Module Directory

For students outside of the Department, an appropriate A level in Mathematics (or equivalent) is required for this module. If you are unsure whether you meet this criteria please contact maths@essex.ac.uk before attempting to enrol.

This module introduces students to the basic ideas of probability (combinatorial analysis and axioms of probability), conditional probability and independence, probability distributions, and provides an introduction to handling data using descriptive statistics. This module uses the R software package to clarify and illustrate theoretical concepts of probability, to show how random variables are generated and how they vary, enabling the construction of appropriate diagrams for data summary. This module covers part of the CS1 IFOA syllabus.

The aims of this module are:

• To familiarize students with descriptive statistics to explore real data.


• To understand the concepts of probability and conditional probability and apply them in real situations using various counting techniques.


• To understand the concepts of discrete and continuous random variables, their distributions, and their measures of location and variability.


• To examine in detail several parametric models (Binomial, Poisson, Normal, Gamma, etc) and explore their applications.


• To introduce students to R software and investigate data sets.

By the end of this module, students will be expected to be able to:

1. Understand how to calculate and interpret simple summary statistics.


2. How to choose and construct appropriate diagrams to illustrate data sets.


3. Use R for the data analysis examples of the course.


4. Understand and apply the addition rule and multiplication rule of probability.


5. Understand the basic ideas of conditional probability including the application of the total probability theorem and Bayes' theorem.


6. Understand and recognise situations appropriate for Binomial and Poisson models.


7. Calculate expectations and variances for discrete and continuous random variables, understand the ideas of probability density function and the distribution function.


8. Understand the change of variables formula and know how to calculate the distributions of functions of random variables.


9. Understand moment generating functions.


10. Recognise the central role of the normal distribution, be able to reduce normal random variables to standard form, and be able to use tables of normal probabilities.


11. Understand the basic ideas of central limit theorem.


12. Implement in R the statistical methods described above.

Syllabus

Descriptive statistics:

• Data collection and summary.


• Stem/leaf plots and histograms.


• Measures of location (mode, median, mean).


• Measures of spread.


• Quartiles.


• Box plots.


• Variance and standard deviation.


• Transformations.

Probability:

• Relative frequency.


• Probability as a limit.


• Events.


• Union and intersection.


• Addition rule.


• Exclusive events.


• Independent events.


• Multiplication rule.


• Permutations and combinations.


• Conditional probability.


• Total probability theorem.


• Bayes' theorem.

Discrete probability distributions:

• Discrete random variables.


• Probability distributions.


• Expectation.


• Algebra of expectations.


• Variance.


• Bernoulli distribution.


• Binomial distribution (sampling with replacement).


• Mean and variance of Bernoulli and binomial.


• Poisson distribution (and applications).


• Derivation of the Poisson.


• Approximation to the binomial.

Continuous probability distributions:

• Density function as the limit of histograms.


• Properties of probability density function (pdf).


• Cumulative distribution function (cdf).


• Uniform and exponential distribution.


• Expectations.


• Variance.


• Median, mode.


• Distributions of functions of random variables.


• Change of variables formula.


• Normal distribution.


• Use of tables.


• Central limit theorem.


• Additivity.


• Moment generating function.

Implement in R the statistical methods described above.

Teaching in the School will be delivered using a range of face to face lectures, classes, and lab sessions as appropriate for each module. Modules may also include online only sessions where it is advantageous, for example for pedagogical reasons, to do so.