Continuous Uniform Distribution (Cambridge (CIE) A Level Maths): Revision Note

Author

Paul

Last updated

10 February 2025

Continuous Uniform Distribution

What is meant by the continuous uniform distribution?

This is a special case of a probability density function for a continuous random variable
- The normal distribution is another special case covered in S1
The uniform, or rectangular, distribution is a p.d.f. that is constant and non-zero over a range of values but zero everywhere else

Since the area under the graph has to total 1, the height of the uniform distribution would be

$\frac{1}{b - a}$

Therefore the probability density function is given by
$f (x) = \{\begin{cases} \frac{1}{b - a} & a \leq x \leq b \\ 0 & otherwise \end{cases}$

How do I find probabilities for a continuous uniform distribution?

Sketch the graph of y= f(x)
Probabilities are the area under the graph, all such areas will now be rectangles
- Finding the area of a rectangle is likely to be easier than integration!
The symmetrical properties of rectangles may also be used to find probabilities

How do I find the mean, median, mode and variance of a continuous uniform distribution?

The mean, or expected value, is given by

$E (X) = \frac{1}{2} (a + b)$

This is the (vertical) axis of symmetry of the rectangle
Should the above be forgotten, $E (X) = \int_{a}^{b} x f (x) d x$ can still be applied
- You be may asked to use this to prove the result
The median can also be found by symmetry and will be equal to the mean
There is no mode as f(x) is equal - and so at its greatest - for all values of x
The variance is given by

$Var (X) = \frac{1}{12} {(b - a)}^{2}$

Should the above be forgotten, $Var (X) = \int_{- \infty}^{\infty} x^{2} f (x) d x - {[E (X)]}^{2}$ or $V a r (X) = E (X^{2}) - {[E (X)]}^{2}$ can still be applied
- You may be asked to use this to prove the result
- The standard deviation is the square root of the variance

Worked Example

A continuous random variable, $X$ , is modelled by the uniform distribution such that
$f (x) = 0.4$ for $a \leq x \leq 4$ and $f (x) = 0$ otherwise.
a is a constant.

(a) Show that the value of a is 1.5 .

(b) Find

(i) $P (2.5 \leq X \leq 3)$

(ii) $E (X)$

Examiner Tips and Tricks

A sketch of the graph of a uniform distribution is quick and will highlight the symmetry in a uniform distribution
Use areas of rectangles to find probabilities rather than integrating

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Previous:E(X) & Var(X) (Continuous)Next:Choosing Distributions

Continuous Uniform Distribution (Cambridge (CIE) A Level Maths): Revision Note

Continuous Uniform Distribution

What is meant by the continuous uniform distribution?

How do I find probabilities for a continuous uniform distribution?

How do I find the mean, median, mode and variance of a continuous uniform distribution?

Worked Example

Examiner Tips and Tricks

You've read 0 of your 5 free revision notes this week

Sign up now. It’s free!

Join the 100,000+ Students that ❤️ Save My Exams

Statistical Sampling & Estimation

Sampling & Data Collection

Sampling & Data Collection

Sampling & Estimation

Unbiased Estimates

Distribution of Sample Means

Confidence Intervals

Statistical Distributions

Poisson Distribution

The Poisson Distribution

Linear Combinations of Random Variables

Linear Combinations of Random Variables

Continuous Random Variables

Probability Density Function

E(X) & Var(X) (Continuous)

Continuous Uniform Distribution

Working with Distributions

Choosing Distributions

Approximations of Distributions

Hypothesis Testing

Hypothesis Testing

Hypothesis Testing

Type I & Type II Errors

Hypothesis Testing (Binomial & Poisson Distributions)

Hypothesis Testing for the Proportion of a Binomial Distribution

Hypothesis Testing for the Mean of a Poisson Distribution

Hypothesis Testing (Normal Distribution)

Hypothesis Testing for the Mean of a Normal Distribution

Author: Paul