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Aspects of interval analysis applied to initial-value problems for ordinary differential equations and hyperbolic partial differential equations

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dc.contributor.advisor Bishop, N. T.
dc.contributor.advisor Wright, C. J.
dc.contributor.author Anguelov, Roumen Anguelov en
dc.date.accessioned 2015-01-23T04:24:21Z
dc.date.available 2015-01-23T04:24:21Z
dc.date.issued 1998-09 en
dc.identifier.citation Anguelov, Roumen Anguelov (1998) Aspects of interval analysis applied to initial-value problems for ordinary differential equations and hyperbolic partial differential equations, University of South Africa, Pretoria, <http://hdl.handle.net/10500/17723> en
dc.identifier.uri http://hdl.handle.net/10500/17723
dc.description.abstract Interval analysis is an essential tool in the construction of validated numerical solutions of Initial Value Problems (IVP) for Ordinary (ODE) and Partial (PDE) Differential Equations. A validated solution typically consists of guaranteed lower and upper bounds for the exact solution or set of exact solutions in the case of uncertain data, i.e. it is an interval function (enclosure) containing all solutions of the problem. IVP for ODE: The central point of discussion is the wrapping effect. A new concept of wrapping function is introduced and applied in studying this effect. It is proved that the wrapping function is the limit of the enclosures produced by any method of certain type (propagate and wrap type). Then, the wrapping effect can be quantified as the difference between the wrapping function and the optimal interval enclosure of the solution set (or some norm of it). The problems with no wrapping effect are characterized as problems for which the wrapping function equals the optimal interval enclosure. A sufficient condition for no wrapping effect is that there exist a linear transformation, preserving the intervals, which reduces the right-hand side of the system of ODE to a quasi-isotone function. This condition is also necessary for linear problems and "near" necessary in the general case. Hyperbolic PDE: The Initial Value Problem with periodic boundary conditions for the wave equation is considered. It is proved that under certain conditions the problem is an operator equation with an operator of monotone type. Using the established monotone properties, an interval (validated) method for numerical solution of the problem is proposed. The solution is obtained step by step in the time dimension as a Fourier series of the space variable and a polynomial of the time variable. The numerical implementation involves computations in Fourier and Taylor functoids. Propagation of discontinuo~swaves is a serious problem when a Fourier series is used (Gibbs phenomenon, etc.). We propose the combined use of periodic splines and Fourier series for representing discontinuous functions and a method for propagating discontinuous waves. The numerical implementation involves computations in a Fourier hyper functoid.
dc.format.extent 1 online resource (iii, 153 leaves) en
dc.language.iso en
dc.subject Validated methods
dc.subject Interval methods
dc.subject Enclosure methods
dc.subject Ordinary differential equations
dc.subject Partial differential equations
dc.subject Wrapping effect
dc.subject Wrapping function
dc.subject Functoid
dc.subject Fourier hyper functoid
dc.subject.ddc 511.42 en
dc.subject.lcsh Differential equations, Partial en
dc.title Aspects of interval analysis applied to initial-value problems for ordinary differential equations and hyperbolic partial differential equations en
dc.type Thesis
dc.description.department Mathematical Sciences
dc.description.degree D. Phil. (Mathematics) en


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