An adaptive multilevel approach to parabolic equations I. General theory and 1D implementation

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Abstract

A new adaptive multilevel approach for parabolic PDEs is presented. Full adaptivity of the algorithm is realized by combining multilevel time discretization, better known as extrapolation methods, and multilevel finite element space discretization. In the theoretical part of the paper the existence of asymptotic expansions in terms of time steps for single-step methods in Hilbert space is established. Finite element approximation then leads to perturbed expansions, whose perturbations, however, can be pushed below a necessary level by means of an adaptive grid control. The theoretical presentation is independent of space dimension. This paper details the algorithm, and numerical examples are given for the 1D case only. The numerical results clearly show the significant perspectives opened by the new algorithmic approach.

Original languageEnglish
Pages (from-to)279-317
Number of pages39
JournalIMPACT of Computing in Science and Engineering
Volume2
Issue number4
DOIs
StatePublished - Dec 1990
Externally publishedYes

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