting of corresponding terms from
the two patterns, and graph the ordered pairs on a coordinate plane. For example, given the rule “Add 3”
and the starting number 0, and given the rule “Add 6” and the starting number 0, generate terms in the
resulting sequences, and observe that the terms in one sequence are twice the corresponding terms in
the other sequence. Explain informally why this is so.
Standards for Mathematical Practices (MP) to be emphasized:
 MP.2. Reason abstractly and quantitatively.
 MP.7. Look for and make use of structure.
Patterns, Functions, Algebra
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Patterns are key factors in understanding mathematical
concepts. The ability to create, recognize, and extend
patterns is essential for making generations, seeing
relationships, and the order/logic of mathematics.
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Students investigate numerical and geometric patterns;
describing them verbally; representing them in tables and
graphically.
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Students can make predictions, generalizations, and
explore properties of our number system, eventually
learning about various uses of variables and how to solve
equations.
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Then students should be able to understand the three
goals in functions, tables, formulas, and graphs.
Turning on the Common Core

Students extend their Grade 4 pattern work by working briefly with two
numerical patterns that can be related and examining these relationships within
sequences of ordered pairs and in the graphs in the first quadrant of the
coordinate plane. 5.OA.3 This work prepares students for studying proportional
relationships and functions in middle school.
An example of a pattern might be:
Students use a table for recording the terms of the pattern and the number of stars, and extend
the pattern.
Number
of Stars
2
7
12
17
22
27
Examples
 Suppose
you fold a piece of paper in half,
and then in half again, and again, until
you make six folds. When you open it up,
how many sections will there be?
 Suppose you draw ten dots on a circle. If
you draw lines connecting every dot to
every other dot, how many lines will you
draw?
Function Tables
1. ‘The Fly on the Ceiling’ draw a simple picture that can be formed with
straight lines connecting points on a coordinate grid. Use at least 8 points but
no more than 10 points.
2.Record the ordered pairs you plotted in the order in which you connected
them.
3. Next, double each number of the original pair and plot the ordered
number pairs on a second grid. Connect the points in the same order that
you plot them.
Challenge: What would happen if you:
-doubled only the first number of each original ordered pair?
- doubled only the second number of each original ordered pair?
Misconceptions
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Engage in pattern work without developing any
algebraic thinking.
Students often reverse the points when plotting them
on a coordinate plane.
In graphing a function, the function rule does not
need to be fully understood.
In generating a number pattern with 2 rules, stop
after the first rule.
http://learnzillion.com/lessons/797-generate-a-pattern-sequence-using-a-tchart
Teaching Considerations
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Functions can be represented in many ways.
Generalization of patterns should be realized by students.
Context helps student make sense of what changes in a
function. Example: Brian is trying to make money by
selling hot dogs from a cart during ball games. He pays
the cart owner $35 each time he uses the cart. He sells
hot dogs for $1.25 each. His costs for the hot dogs and
condiments etc. are about 60 cents per hot dog on
average. The profit from a single hot dog is 65 cents.
Verbal Description is the functional language.
Symbols are used to express a function as an equation.
Tables provide a concise way to look at recursive and
explicit rules.
Graphical representation allows one to see “at a glance”
relationships and adds understanding to context.
Algebraic Vocabulary for
Communicating Mathematically
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Independent variable is the input or whatever value is used to
find another value.
Dependent variable is the number of objects needed—the
output or whatever value one gets from using the
independent variable.
Discrete relates to graphical representations and whether the
points plotted on a graph should be connected or not. When
isolated or selected values are the only ones appropriate for
the context, the function is discrete.
Continuous relates to the connected points on a graph.
Domain of a function comprises the possible values for the
independent variable.
Range is the corresponding possible values for the dependent
variable.
References
 Source:
Utah Education Network
http://www.uen.org/core/math/downloads/5OA
2.pdf
 Marilyn Burns, About Teaching Mathematics
 NCTM
 K-5 Teaching Resources
 Turning on the Common Core
 University of Arizona Progression documents
 Zimba chart
 Van De Walle , Elementary and Middle School
Mathematics Teaching Developmentally
Feedback
 What
part of the lesson were you most
engaged in?
 Would you have sequenced the lesson
the same or different?
 Is there anything you would have
included that we didn’t?
Lesson Agenda
 Read
Aloud
 Discussion
 Introductory expressions
 Discuss solutions
 Order of Operations
 PEMDAS (Graphic Organizer)
 Order of Operations song/TPR
 Hopscotch
 Journal page
 Exit Ticket
Trailer
 http://www.wbrschools.net/technology/c
trailers/orderofoperations%20g7gle3%20g
8gle35%20g9%20gle8.wmv
Guiding Question
 How
does the punctuation affect the
meaning?
Lesson Objective: Students will be able to
explore the order of operations by a read
aloud, class discussion, and engaging
activities.
Solve these two problems:
5x3+6=
5+3x6=
 Discuss
 Does
why the values are different?
the order of operations effect the
solution?
Exit Ticket
 Three
students evaluated the numerical
expression 7 + (8-3) X 2. Tom said the
answer was 24. Nicole said the answer
was 17. Sam said the answer was 19
Who was correct? Why? Explain your
thinking.