A Compendium of Partial Differential Equation Models
A Compendium of Partial Differential Equation Models
AUD$209.05
exc GSTMathematical modelling of physical and chemical systems is used extensively throughout science, engineering, and applied mathematics. To use mathematical models, one needs solutions to the model equations; this generally requires numerical methods. This book presents numerical methods and associated computer code in Matlab for the solution of a spectrum of models expressed as partial differential equations (PDEs). The authors focus on the method of lines (MOL), a well-established procedure for all major classes of PDEs, where the boundary value partial derivatives are approximated algebraically by finite differences. This reduces the PDEs to ordinary differential equations (ODEs) and makes the computer code easy to understand, implement, and modify. Also, the ODEs (via MOL) can be combined with any other ODEs that are part of the model (so that MOL naturally accommodates ODE/PDE models). This book uniquely includes a detailed line-by-line discussion of computer code related to the associated PDE model.
- Includes line-by-line analysis and solutions for computer code associated with model equations
- Offers a detailed presentation of ODE/PDE mathematical models
- Methodology covers a broad spectrum of problems in science, engineering and applied mathematics
Reviews & endorsements
'The presented book is very interesting not only for students in applied mathematics, physics and engineering, but also for their teachers and can act as an effective and useful motivation in their work.' Zentralblatt MATH
Product details
March 2009Hardback
9780521519861
490 pages
260 × 182 × 31 mm
1.1kg
58 b/w illus. 2 colour illus. 43 tables
Available
Table of Contents
- 1. An introduction to the Method of Lines (MOL)
- 2. A one-dimensional, linear partial differential equation
- 3. Green's function analysis
- 4. Two nonlinear, variable coeffcient, inhomogeneous PDEs
- 5. Euler, Navier-Stokes and Burgers equations
- 6. The Cubic Schrödinger Equation (CSE)
- 7. The Korteweg-deVries (KdV) equation
- 8. The linear wave equation
- 9. Maxwell's equations
- 10. Elliptic PDEs: Laplace's equation
- 11. Three-dimensional PDE
- 12. PDE with a mixed partial derivative
- 13. Simultaneous, nonlinear, 2D PDEs in cylindrical coordinates
- 14. Diffusion equation in spherical coordinates
- Appendix 1: partial differential equations from conservation principles: the anisotropic diffusion equation
- Appendix 2: order conditions for finite difference approximations
- Appendix 3: analytical solution of nonlinear, traveling wave partial differential equations
- Appendix 4: implementation of time varying boundary conditions
- Appendix 5: the DSS library
- Appendix 6: animating simulation results.
