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6.04 One-step equations with multiplication and division

One-step equations with multiplication and division

Just like we saw with addition and subtraction, multiplication and division are also inverse operations. For example, multiplying a number by two is the opposite of dividing it by two.

Looking at a balance scale model again, we can see how we can multiply or divide by the same number on both sides of an equation to keep it balanced.

An image showing two balanced scales with tiles on it. Ask your teacher for more information.

Multiplication property of equality: Multiplying each side of an equation by the same number produces an equivalent equation. Example:

\begin{aligned}&\text{If } &x &= 3 \\ &\text{Then } &x\cdot{2} &= 3\cdot{2}\end{aligned}

We can visualize this with a scale.

A scale with one positive x tile on the left side and three positive 1 tiles on the right side. Ask your teacher for more information.

The scale tells us that x=3. We can double the values on both sides and the scale will still be balanced.

A scale with two positive x tiles on the left side and six positive 1 tiles on the right side. Ask your teacher for more information.

We multiplied the tiles on both sides of the scale by 2 and it is still balanced. We could have also multiplied both sides of the original scale by 3 to create 3 equal groups on each side of the balance and it would still be balanced.

A scale with three positive x tiles on the left side and nine positive 1 tiles on the right side. Ask your teacher for more information.

If we treat each side of the scale like a group that aligns with the other side, we can keep applying the multiplication property of equality.

Division property of equality: Dividing each side of an equation by the same number produces an equivalent equation. Example:

\begin{aligned}&\text{If } &4x &= 8 \\ &\text{Then } &\dfrac{4x}{4} &= \dfrac{8}{4}\end{aligned}

We can visualize this with a scale.

A scale with four positive x tiles on the left side and eight positive 1 tiles on the right side. Ask your teacher for more information.

Notice that the groups on the left and right align where every 2x aligns with 4 unit tiles. We can divide both sides by 2 (removing half of the tiles) and the scale will still be balanced.

A scale with two positive x tiles on the left side and four positive 1 tiles on the right side. Ask your teacher for more information.

We can also divide both sides of the original scale by 4, since we can see there are 4 groupings where every x tile is equal to 2 unit tiles.

A scale with one positive x tile on the left side and two positive 1 tiles on the right side. Ask your teacher for more information.

By dividing both sides of the scale by the same amount, we ensure that the left and right side of the scale are still the same size and weight to keep the scale balanced.

When we use these properties with specific numbers to eliminate them on one side of the equation, we are applying the multiplicative inverse and identity properties.

For example, with the equation 8x=30 we want to isolate x which requires getting rid of the coefficient 8. To do this we can use the inverse operation of dividing by 8.

\dfrac{8x}{8}=\dfrac{30}{8}

This can also be written as multiplication: \dfrac{1}{8} \cdot 8x=\dfrac{1}{8}\cdot 30

This allows us to see the multiplicative inverse in action: 1\cdot x=\dfrac{1}{8}\cdot 30

Now applying the multiplicative identity: x=\dfrac{1}{8}\cdot 30

Then we can simplify the right side of the equation: x=\dfrac{30}{8}=\dfrac{15}{4}

We don't always write out all of these steps, but it is still important to know what is happening algebraically.

Examples

Example 1

Scale 1 is balanced.

Scale 1:

A scale with one positive x tiles on the left side and three positive 1 tiles on the right side. Ask your teacher for more information.

Scale 2:

A scale with one positive x tiles on the left side and a question mark on the right side. Ask your teacher for more information.

Which of the following options could go in place of the question mark to balance scale 2?

A
A positive x tile.
B
A positive 1 tile.
C
Three positive 1 tiles.
D
Three rows with three columns of  positive 1 tiles.
Worked Solution
Create a strategy

From Scale 1, we can say that 1 positive x tile is equivalent to 3 positive 1 tiles or simply x=3.

Apply the idea
We must add three +1 tiles on the right side of the scale for every new positive tile on the left side. So, we need to add a total of six +1 tiles to the right side of scale 1.

We need 9 positive 1 tiles in place of the question mark to balance scale 2, option D.

Reflect and check

We can write this algebraically as:

\displaystyle x\displaystyle =\displaystyle 3Write the equation
\displaystyle 3x\displaystyle =\displaystyle 3 \cdot 3Multiply both sides by 3
\displaystyle 3x\displaystyle =\displaystyle 9Evaluate the multiplication

Example 2

Solve 3x=18

Worked Solution
Create a strategy

To undo multiplication, we can divide both sides of the equation.

