A first course in the numerical analysis of differential equations

Numerical analysis presents different faces to the world. For mathematicians it is a bona fide mathematical theory with an applicable flavour. For scientists and engineers it is a practical, applied subject, part of the standard repertoire of modelling techniques. For computer scientists it is a theory on the interplay of computer architecture and algorithms for real-number calculations. The tension between these standpoints is the driving force of this book, which presents a rigorous account of the fundamentals of numerical analysis of both ordinary and partial differential equations. The exposition maintains a balance between theoretical, algorithmic and applied aspects. This second edition has been extensively updated, and includes new chapters on emerging subject areas: geometric numerical integration, spectral methods and conjugate gradients. Other topics covered include multistep and Runge-Kutta methods; finite difference and finite elements techniques for the Poisson equation; and a variety of algorithms to solve large, sparse algebraic systems.

• Preface to the first edition
• Preface to the second edition
• Flowchart of contents
• Part I. Ordinary Differential Equations: 1. Euler's method and beyond
• 2. Multistep methods
• 3. Runge-Kutta methods
• 4. Stiff equations
• 5. Geometric numerical integration
• 6. Error control
• 7. Nonlinear algebraic systems
• Part II. The Poisson Equation: 8. Finite difference schemes
• 9. The finite element method
• 10. Spectral methods
• 11. Gaussian elimination for sparse linear equations
• 12. Classical iterative methods for sparse linear equations
• 13. Multigrid techniques
• 14. Conjugate gradients
• 15. Fast Poisson solvers
• Part III. Partial Differential Equations of evolution: 16. The diffusion equation
• 17. Hyperbolic equations
• Appendix. Bluffer's guide to useful mathematics: A.1. Linear algebra
• A.2. Analysis
• Bibliography
• Index.