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3.3: Evaluate, Simplify, and Translate Expressions (Part 1)

  2. Last updated
    Aug 14, 2020
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Learning Objectives
  • Evaluate algebraic expressions
  • Identify terms, coefficients, and like terms
  • Simplify expressions by combining like terms
  • Translate word phrases to algebraic expressions
Be prepared!

Before you get started, take this readiness quiz.

  1. Is n÷5 an expression or an equation? If you missed this problem, review Example 2.1.4.
  2. Simplify 45. If you missed this problem, review Example 2.1.6.
  3. Simplify 1+89. If you missed this problem, review Example 2.1.8.

Evaluate Algebraic Expressions

In the last section, we simplified expressions using the order of operations. In this section, we’ll evaluate expressions—again following the order of operations.

To evaluate an algebraic expression means to find the value of the expression when the variable is replaced by a given number. To evaluate an expression, we substitute the given number for the variable in the expression and then simplify the expression using the order of operations.

Example 3.3.1: evaluate

Evaluate x+7 when

  1. x=3
  2. x=12

Solution

  1. To evaluate, substitute 3 for x in the expression, and then simplify.
  x+7
Substitute. 3+7
Add. 10

When x=3, the expression x+7 has a value of 10.

  1. To evaluate, substitute 12 for x in the expression, and then simplify.
  x+7
Substitute. 12+7
Add. 19

When x=12, the expression x+7 has a value of 19. Notice that we got different results for parts (a) and (b) even though we started with the same expression. This is because the values used for x were different. When we evaluate an expression, the value varies depending on the value used for the variable.

exercise 3.3.1

Evaluate: y+4 when

  1. y=6
  2. y=15
Answer a

10

Answer b

19

exercise 3.3.2

Evaluate: a5 when

  1. a=9
  2. a=17
Answer a

4

Answer b

12

Example 3.3.2

Evaluate 9x2, when

  1. x=5
  2. x=1

Solution

Remember ab means a times b, so 9x means 9 times x.

  1. To evaluate the expression when x=5, we substitute 5 for x, and then simplify.
  9x2
Substitute 5 for x. 952
Multiply. 452
Subtract. 43
  1. To evaluate the expression when x=1, we substitute 1 for x, and then simplify.
  9x2
Substitute 1 for x. 912
Multiply. 92
Subtract. 7

Notice that in part (a) that we wrote 95 and in part (b) we wrote 9(1). Both the dot and the parentheses tell us to multiply.

exercise 3.3.3

Evaluate: 8x3, when

  1. x=2
  2. x=1
Answer a

13

Answer b

5

exercise 3.3.4

Evaluate: 4y4, when

  1. y=3
  2. y=5
Answer a

8

Answer b

16

Example 3.3.3: evaluate

Evaluate x2 when x=10.

Solution

We substitute 10 for x, and then simplify the expression.

  x2
Substitute 10 for x. 102
Use the definition of exponent. 1010
Multiply 100

When x=10, the expression x2 has a value of 100.

exercise 3.3.5

Evaluate: x2 when x=8.

Answer

64

exercise 3.3.6

Evaluate: x3 when x=6.

Answer

216

Example 3.3.4: evaluate

Evaluate 2x when x=5.

Solution

In this expression, the variable is an exponent.

  2x
Substitute 5 for x. 25
Use the definition of exponent. 22222
Multiply 32

When x=5, the expression 2x has a value of 32.

exercise 3.3.7

Evaluate: 2x when x=6.

Answer

64

exercise 3.3.8

Evaluate: 3x when x=4.

Answer

81

Example 3.3.5: evaluate

Evaluate 3x+4y6 when x=10 and y=2.

Solution

This expression contains two variables, so we must make two substitutions.

  3x+4y6
Substitute 10 for x and 2 for y. 3(10)+4(2)6
Multiply. 30+86
Add and subtract left to right. 32

When x=10 and y=2, the expression 3x+4y6 has a value of 32.

exercise 3.3.9

Evaluate: 2x+5y4 when x=11 and y=3

Answer

33

exercise 3.3.10

Evaluate: 5x2y9 when x=7 and y=8

Answer

10

Example 3.3.6: evaluate

Evaluate 2x2+3x+8 when x=4.

Solution

We need to be careful when an expression has a variable with an exponent. In this expression, 2x2 means 2xx and is different from the expression (2x)2, which means 2x2x.

  2x2+3x+8
Substitute 4 for each x. 2(4)2+3(4)+8
Simplify 42. 2(16)+3(4)+8
Multiply. 32+12+8
Add. 52
exercise 3.3.11

Evaluate: 3x2+4x+1 when x=3.

Answer

40

exercise 3.3.12

Evaluate: 6x24x7 when x=2.

Answer

9

Identify Terms, Coefficients, and Like Terms

Algebraic expressions are made up of terms. A term is a constant or the product of a constant and one or more variables. Some examples of terms are 7, y, 5x2, 9a, and 13xy.

The constant that multiplies the variable(s) in a term is called the coefficient. We can think of the coefficient as the number in front of the variable. The coefficient of the term 3x is 3. When we write x, the coefficient is 1, since x=1x. Table 3.3.1 gives the coefficients for each of the terms in the left column.

Table 3.3.1
Term Coefficient
7 7
9a 9
y 1
5x2 5

An algebraic expression may consist of one or more terms added or subtracted. In this chapter, we will only work with terms that are added together. Table 3.3.2 gives some examples of algebraic expressions with various numbers of terms. Notice that we include the operation before a term with it.

