History of mathematicians

In this document we give some information of mathematicians which work or names are used in the course wi2023 "Numerieke Wiskunde voor technici". November 1947 can be seen as the birthday of modern numerical analysis.

1. Ordinary differential equations

Ordinary differential equations are splitted into two classes: initial value problems and boundary value problems. In Chapter 1 initial value problems are considered. Several numerical integration methods are given and analysed as there are

Euler methods ( Leonhard Euler (1707-1783))
The method of Heun
The Runge-Kutta method ( Martin Wilhelm Kutta (1867-1944), Carle David Tolmé Runge (1856-1927))

As an application of the theory given in Chapter 1 of this course a simulation (using a Java-applet) of a double pendulum is possible. The integration is done by a Runge-Kutta method.

To analyse the discretisation error of these methods the Taylor ( Brook Taylor (1685-1731)) polynomial is used together with numerical integration methods: midpoint rule, trapezium rule and the integration method of Simpson ( Thomas Simpson (1710-1761)). The order symbol of Landau ( Edmund Georg Hermann Landau (1877-1938)) is used to give a short notation of the approximation error when a finite difference is used. To estimate the difference between the solution of an exact and perturbed system of equations we the Euclid norm ( Euclid (365 BC-300 BC ).

2. The solution of a system of linear equations

A system of linear equations can be solved in several ways. Which method is chosen depends on the dimensions of the coefficient matrix. When the dimension is small Cramers's ( Gabriel Cramer (1704-1752)) rule can be used. However for large dimensions this method becomes too expensive with respect to the amount of work. So for large problems the inverse of the matrix can be used, but in many problems (especially if the coefficient matrix is a band matrix) the Gauss elimination method ( Carl Friedrich Gauss (1777-1855)) is preferred. This method is only robust with respect to rounding errors when complete or partial pivotting is used. In general it is difficult to get a good analysis of rounding errors due to floating point arithmetic done by computers. To motivate the study of rounding errors we note that several disasters are originated by rounding errors. Recent examples are: Patriot Missile Failure and the Explosion of the Ariane 5. Some historical notes on matrices and determinants are given here.

3. Eigenvalue problems

Eigenvalue problems are solved using the Power method. This method gives the largest eigenvalue and its corresponding eigenvector. To compute smaller eigenvalues, deflation can be used. When the smallest eigenvalue is necessary it is better to use the inverse Power method.

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Last modified on 02-11-2001 by Kees Vuik