Numerical solution of boundary value problems in ordinary differential equations

Usmani, Riaz Ahmad

January 1967

In the numerical solution of the two point "boundary value problem, [ equation omitted ] (1) the usual method is to approximate the problem by a finite difference analogue of the form [ equation omitted ] (2) with k = 2, and the truncation error T.E. = O(h⁴) or O(h⁶), where h is the step-size. Varga (1962) has obtained error bounds for the former when the problem (1) is linear and of class M . In this thesis, more accurate finite difference methods are considered. These can be obtained in essentially two different ways, either by increasing the value k in difference equations (2), or by introducing higher order derivatives. Several methods of both types have been derived. Also, it is shown how the initial value problem y' = ϕ(x,y) can be formulated as a two point boundary value problem and solved using the latter approach. Error bounds have been derived for all of these methods for linear problems of class M . In particular, more accurate bounds have been derived than those obtained by Varga (1962) and Aziz and Hubbard (1964). Some error estimates are suggested for the case where [ equation omitted ], but these are not accurate bounds, especially when [ equation omitted ] not a constant. In the case of non-linear differential equations, sufficient conditions are derived for the convergence of the solution of the system of equations (2) by a generalized Newton's method. Some numerical results are included and the observed errors compared with theoretical error bounds. / Science, Faculty of / Mathematics, Department of / Graduate

Boundary value problems

Differential equations

A numerical investigation of two boundary element methods

Quek, Mui Hoon

January 1984

This thesis investigates the viability of two boundary element methods for solving steady state problems, the continuous least squares method and the Galerkin minimization technique. In conventional boundary element methods, the singularities of the fundamental solution involved are usually located at fixed points on the boundary of the problem's domain or on an auxiliary boundary. This leads to some difficulties: when the singularities are located on the problem domain's boundary, it is not easy to evaluate the solution for points on or near that boundary whereas if the singularities are placed on an auxiliary boundary, this auxiliary boundary would have to be carefully chosen. Hence the methods studied here allow the singularities, initially located at some auxiliary boundary, to move until the best positions are found. These positions are determined by attempting to minimize the error via the least squares or the Galerkin technique. This results in a highly accurate, adaptive, but nonlinear method. We study various methods for solving systems of nonlinear equations resulting from the Galerkin technique. A hybrid method has been implemented, which involves the objective function from the least squares method while the gradient is due to the Galerkin method. Numerical examples involving Laplace's equation in two dimensions are presented and results using the discrete least squares method, the continuous least squares method and the Galerkin method are compared and discussed. The continuous least squares method appears to give the best results for the sample problems tried. / Science, Faculty of / Computer Science, Department of / Graduate

Numerical algorithms for the solution of a single phase one-dimensional Stefan problem

Milinazzo, Fausto

January 1974

A one-dimensional, single phase Stefan Problem is considered. This problem is shown to have a unique solution which depends continuously on the boundary data. In addition two algorithms are formulated for its approximate numerical solution. The first algorithm (the Similarity Algorithm), which is based on Similarity, is shown to converge with order of convergence between one half and one. Moreover, numerical examples illustrating various aspects of this algorithm are presented. In particular, modifications to the algorithm which are suggested by the proof of convergence are shown to improve the numerical results significantly. Furthermore, a brief comparison is made between the algorithm and a well-known difference scheme. The second algorithm (a Collocation Scheme) results from an attempt to reduce the problem to a set of ordinary differential equations. It is observed that this set of ordinary differential equations is stiff. Moreover, numerical examples indicate that this is a high order scheme capable of achieving very accurate approximations. It is observed that the apparent stiffness of the system of ordinary differential equations renders this second algorithm relatively inefficient. / Science, Faculty of / Statistics, Department of / Graduate

Boundary value problems

Heat -- Conduction

The numerical solution of two-dimensional problems of the theory of elasticity /

Hulbert, Lewis Eugene

January 1962

No description available.

Education

Elasticity

Boundary value problems

Best least squares solution of two-point boundary value problems

Gentile, Giorlando Enrico.

January 1975

No description available.

Least squares.

Boundary value problems.

The natural convection above a point heat source in a rotating environment.

Ng, Kevin Y. K. (Kevin Yui Ki)

January 1972

No description available.

Heat -- Convection

Boundary value problems

Finite-amplitude vibration of clamped and simply-supported circular plates

Al-Khattat, Ibrahim Mahdi

January 2011

Digitized by Kansas Correctional Industries

Elastic plates and shells--Vibration

Boundary value problems

Some applications of Bessel functions

Unruh, Wilbur Victor.

January 1943

Call number: LD2668 .T4 1943 U5 / Master of Science

Bessel functions.

Boundary value problems.

Masters theses

Integral inequalities and solvability of boundary value problems with p(t)-Laplacian operators

Zhao, Dandan., 趙丹丹.

January 2009

published_or_final_version / Mathematics / Doctoral / Doctor of Philosophy

Integral inequalities.

Boundary value problems.

Laplacian operator.

A vectorised Fourier-Laplace transformation and its application to Green's tensors

Smith, James Raphael

January 1993

No description available.

510

Vector fields; Boundary value problems