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5.03 Find part or whole measures with ratios

Lesson

Introduction

We previously learned how to write  equivalent and simplified ratios  . We can apply these to finding part or whole measures of quantities using ratios. This is useful for when we want to find an unknown value that is in a ratio with a known ratio.

Part to whole ratios

Consider a bag containing 56 red and blue marbles where the ratio of red marbles to blue marbles is 3:5.

How many red marbles are there? How many blue marbles are there?

To find the number of red and blue marbles we would normally use equivalent ratios by increasing or decreasing the ratio by some multiple. However, in this case, we only know the total number of marbles so this method won't work. So what do we do?

To solve our problem we can make the total number of marbles a component in our ratio. To do this we need to know how many ratio parts correspond to the total number of marbles. Since there are 3 parts red marbles and 5 parts blue marbles, the total number of marbles is simply 3+5=8 parts.

Taking this information, our ratio of red to blue to the total number of marbles is written 3:5:8.

Now we can use equivalent ratios to solve our problem.

Since we get 56 from 8 by increasing by a multiple of 7, we can find the number of red and blue marbles by increasing their ratio parts by the same multiple.\begin{array}{c} &\text{Red} &\text{to} &\text{Blue} &\text{to} &\text{Total} \\ &3 &: &5 &: &8 \\ \\ &\times 7 & &\times 7 & &\times 7 \\ \\ &21 &: &35 &: &56 \end{array}

Using the equivalent ratio we find that there are 21 red marbles and 35 blue marbles.

We used the ratio 3:5:8 to represent the ratio of red to blue to the total number of marbles. This is an example of a part to whole ratio. A part to whole ratio is a ratio that shows the ratio of one component compared to the whole and is useful when considering what fraction of the total represents that component.

For example, we can write the part to whole ratio of blue marbles to the total as 5:8 which is equivalent to saying that \dfrac{5}{8} of the marbles are blue. This can then be used to find the number of blue marbles from the total with the calculation:

\text{Number of blue marbles}=56 \times \dfrac{5}{8}=35

This is equivalent to finding the number of marbles in one part, that is we divide the total, 56, by 8, and then multiplying by 5 to find the number of marbles in 5 parts. This is known as the unitary method.

\text{Number of blue marbles}=\dfrac{56}{8} \times 5=35

Notice that the only difference is which number we divide by 8.

We can use the ratio 3:8 to perform a similar calculation to find the number of red marbles.

A part to whole ratio is a ratio between the quantity of a component (or components) and the total quantity. We can find the quantity of that component by multiplying the total quantity by the fraction that is equivalent to the ratio.

Can we use these types of ratios to find the total quantities when we only know the quantity of the component?

Yes, we can do this by multiplying the quantity of the component by the reciprocal of the fraction equivalent to the ratio.

For example, if we know that there are 21 red marbles and the ratio of red to the total number of marbles is 3:8 we can find the total number of marbles with the calculation:\text{Total number of marbles}=21 \times \dfrac{8}{3}=56 which returns the expected answer.

We can also solve this using the unitary method.

If 21 red marbles is 3 parts, we can divide 21 by 3 to find the size of one part, and then multiply this amount by 8 to find the total number of marbles:\text{Total number of marbles}=\dfrac{21}{3} \times 8=56

Examples

Example 1

Ben always buys melons and bananas in the ratio 7:3. If he buys 30 pieces of fruit in total, how many melons did he buy?

Worked Solution
Create a strategy

The first part of the ratio corresponds to the melons.

Apply the idea

The ratio 7:3 has 10 parts. Out of those parts, 7 of them will be melons. This means that 7 out of 10 fruits will be melons.

\displaystyle \text{Number of melons}\displaystyle =\displaystyle 30 \times \dfrac{7}{10}Multiply 30 by \dfrac{7}{10}
\displaystyle =\displaystyle 3 \times 7Divide 30 by 10
\displaystyle =\displaystyle 21Evaluate

Example 2

In a zoo the ratio of elephants to lions is 7:4.

a

Which of the following represents the ratio of elephants to lions to the total number of elephants and lions?

A
7:4:11
B
7:4:28
C
7:4
D
28:11
Worked Solution
Create a strategy

We can find the total by adding together the parts from the ratio.

Apply the idea
\displaystyle 7+4\displaystyle =\displaystyle 11

So the ratio of elephants to lions to total is option A: 7:4:11.

b

Complete the table of equivalent ratios.

ElephantstoLionstoTotal
7:4:
14::
::110
Worked Solution
Create a strategy

We can write equivalent ratios by increasing each number in the ratio by a common multiple.

Apply the idea

We can complete the first row using the ratio from the previous part.

ElephantstoLionstoTotal
7:4:11
14::
::110

7\times 2=14 so we need to multiply 4 and 11 by 2 to get the equivalent ratio in the second row.

ElephantstoLionstoTotal
7:4:11
14:8:22
::110

In the total column 11\times 10=110 so we need to multiply the first row by 10 to get the equivalent ratio in the third row.

ElephantstoLionstoTotal
7:4:11
14:8:22
70:40:110
c

If there are 66 elephants and lions altogether, how many lions are there?

Worked Solution
Create a strategy

Determine what we need to multiply the total in the ratio by to get 66.

Apply the idea

The total in the ratio is 11, and 11\times 6 =66. So we need to multiply the number of lions in the ratio by 6.

\displaystyle \text{Lions}\displaystyle =\displaystyle 4 \times 6Multiply 4 by 6
\displaystyle =\displaystyle 24Evaluate the product
Idea summary

A part to whole ratio is a ratio between the quantity of a component (or components) and the total quantity. We can find the quantity of that component by multiplying the total quantity by the fraction that is equivalent to the ratio.

Outcomes

MA4-7NA

operates with ratios and rates, and explores their graphical representation

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