Apply the idea
\displaystyle 3x\displaystyle =\displaystyle 18Write the original equation
\displaystyle \dfrac{3x}{3}\displaystyle =\displaystyle \dfrac{18}{3}Divide both sides by 3
\displaystyle x\displaystyle =\displaystyle 6Evaluate the division

Example 3

Solve: \dfrac{x}{8}=6

Worked Solution
Create a strategy

To undo division, we can multiply both sides of the equation.

Apply the idea
\displaystyle \dfrac{x}{8}\displaystyle =\displaystyle 6Write the original equation
\displaystyle \dfrac{x}{8}\cdot8\displaystyle =\displaystyle 6\cdot8Multiply both sides by 8
\displaystyle x\displaystyle =\displaystyle 48Evaluate the multiplication

Example 4

5 is a solution to the equation 8x=40.

a

Verify using substitution.

Worked Solution
Create a strategy

Substitute 5 into the equation. The left side of the equation should be equal to the right side if 5 is a solution.

Apply the idea
\displaystyle 8\left(5\right)\displaystyle =\displaystyle 40Substitute x=5
\displaystyle 40\displaystyle =\displaystyle 40Evaluate the multiplication

The left side of the equation is equal to the right side of the equation, verifying that 5 is a solution.

b

Verify using a model.

Worked Solution
Create a strategy

Represent the equation using algebra tiles on a scale. Make the left side of the scale to have the same number of unit tiles as the right side by replacing the variable tile with the appropriate tiles.

Apply the idea

The equation 8x=40 can be represented by:

A scale with eight positive x tiles on the left side and forty positive 1 tiles on the right side. Ask your teacher for more information.

The given solution if 5, so we replace each variable tile with 5 unit tiles. Notice that the variable tile is positive, so the resulting 5 unit tiles are positive.

A scale with forty positive 1 tiles on the left side and forty positive 1 tiles on the right side. Ask your teacher for more information.

Both sides of the scale now have 40 positive unit tiles, verifying that 5 is a solution to the equation.

Example 5

At a beach fruit stand, fresh squeezed juice is sold at \$ 6 per quart. You and your friends spent a total of \$ 84 on quarts of juice. Write an equation that shows the relationship between the total cost and the number of quarts of juice purchased.

Worked Solution
Create a strategy

The number of quarts of juice purchased is the unknown value.

Apply the idea

Let q represent the number of quarts of juice purchased.

6q=84

Example 6

Write a situation that could represent the equation \dfrac{x}{4}=52.

Worked Solution
Create a strategy

Think of a situation where there is an unknown value, x, divided into 4 equal sized groups and each group is size 52.

Apply the idea

At a craft store, you buy 4 packs of markers. Each pack contains the same number of markers. In total, you have 52 markers. Write an equation that shows the relationship between the number of markers in a pack and the total number of markers you bought.

Idea summary
Multiplication property of equality\text{If } a=b \text{ then } a\cdot c=b \cdot c
Division property of equality\text{If } a=b, \text{ and } c \neq 0, \text{ then } \dfrac{a}{c}=\dfrac{b}{c}
Inverse property of multiplicationa \cdot \dfrac{1}{a}=1 \text{ and } \dfrac{1}{a} \cdot a=1
Identity property of multiplicationa \cdot 1=a \text{ and } 1 \cdot a = a
Substitution property\text{If } {a=b} \text{, then } b \text{ can be substituted for } a \text{ in any expression,}\\\text{equation, or inequality.}

Outcomes

6.PFA.3

The student will write and solve one-step linear equations in one variable, including contextual problems that require the solution of a one-step linear equation in one variable.

6.PFA.3b

Represent and solve one-step linear equations in one variable, using a variety of concrete manipulatives and pictorial representations (e.g., colored chips, algebra tiles, weights on a balance scale).

6.PFA.3c

Apply properties of real numbers and properties of equality to solve a one-step equation in one variable. Coefficients are limited to integers and unit fractions. Numeric terms are limited to integers.

6.PFA.3d

Confirm solutions to one-step linear equations in one variable using a variety of concrete manipulatives and pictorial representations (e.g., colored chips, algebra tiles, weights on a balance scale).

6.PFA.3e

Write a one-step linear equation in one variable to represent a verbal situation, including those in context.

6.PFA.3f

Create a verbal situation in context given a one-step linear equation in one variable.

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