Unit name | Control Theory |
---|---|
Unit code | EMATM2700 |
Credit points | 10 |
Level of study | M/7 |
Teaching block(s) |
Teaching Block 2 (weeks 13 - 24) |
Unit director | Professor. Di Bernardo |
Open unit status | Not open |
Pre-requisites |
EMAT20200 or equivalent |
Co-requisites |
None |
School/department | School of Engineering Mathematics and Technology |
Faculty | Faculty of Engineering |
This unit introduces students to the theory of Automatic Control. The aim is to illustrate the skills and analytical tools required to analyse appropriate control strategies for both linear and nonlinear dynamical systems. Emphasis is given to Optimal Control Strategies particularly relevant in applications. The syllabus includes foundation topics such as linearisation, controllability and observability together with more advanced ones, e.g. control of bifurcations and chaos and adaptive control.
Control theory is a branch of Applied Mathematics whose recent developments have made possible, for example, the implementation of autopilots on aeroplanes and the landing of automatic interplanetary probes on Mars. Nowadays, novel challenges have arisen which require a proper mathematical understanding. Hybrid Control, Internet congestion control and the control of networks are just some examples of recent applications of control theory.
If you have taken previous courses in control or nonlinear dynamics and chaos, this course will give you the opportunity to look at some of the "hot" research topics in modern control theory and dynamical systems and see how the theory of nonlinear dynamics and chaos can be used to engineer new control devices !
The course is based on a series of lectures and computer demonstrations. When appropriate, visits to the Automatic Control Laboratory of the University of Bristol will be arranged. The syllabus includes linearisation techniques; controllability and observability of linear dynamical systems; stability theory and Lyapunov techniques; optimal control; elements of adaptive control; control and synchronisation of Chaos; applications to physics and engineering.
No previous course in control or nonlinear dynamics is required.
Aims:
This unit is intended to introduce you to the mathematical foundations of Control Theory. The aim of the course is to allow you to develop new skills and analytical tools required to analyse and design methods for the control of both linear and nonlinear dynamical systems.
By the end of this module, you will be able to use appropriate analytical tools to model and control a given physical system. Specifically, we will discuss how to:
Lectures
2-hour written examination: 100% (all learning outcomes)