If you've ever seen a poll or a popularity survey on the news, you might be familiar with graphs that look something like these:
In terms of representing data in a visually appealing and digestible manner, two of the most common tools are histograms and circle graphs (which are also called circle graphs).
Unlike the dot plot and stem-and-leaf plot, these graphs focus more on representing the relation between different results visually while worrying less about displaying the exact values of the survey. It is for this reason that histograms and circle graphs are often used to represent large data sets.
The reason why these two graphs look so similar, aside from them representing the same data, is because the histogram is essentially a more complex version of the line plot. Rather than counting dots, the histogram uses a scale to indicate the height of the columns, allowing it to represent larger data sets.
Below is a column graph showing the type of fruit each student in a class brought in for lunch yesterday.
What was the most common fruit?
Apple
Orange
Banana
Mango
Mandarin
How many more mandarins were brought than mangoes?
Complete the table below using the information from the graph.
Fruit |
Number |
---|---|
Banana | $3$3 |
Apple | $\editable{}$ |
Mandarin | $\editable{}$ |
Mango | $\editable{}$ |
Orange | $\editable{}$ |
Circle graphs are, at first glance, completely different from histograms. The main similarity is that the mode of a circle graph is clearly visible, just as it is on a histogram.
What makes a circle graph so different is that it represents the data as parts of a whole. In a circle graph, all the data is combined to make a single whole with the different sectors representing different categories. The larger the sector, the larger percentage of the data points that category represents.
Consider the circle graph below:
We can see from the circle graph (using the legend to check our categories) that the red sector takes up half the circle, while the blue sector takes up a quarter and the yellow and orange sectors both take up one eighth.
The fraction of the circle taken up by each sector indicates what fraction of the total fish are that color. So, in this case, half the fish are red since the red sector takes up half the circle. We can also write this as a percentage: $50%$50% of the fish are red.
If we consider how much of the circle each sector takes up, we can identify what percentage of the total fish are of each color.
Color of fish | Fraction of total | Percentage |
---|---|---|
Orange | $\frac{1}{8}$18 | $12.5%$12.5% |
Red | $\frac{1}{2}$12 | $50%$50% |
Blue | $\frac{1}{4}$14 | $25%$25% |
Yellow | $\frac{1}{8}$18 | $12.5%$12.5% |
Notice that the sum of our percentages is $100%$100%. This is consistent with the fact that a circle graph represents $100%$100% of the data, one whole, split up into different category sectors.
A notable drawback of the circle graph is that it doesn't necessarily tell us how many data points belong to each category. This means that, without any additional information, the circle graph can only show us which categories are more or less popular and roughly by how much.
It is for this reason that we will often add some additional information to our circle graphs so that we can show (or at least calculate) the number of data points in each category. There are two main ways to add information to a circle graph:
By revealing the total number of data points, we can use the percentages represented by the sector sizes to calculate how many data points each sector represents.
Consider the circle graph below:
If there are $48$48 fish in total, how many of them are either blue or yellow?
Think: We found in the exploration above that $25%$25% of the fish are blue and $12.5%$12.5% are yellow. Together this represents $37.5%$37.5% of the $48$48 fish.
Do: We can find the number of blue or yellow fish by multiplying the total number of fish by the percentage taken up by these two colors.
Blue or yellow fish | $=$= | $48\times37.5%$48×37.5% |
$=$= | $48\times\frac{3}{8}$48×38 | |
$=$= | $18$18 |
As shown, $18$18 fish are either blue or yellow.
Reflect: By relating the sizes of sectors to fractions or percentages, we can calculate the number of data points belonging to a category by multiplying that fraction (or percentage) by the total number of data points.
Revealing the total number of data points is useful for calculating the value represented by each sector, but this is only if we can interpret the exact size of each sector from the circle graph.
In the case where it is not so obvious what percentage of the circle graph each sector represents, we can instead add information by explicitly stating how many data points each sector represents. This can be written either on the sectors or the legend, as shown below.
Consider the circle graphs below:
Using either of them, show that the sector representing basketball takes up $43%$43% of the circle graph.
Think: To show that the basketball sector takes up $43%$43% of the circle graph, we need to show that the number of basketball data points is equal to $43%$43% of the total data points.
Do: We can see from the circle graphs that the basketball sector represents $86$86 data points. By adding up the data points from all the different sectors, we find that the total number of data points is:
Total number of data points | $=$= | $86+27+53+30+4$86+27+53+30+4 |
$=$= | $200$200 |
So the percentage of the total number of data points represented by basketball is:
Percentage | $=$= | $\frac{86}{200}\times100%$86200×100% |
$=$= | $43%$43% |
Since basketball represents $43%$43% of the data points, its sector must take up $43%$43% of the circle graph.
Reflect: We can calculate the exact percentage of the circle graph that different sectors take up by finding their number of data points as a percentage of the total.
Aside from these two ways to add extra information to a circle graph, there is also the case where the percentage taken up by each sector is shown on the circle graph.
This will often look something like this:
This is very useful as it does a lot of the calculations for us. However, it is important that we always check that the percentages on the graph add up to $100%$100% since a circle graph always represents the whole of the data points, no more and no less.
In this particular case, the percentages do in fact add up to $100%$100% so this circle graph is valid.
Every student in year $8$8 was surveyed on their favorite subject, and the results are displayed in this pie chart:
Which was the most popular subject?
Phys. Ed.
Math
History
Languages
Science
English
What percentage of the class selected History, Phys. Ed., or Languages?
$50%$50%
$30%$30%
$3%$3%
$25%$25%
You later find out that $32$32 students selected Science. How many students are there in year $8$8?