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Unit information: Complex Networks in 2016/17

Please note: you are viewing unit and programme information for a past academic year. Please see the current academic year for up to date information.

Unit name Complex Networks
Unit code MATH36201
Credit points 20
Level of study H/6
Teaching block(s) Teaching Block 2 (weeks 13 - 24)
Unit director Dr. Ayalvadi Ganesh
Open unit status Not open

MATH11300 Probability 1 (or equivalent) and MATH 11005 Linear Algebra & Geometry (or equivalent). MATH 21400 (Applied Probability 2) is strongly recommended.



School/department School of Mathematics
Faculty Faculty of Science


Unit aims

Understand how to mathematically model complex networks. Learn to analyse stochastic processes such as rumour spread, epidemics and consensus on networks.

General Description of the Unit

This unit will teach ways of modelling and working with large complex networks such as the Internet and social networks. The topics covered will be

Probability background: Markov chains in discrete and continuous time, and Poisson processes Spread of information and epidemics on networks Consensus models on networks Random walks on networks and spectral graph theory Random graphs

Relation to Other Units

The unit introduces Markov chain models seen in Applied Probability 2 (which is not a pre-requisite but is strongly recommended) and applies them to the study of random processes on networks. Information Theory, Complex Networks, Financial Mathematics, and Queueing Networks, all involve the application of probability theory to problems arising in various fields.

Applied Probability 2 will become a pre-requisite for this course from next year. Students who have not taken it should discuss the suitability of this course with the unit organiser before registering for it.

Additional unit information can be found at

Intended learning outcomes

Learning Objectives

  • Learn to model a variety of stochastic processes on graphs, including random walks and the spread of information and epidemics
  • Learn to analyse these processes to obtain bounds and approximations for quantities of interest
  • Learn about the relationship of graph spectra to various properties of the graph

Teaching details

Lectures and problem sheets, from which work will be set and marked, with outline solutions handed out a fortnight later.

Assessment Details

100% Examination

Raw scores on the examinations will be determined according to the marking scheme written on the examination paper. The marking scheme, indicating the maximum score per question, is a guide to the relative weighting of the questions. Raw scores are moderated as described in the Undergraduate Handbook.

Reading and References

Reading and references are available at