Probability, the science of chance, and statistics, the science of interpreting data, influence and govern our daily lives. They are used to predict the weather, determine the effectiveness of medicine and are an important process in making scientific breakthroughs. They can even help us play card games.
More generally, probability and statistics help individuals and institutions make better decisions by learning from events in the past and applying this knowledge to the present to affect the future.
The relationship between probability and statistics
It is important to understand the differences and similarities between probability and statistics. They are different but related subjects.
Probability is a theoretical subject used to analyse the likelihood of events happening in the future. On the other hand, statistics is an applied subject which uses probability theory to analyse data which has been collected.
Probability and statistics are related in that the theories we develop in probability mathematics are compared with statistical findings which can tell us more information about the data. We can also use statistics to estimate the probability of something happening in the future.
Probability
Probability is the likelihood of some event occurring. The probability of an event happening is always a fraction, decimal or percentage between 0 and 1.
Probability is the branch of mathematics that studies the likelihood of events occurring.
The basic formula for probability is the following:
Some terminology for probability
There is a lot of terminology in probability which you need to be familiar with. The better you understand the basic concepts detailed below, the easier it will be when you tackle trickier probability questions!
| Terminology | Definition |
| Experiment or trial | A repeatable action which has a defined set of outcomes. |
| Sample space | The set of all possible outcomes of an experiment, usually denoted by ![]() or S. |
| Event | An event is one particular outcome, usually denoted by a capital letter. The probability of event A occurring is commonly notated as P(A). |
An example of probability
You are on a game show and you have to choose between 2 boxes. One contains a sports car and the other is empty. You are given no clues as to which box contains the prize and must therefore choose a box at random. What is the probability you win the sports car?
Solution
Here, the sample space is S = {W, L} where W stands for 'win' and L stands for 'lose'. This is the sample space since these are the only possible outcomes.
Intuitively, since you are choosing at random, there is an equal probability of choosing the prize and choosing the empty box. Since probabilities are always between 0 and 1, the probability of choosing the sports car is 0.5 (= 50%).
We can also arrive at this answer by using the basic formula for probability. The number of ways to choose the box with the sports car is 1, and the total number of outcomes (either choosing the sports car or choosing the empty box) is 2. Using mathematical notation, the probability of winning is as follows:
![]()
.
Therefore, the probability of choosing the sports car and therefore winning is ![]()
which is equivalent to 50% or 0.5.
Statistics
Data usually contains far too many individual numbers for the human brain to even comprehend, let alone understand. This is why we need statistics: to help us to better understand the underlying complexities in the data we have collected.
Statistics concerns the analysis and interpretation of data which has been collected.
The sorts of tasks you will have in statistics questions will fall into one of three categories: data collection, analysis, and visualisation and interpretation.
Data collection
The type of data collected will depend on the statistical question you want answered, i.e. the characteristic you want to study. You might be interested in collecting data through holding a scientific experiment (e.g. measuring the effect of location on the growth of plants) or perhaps by collecting data through observation (e.g. recording the number of students that are late for class).
All data falls into two categories: qualitative and quantitative.
Qualitative data refers to descriptive data, such as words. It might be collected through interviews or surveys.
Quantitative data refers to things which can be represented using numbers, like measurements such as height and weight, or quantities of something that we are interested in knowing more about. Important methods include:
conducting a census
sampling
controlled experiments
Quantitative data also falls into two categories: continuous and discrete.
Continuous variables can take on any value within a range, which can make it more difficult for us to count them. For example, length can be measured to as many decimal places as is possible. It's up to you, the data collector, to decide how many decimal places are necessary.
Discrete variables must take on particular values within a range, which makes it easier to count them. For example, shoe size can be 4 or 4.5, but not 4.26735!
Analysis
Once you have collected your data, it is now time to start analysing it. Since it is very difficult (and often impossible!) to understand data in its raw form, we need to condense it into manageable descriptions that retain as much information about the data as possible whilst being understandable. This is the ultimate goal of statistics: to understand, describe and find meaningful information from datasets.
Descriptive statistics are particularly useful. These are numbers that tell us something about the data. There are two kinds: measures of location and measures of spread.
Measures of location use one statistic to summarise a dataset. They include:
![]()
;
Measures of spread describe the variability of the data. They include:
Data is often be represented in frequency tables. Frequency refers to the number of times something occurs, which in the case of statistics will be the number of times a particular data value occurs. From a frequency table, you will be able to extract descriptive statistics such as the ones listed above. You will also be able to use these to visualise data.
Visualisation and interpretation
Descriptive statistics are useful in condensing data into a small amount of information, and can tell us about the location and spread of the data. Data visualisations, on the other hand, are able to graphically represent the data. For a thorough analysis, you would ideally use both methods to be able to fully understand the behaviour of the data.
