Introduction
Instead of calculating a moving mean or a moving median, time series data that contains seasonality can be smoothed by calculating what is known as a seasonal index and using it to deseasonalise the data.
Calculate seasonal indices
The seasonal index is a measure of how a particular season compares with the mean season.
There is a four step process involved to deseasonalise time series data:
Calculate the mean for each cycle
Express each piece of original data as a proportion of the cycle mean
Calculate the seasonal index for each season by finding the mean of the proportions
Deseasonalise the data by dividing by the seasonal index
Examples
Example 1
The local police station records the number of speeding fines issued each quarter. The table below has the data for each quarter from 2012 to 2014.
| Time period | Data | Percentage of yearly mean |
|---|---|---|
| \text{March }2012 | 105 | 106.06\% |
| \text{June }2012 | 91 | x |
| \text{September }2012 | 101 | 102.02\% |
| \text{December }2012 | 99 | 100\% |
| \text{March }2013 | 101 | y |
| \text{June }2013 | 83 | 89.01\% |
| \text{September }2013 | 96 | 102.95\% |
| \text{December }2013 | 93 | 99.73\% |
| \text{March }2014 | 99 | 108.2\% |
| \text{June }2014 | 82 | 89.62\% |
| \text{September }2014 | 94 | 102.73\% |
| \text{December }2014 | 91 | z |
For 2012, 2013 and 2014, calculate the mean number of speeding tickets issued in each time period. Give your answers to two decimal places.
| Year | 2012 | 2013 | 2014 |
|---|---|---|---|
| Mean |
Divide the time period's data value by the yearly mean then multiply by a hundred percent.
Use your answers from part (a) to calculate the value of y. Give your answer to two decimal places.
Use your answers from part (a) to calculate the value of z. Give your answer to two decimal places.
The following are the properties of seasonal indices.
A seasonal index more than 1 means the season is higher than average.
A seasonal index less than 1 means the season is lower than average.
The sum of the seasonal indices equals the number of seasons.
The mean of the seasonal indices always equals 1.
Deseasonalise the data
To deseasonalise the data each raw value can now be adjusted by dividing it by the relevant seasonal index as follows. This process is also referred to as seasonal adjustment.
\text{Deseasonalised data}=\dfrac{\text{Actual figure}}{\text{Seasonal index}}
If given a deseasonalised figure, then the same formula can also be used to reseasonalise it using the seasonal index.
\text{Reseasonalised data}=\text{Deseasonalised data}\times \text{Seasonal index}
Examples
Example 2
The number of waiters employed by a restaurant chain in each quarter of 1 year, along with some seasonal indices that have been calculated from the previous year's data, are given in the following table.
| Quarter 1 | Quarter 2 | Quarter 3 | Quarter 4 | |
|---|---|---|---|---|
| Number of waiters | 197 | 144 | 83 | 170 |
| Seasonal index | 1.31 | - | 0.57 | 1.08 |
What is the seasonal index for the second quarter?
The seasonal index for quarter 1 is 1.31. What does this mean in terms of the average quarterly numbers of waiters?
Deseasonalise the data. Round to the nearest whole number.
| Quarter 1 | Quarter 2 | Quarter 3 | Quarter 4 | |
|---|---|---|---|---|
| Number of waiters | 197 | 144 | 83 | 170 |
| Seasonal index | 1.31 | 1.04 | 0.57 | 1.08 |
| Deseasonalised No. of waiters | ⬚ | ⬚ | ⬚ | ⬚ |
Deseasonalised data formula:
\text{Deseasonalised data}=\dfrac{\text{Actual figure}}{\text{Seasonal index}}
Reseasonalised data formula:
| \displaystyle \text{Reseasonalised data} | \displaystyle = | \displaystyle \text{Deseasonalised data}\times \text{Seasonal index} |