Introduction
In order to predict the future, we sometimes need to determine the probability by running experiments, or looking at data that has already been collected. This is called experimental probability (or relative frequency), since we determine the probability of each outcome by looking at past events.
Experimental probability
Instead we will need to roll the die many times and record our results, and use these results to predict the future.
| Result | Number of rolls |
|---|---|
| \ 1 | \ 11 |
| \ 2 | \ 19 |
| \ 3 | \ 18 |
| \ 4 | \ 18 |
| \ 5 | \ 20 |
| \ 6 | \ 114 |
We can now try to predict the future using this experimental data, and the following formula:\text{Experimental probability of event} = \dfrac{\text{Number of times event occurred in experiments}}{\text{Total number of experiments}}
Here is the table again, with the experimental probability of each face listed as a percentage:
| Result | Number of rolls | Experimental Probability |
|---|---|---|
| \ 1 | \ 11 | \ 5.5 \% |
| \ 2 | \ 19 | \ 9.5 \% |
| \ 3 | \ 18 | \ 9 \% |
| \ 4 | \ 18 | \ 9 \% |
| \ 5 | \ 20 | \ 10 \% |
| \ 6 | \ 114 | \ 57 \% |
A normal die has around a 17\% chance of rolling a 6, but this die rolls a 6 more than half the time.
Sometimes our "experiments" involve looking at historical data instead. For example, we can't run hundreds of Eurovision Song Contests to test out who would win, so instead we look at past performance when trying to predict the future. The following table shows the winner of the Eurovision Song Contest from 1999 to 2018:
| Year | Winning country | Year | Winning country |
|---|---|---|---|
| \ 1999 | \text{Sweden} | \ 2009 | \text{Norway} |
| \ 2000 | \text{Denmark} | \ 2010 | \text{Germany} |
| \ 2001 | \text{Estonia} | \ 2011 | \text{Azerbaijan} |
| \ 2002 | \text{Latvia} | \ 2012 | \text{Sweden} |
| \ 2003 | \text{Turkey} | \ 2013 | \text{Denmark} |
| \ 2004 | \text{Ukraine} | \ 2014 | \text{Austria} |
| \ 2005 | \text{Greece} | \ 2015 | \text{Sweden} |
| \ 2006 | \text{Finland} | \ 2016 | \text{Ukraine} |
| \ 2007 | \text{Serbia} | \ 2017 | \text{Portugal} |
| \ 2008 | \text{Russia } | \ 2018 | \text{Israel} |
What is the experimental probability that Sweden will win the next Eurovision Song Contest?
We think of each contest as an "experiment", and there are 20 in total. The winning country is the event, and we can tell that 3 of the contests were won by Sweden. So using the same formula as above, \text{Experimental probability of event} = \dfrac{\text{Number of times event occurred in experiments}}{\text{Total number of experiments}}
the experimental probability is \dfrac{3}{20}, which is 15\%.
How many of the next 50 contests can Sweden expect to win?
We can calculate this by multiplying the experimental probability of an event by the number of trials. In this case Sweden can expect to win
| \displaystyle \dfrac{3}{50} \times 50 | \displaystyle = | \displaystyle \dfrac{150}{20} \text{ contests} |
This rounds to 8 contests out of the next 50 .
The theoretical probability of rolling any given number on a fair die is \dfrac{1}{6}. However, if we rolled the die 100 times and got these results:
| Result | Number of rolls | Experimental Probability |
|---|---|---|
| \ 1 | \ 14 | \ 14 \% |
| \ 2 | \ 19 | \ 19 \% |
| \ 3 | \ 18 | \ 18\% |
| \ 4 | \ 20 | \ 20\% |
| \ 5 | \ 16 | \ 16 \% |
| \ 6 | \ 13 | \ 13\% |
We can see that the experimental values even for a fair die might not equal the theoretical probability of 16.67\%. If we convert this to the percentage of the rolls though we can see they are reasonably close to the theoretical probability. But perhaps the die could be a little bit biased. In this case we can roll the die more to see if the experimental probability approaches the the theoretical probability with a higher number of rolls.
| Result | Number of rolls | Experimental Probability |
|---|---|---|
| \ 1 | \ 171 | \ 17.1 \% |
| \ 2 | \ 159 | \ 15.9 \% |
| \ 3 | \ 172 | \ 17.2 \% |
| \ 4 | \ 166 | \ 16.6 \% |
| \ 5 | \ 169 | \ 16.9 \% |
| \ 6 | \ 163 | \ 16.3 \% |
If we rolled the die 1000 times we should expect the percentage to get closer, but not the actual number of rolls will still not be equal to the expected number of rolls.
Examples
Example 1
Ryan decided to flip a coin 20 times.
How many times would he expect a head to appear?
After he finished flipping the coins, he noticed that heads had appeared 11 times. Write the experimental probability of getting a head as a fraction.
Example 2
To prepare for the week ahead, a restaurant keeps a record of the number of each main meal ordered throughout the previous week.
| Meal | Frequency |
|---|---|
| \text{Chicken} | 21 |
| \text{Beef} | 55 |
| \text{Lamb} | 44 |
| \text{Vegetarian} | 31 |
How many meals were ordered altogether?
What is the experimental probability that a customer will order a chicken meal? Round your answer to the nearest whole percent.
To calculate the experimental probability:\text{Experimental probability of event} = \dfrac{\text{Number of times event occurred}}{\text{Total number of experiments}}
To calculate the expected number of trials with a specific outcome:
\text{Expected no. of favourable trials} = \text{Experimental probability} \times \text{Total no. of trials}
Experimental probability does not need to equal theoretical probability. Experimental probability should get closer to the theoretical probability value as the number of trial increases.