We will now go through some examples of different data visualisations. Don't worry if you can't yet fully understand the examples below – there are in-depth explanations in other articles!
Line graphs
These are useful in representing continuous data and trends.
The following is an example of a line graph:
StudySmarter originals, Rebecca Farthing
Bar charts
These are useful in representing data which is grouped.
The following is an example of a bar chart:
StudySmarter originals, Rebecca Farthing
Histograms
These are useful in representing the frequency of something happening.
The following is an example of a histogram:
StudySmarter originals, Rebecca Farthing
Pie charts
These are useful in representing proportional data.
The following is an example of a pie chart:
StudySmarter originals, Rebecca Farthing
Box-and-whisker plots
These visualise the range, interquartile range and median.
The following is an example of a box-and-whisker plot:
StudySmarter originals, Rebecca Farthing
Scatter graphs
Shows the relationship between two variables.
The following is an example of a scatter plot:
StudySmarter originals, Rebecca Farthing
Finally, once the data has been analysed and represented graphically, we can draw conclusions from the data. Have a look at the example below.
An example of statistics
The following is data collected from a team's football matches. The frequency of the number of goals scored by each player per match is recorded from a total of 20 matches.
| Team member | Scored 0 goals | Scored 1 goal | Scored 2 goals | Scored 3 goals | Scored 4 goals |
| Zack | 5 | 6 | 4 | 4 | 1 |
| Josh | 9 | 5 | 7 | 0 | 0 |
| Amy | 0 | 13 | 3 | 4 | 0 |
| Ahmed | 2 | 11 | 4 | 1 | 2 |
| Emily | 7 | 12 | 0 | 0 | 1 |
a) What type of data is presented here?
b) Which team member scores the largest number of goals over the course of the season?
c) Which player scored the highest average number of goals per game?
d) Represent this data using a pie chart.
e) What does this data tell us about the performance of the players?
Solution
a) Frequency and goals scored per match are both quantitative, discrete data. It is impossible to score 0.5 goals!
b) By multiplying the number of goals by the frequency, f, we can find the total goals scored by each player:
| Team member | f x 0 | f x 1 | f x 2 | f x 3 | f x 4 | Total goals |
| Zack | 0 | 5 | 4 × 2 = 8 | 4 × 3 = 12 | 2 × 4 = 8 | 33 |
| Josh | 0 | 5 | 7 × 2 = 14 | 0 × 3 = 0 | 0 × 4 = 0 | 19 |
| Amy | 0 | 13 | 3 × 2 = 6 | 4 × 3 = 12 | 0 × 4 = 0 | 32 |
| Ahmed | 0 | 11 | 4 × 2 = 8 | 1 × 3 = 3 | 2 × 4 = 8 | 30 |
| Emily | 0 | 12 | 0 × 2 = 0 | 0 × 3 = 0 | 1 × 4 = 4 | 16 |
We can see that the most goals scored by one player was by Zack, who scored 33 during the season.c) To find the average number of goals per match, we need to divide the total number of goals by the number of matches:Zack:
![]()
goals per match
Josh: ![]()
goals per match
Amy: ![]()
to 2 d.p. goals per match
Ahmed: ![]()
goals per match
Emily: ![]()
goals per match
d) A pie chart shows proportional data. This means we need to work out what
proportion of the total goals in the season are scored by each player. To do this, we should divide each player's total goals by the total number of goals scored during the season.Total number of goals scored by all players = 33 + 19 + 32 + 30 + 16 = 130Zack:
![]()
Josh:
![]()
Amy:
![]()
Ahmed:
![]()
Emily:
![]()
StudySmarter originals, Rebecca Farthinge) There isn't just one right answer here! This is about interpretation, so what is important is to have your answer backed up by statistics that you have found from the data.A possible conclusion we might take from the data is that the three highest-scoring players, Zack, Amy and Ahmed, all contributed a similar number of goals, making up 73% of the goals scored. On the other hand, Ahmed and Emily together contributed 27% of the goals, which is considerably less.
Probability and Statistics - Key takeaways
- Probability is the branch of mathematics that studies the likelihood of events occurring
![]()
- An experiment or trial is a repeatable action which has a defined set of outcomes
- A sample space is the set of all possible outcomes of an experiment
- An event is one particular outcome. The probability of event A occurring is P(A)
- Statistics concerns the analysis and interpretation of data which has been collected
- Data can be qualitative or quantitative
- Quantitative data can be discrete or continuous
- Measures of location use one statistic to summarise a dataset
- e.g. mean, median and mode
- Measures of spread describe the variability of the data
- e.g. range and interquartile range
- Some examples of data visualisations are line graphs, bar charts, histograms, pie charts, box-and-whisker plots and scatter plots
Explanations 
Exams 
Magazine 
