Introduction

This course provides an introduction to applied non-linear ordinary differential equations. This course is applied mathematics. There will be no technical lemmas or abstract definitions!

The course typically consists of twelve two-hour lectures. Participants will spend most of their time working on example problems and tutorial sheets, often using computer packages such as maple and matlab. In some years, towards the end of the session, students are given a project to apply the ideas that they have learnt.

A set of AMSI guidelines for this course are available here.

Content

Topics to be covered include (but are not limited to):

1. First-order differential equation: Graphical insights, steady-state solutions and their stability, steady-state diagrams and bifurcations.
2. Singularity theory with a distinguished parameter: singularity theory and bifurcation points, constructing static bifurcation diagrams.
3. Systems of two first-order differential equations
   1. steady-state solutions and their stability: local and Liapunov.
   2. the absence of periodic solutions: Bendixon's Criteria and Dulac's Test.
   3. periodic behaviour: the Hopf bifurcation Theorem, sub-critical and super-critical Hopf bifurcations.
   4. bifurcations and steady-state diagrams: singularity theory and bifurcation points.
   5. degenerate Hopf bifurcations: the double Hopf bifurcation, the Bautin bifurcation, the double-zero eigenvalue bifurcation.

Prerequisites

Assessment

Your final mark in MATH971 will be determined as follows. Two marks will be calculated using scheme one (S1) and scheme two (S2).

Your final mark will be the higher of the marks calculated using schemes one and two. Scaling of marks is not a standard procedure in this subject.

Note that you are not required to `pass' each individual component to receive a pass grade in MATH971. However, you would seriously jeopardise your chances of passing this subject if you do not aim to be successful in every component of the assessment.