Table 3.3.2
Expression Terms
7 7
y y
x + 7 x, 7
2x + 7y + 4 2x, 7y, 4
3x2 + 4x2 + 5y + 3 3x2, 4x2, 5y, 3
Example 3.3.7:

Identify each term in the expression 9b+15x2+a+6. Then identify the coefficient of each term.

Solution

The expression has four terms. They are 9b, 15x2, a, and 6.

The coefficient of 9b is 9.

The coefficient of 15x2 is 15.

Remember that if no number is written before a variable, the coefficient is 1. So the coefficient of a is 1.

The coefficient of a constant is the constant, so the coefficient of 6 is 6.

exercise 3.3.13

Identify all terms in the given expression, and their coefficients: 4x+3b+2

Answer

The terms are 4x,3b, and 2. The coefficients are 4,3, and 2.

exercise 3.3.14

Identify all terms in the given expression, and their coefficients: 9a+13a2+a3

Answer

The terms are 9a,13a2, and a3, The coefficients are 9,13, and 1.

Some terms share common traits. Look at the following terms. Which ones seem to have traits in common?

5x,7,n2,4,3x,9n2

Which of these terms are like terms?

  • The terms 7 and 4 are both constant terms.
  • The terms 5x and 3x are both terms with x.
  • The terms n2 and 9n2 both have n2.

Terms are called like terms if they have the same variables and exponents. All constant terms are also like terms. So among the terms 5x,7,n2,4,3x,9n2,7 and 4 are like terms, 5x and 3x are like terms, and n2 and 9n2 are like terms.

Definition: Like terms

Terms that are either constants or have the same variables with the same exponents are like terms.

Example 3.3.8: identify

Identify the like terms:

  1. y3,7x2,14,23,4y3,9x,5x2
  2. 4x2+2x+5x2+6x+40x+8xy

Solution

  1. y3,7x2,14,23,4y3,9x,5x2

Look at the variables and exponents. The expression contains y3,x2,x, and constants. The terms y3 and 4y3 are like terms because they both have y3. The terms 7x2 and 5x2 are like terms because they both have x2. The terms 14 and 23 are like terms because they are both constants. The term 9x does not have any like terms in this list since no other terms have the variable x raised to the power of 1.

  1. 4x2+2x+5x2+6x+40x+8xy

Look at the variables and exponents. The expression contains the terms 4x2,2x,5x2,6x,40x, and 8xy The terms 4x2 and 5x2 are like terms because they both have x2. The terms 2x,6x, and 40x are like terms because they all have x. The term 8xy has no like terms in the given expression because no other terms contain the two variables xy.

exercise 3.3.15

Identify the like terms in the list or the expression: 9,2x3,y2,8x3,15,9y,11y2

Answer

9,15; 2x3 and 8x3, y2, and 11y2

exercise 3.3.16

Identify the like terms in the list or the expression: 4x3+8x2+19+3x2+24+6x3

Answer

4x3 and 6x3; 8x2 and 3x2; 19 and 24

Simplify Expressions by Combining Like Terms

We can simplify an expression by combining the like terms. What do you think 3x+6x would simplify to? If you thought 9x, you would be right!

We can see why this works by writing both terms as addition problems.

CNX_BMath_Figure_02_02_001_img.jpg

Add the coefficients and keep the same variable. It doesn’t matter what x is. If you have 3 of something and add 6 more of the same thing, the result is 9 of them. For example, 3 oranges plus 6 oranges is 9 oranges. We will discuss the mathematical properties behind this later.

The expression 3x+6x has only two terms. When an expression contains more terms, it may be helpful to rearrange the terms so that like terms are together. The Commutative Property of Addition says that we can change the order of addends without changing the sum. So we could rearrange the following expression before combining like terms.

CNX_BMath_Figure_02_02_015_img.jpg

Now it is easier to see the like terms to be combined.

HOW TO: COMBINE LIKE TERMS

Step 1. Identify like terms.

Step 2. Rearrange the expression so like terms are together.

Step 3. Add the coefficients of the like terms.

Example 3.3.9: simplify

Simplify the expression: 3x+7+4x+5.

Solution

  3x+7+4x+5
Identify the like terms 3x+7+4x+5
Rearrange the expression, so the like terms are together. 3x+4x+7+5
Add the coefficients of the like terms. 7x+12
The original expression is simplified to... 7x+12
exercise 3.3.17

Simplify: 7x+9+9x+8

Answer

16x+17

exercise 3.3.18

Simplify: 5y+2+8y+4y+5

Answer

17y+7

Example 3.3.10: simplify

Simplify the expression: 7x2+8x+x2+4x.

Solution

  7x2+8x+x2+4x
Identify the like terms. 7x2+8x+x2+4x
Rearrange the expression so like terms are together. 7x2+x2+8x+4x
Add the coefficients of the like terms. 8x2+12x

These are not like terms and cannot be combined. So 8x2+12x is in simplest form.

exercise 3.3.19

Simplify: 3x2+9x+x2+5x

Answer

4x2+14x

exercise 3.3.20

Simplify: 11y2+8y+y2+7y

Answer

12y2+15y

Contributors and Attributions

  • Lynn Marecek (Santa Ana College) and MaryAnne Anthony-Smith (formerly of Santa Ana College). This content produced by OpenStax and is licensed under a Creative Commons Attribution License 4.0 license.

This page titled 3.3: Evaluate, Simplify, and Translate Expressions (Part 1) is shared under a not declared license and was authored, remixed, and/or curated by OpenStax.

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