Practical Scientific Computing

Professor of Biotechnology, Vice Chancellor, Government College University, Faisalabad, Pakistan Dr. Victor Zalizniak was awarded his Masters in Physics at Krasnoyarsk State University, Russia before becoming a Research Fellow at the Centre for Scientific Computing at the Russian Academy of Sciences (Siberian Branch). He then moved to the Department of Aerospace Engineering at the Royal Melbourne Institute of Technology where he obtained his PhD. In 2001 he returned to the Department of Computer Science at his alma mater, Krasnoyarsk State University, where he continues to lecture, research and write in his particular fields of computational physics and mathematical physics. He is the author of several books on scientific computing including Essentials of Computational Physics Parts 1 and 2.

Preface

Acknowledgements

Part I

Chapter 1: Introduction

1.1 Getting Started

1.2 Interpreter

1.3 Program

Chapter 2: Expressions

2.1 Matrix

2.2 Real Number

2.3 Complex Number

2.4 Boolean

2.5 String

2.6 Structure

2.7 Cell

2.8 Range Expression

2.9 Boolean Expression

2.10 Relational Expression

2.11 Numerical Expression

Chapter 3: Statements

3.1 Assignment Statement

3.2 Loop Statements

3.3 Conditional Statements

3.4 Continue and Break Statements

Chapter 4: Programming

4.1 Program

4.2 Function

4.3 Procedure

4.4 Java Programming

4.5 C Programming

Chapter 5: Architecture

5.1 Front-end

5.2 Back-end

5.3 User Interface

5.4 Gnuplot Interface

5.5 Execution Engine

Chapter 6: Plotting

6.1 Simple Function Plot (fplot)

6.2 Two-Dimensional Plots

6.3 Three-Dimensional Plots

Part II

Chapter 7: Solving Nonlinear Equations

7.1 Calculation of Roots with the use of Iterative Functions

7.2 Exercises

Chapter 8: Solving Systems of Linear Equations

8.1 Linear Algebra Background

8.2 Systems of Linear Equations

8.3 Types of Matrices that arise from Applications and Analysis

8.4 Error Sources

8.5 Condition Number

8.6 Direct Methods

8.7 Iterative Methods

8.8 Exercises

Chapter 9: Computational Eigenvalue Problems

9.1 Basic Facts concerning Eigenvalue Problems

9.2 Localization of Eigenvalues

9.3 Power Method

9.4 Inverse Iteration

9.5 Iteration with a Shift of Origin

9.6 The QR Method

9.7 Exercises

Chapter 10: Introduction to Finite Difference Schemes for Ordinary Differential Equations

10.1 Elementary Example of a Finite Difference Scheme

10.2 Approximation and Stability

10.3 Numerical Solution of Initial Value Problems

10.4 Numerical Solution of Boundary Value Problems

10.5 Error Estimation and Control

10.6 Exercises

Chapter 11: Interpolation and Approximation

11.1 Interpolation

11.2 Approximation of Functions and Data Representation

11.3 Exercises

Bibliography