���˿���

\(Range = largest~number - smallest~number\)

\(\text{Range} = \text{biggest number} - \text{smallest number} = 4.1 - 2.5 = 1.6\)

To find the interquartile range, subtract the value of the lower quartile (\(\frac{1}{4}\) or 25%) from the value of the upper quartile (\(\frac{3}{4}\) or 75%). The interquartile range will give a clearer picture of the middle set of data that is not affected by the extremes or outliers.

\(\text{Interquartile range} = \text{upper quartile} - \text{lower quartile}\)

Lower quartile = \(\frac{7 + 1}{4}\) = \(\frac{8}{4}\), which is the second value in the list.

\(\begin{array}{ccccccc} 2.5~\text{kg}, & 3.1~\text{kg}, & 3.4~\text{kg}, & 3.5~\text{kg}, & 3.5~\text{kg}, & 4~\text{kg}, & 4.1~\text{kg} \\ & \text{lower quartile} && \text{median} &&& \end{array}\)

To find the value of the upper quartile, multiply the lower quartile by 3 as \(\frac{1}{4} \times 3 = \frac{3}{4}\).

The lower quartile was the 2nd number in the list, so the upper quartile must be the 6th number in the list (\(2 \times 3 = 6\)).

\(\begin{array}{ccccccc} 2.5~\text{kg}, & 3.1~\text{kg}, & 3.4~\text{kg}, & 3.5~\text{kg}, & 3.5~\text{kg}, & 4~\text{kg}, & 4.1~\text{kg} \\ & \text{lower quartile} &&&& \text{upper quartile} & \end{array}\)

\(\text{Interquartile range} = \text{upper quartile} - \text{lower quartile} = 4 - 3.1 = 0.9\)