Variation of Data

Example :

Consider the set of values: $\text{10, 21, 34, 35, 36, 37, 37, 41, 44 and 67}$ .

The highest value of the data set is $\text{67}$ and the lowest is $\text{10}$ . So, the range of the data set is

$67-10=57$

But that doesn't tell the whole story. Sometimes, we are also interested in how clustered or spread out the data is.

Consider another set of data $\text{10, 15, 30, 40, 45, 55, 60, 65, 68, and 70}$ .

The two sets have almost the same range, but the distributions have different shapes. 

If you draw a line plot of the two, it will look like this:

In the first data set, the data is clustered around the median, $36.5$ .

In the second data set, the data is more spread out, with a little cluster near the top of the range.

In a set of data, the quartiles are the values that divide the data into four equal parts. The median of a set of data separates the set in half.

The median of the lower half of a set of data is the lower quartile (LQ) or $Q_1$ .

The median of the upper half of a set of data is the upper quartile (UQ) or $Q_3$ .

Here, $Q_1=15$ and $Q_3=35$

The upper and lower quartiles can be used to find another measure of variation call the interquartile range.

The interquartile range is the range of the middle half of a set of data. It is the difference between the upper quartile and the lower quartile.

Interquartile range = $Q_3-Q_1$

In the above example, the interquartile range is $35-15=20$ .

Data points that are more than $1.5$ times the value of the interquartile range beyond the quartiles are called outliers.