|| MAM4420 |
|| BOUNDARY VALUE PROBLEMS |
|| 2006/2007 |
|| Mr Alan Jones |
|| Intended for use in future years |
|Next year offered
|| N/A |
|Next semester offered
|| N/A |
|| MA34410 , MA34110 , MA30210 |
| Course delivery
|| Lecture || 20 x 1hour lectures |
|| Seminars / Tutorials || 7 x 1hour seminars |
|Assessment Type||Assessment Length/Details||Proportion|
|Semester Exam||2 Hours (written examination) ||100%|
|Supplementary Assessment||2 Hours (written examination) ||100%|
On completion of this module, a student should be able to:
1. discretize elliptic boundary value problems in an efficient way;
2. derive accurate numerical solutions of elliptic boundary value problems;
3. explain and use spectral methods and spectral element methods.
Boundary value problems, in ordinary and partial differential equations, occur naturally in science and engineering, eg clamped beam problems, slow viscous flow, and elasticity. Over the centuries many famous mathematicians have been challenged by such problems and have produced elegant classical solution methods. Today it is possible to marry some of these classical discoveries with modern computational methods, to enable the solution of contemporary problems.
To teach students how to solve linear boundary problems using modern analytic and computational methods.
1. TWO POINT BOUNDARY VALUE PROBLEMS: Variational and weak formulations.
2. GALERKIN AND PSEUDOSPECTRAL GALERKIN METHODS: Pseudospectral Galerkin and collocation methods.
3. ERROR ESTIMATE AND CONVERGENCE RATES FOR FINITE DIMENSIONAL APPROXIMATIONS
4. ELLIPTIC BOUNDARY VALUE PROBLEMS IN THE PLANE: Approximation in Tensor Product Spaces of Polynomials
5. INTRODUCTION TO ELEMENT METHODS.
** Supplementary Text
C Johnson (1987) Numerical Solution of Partial Differential Equations by the Finite Element Method
Cambridge University Press 0521347580
D Funaro (1992) Polynomial Approximation of Differential Equations
Springer Verlag 3540552308
This module is at CQFW Level 7