The h-p version of the finite element method for parabolic equations. II. The h-p version in time

The paper is the first in the series addressing the h-p version of the finite element method for parabolic equations. The h-p version is applied to both time and space variables. The present paper addresses the case when in time the p-version with one single time element is used. Error estimation is

The paper addresses the performance of square elements of type Q ( p ) and Q'(p). ( Q ( p ) and Q ' ( p ) are elements of degree p, analogous to the well-known 9-and 8-noded elements for p = 2.) The performance is analysed theoretically for the class of analytic functions. Numerical experiments conf

An adaptive solver for large-scale hierarchic finite element systems has been developed. A decision-making methodology aimed at selecting an optimal solution strategy on the basis of estimated conditioning, sparsity and memory requirements for a given problem has been devised. Numerical experiments

Two practical and effective, h-~p-type. finite element adaptive procedures are presented. The procedures allow not only the final global energy norni error to be well estimated using hierarchic p-refinement, but in addition give a nearly optimal mesh. The de'sign of this is guided by the local infor

A multilevel iteration scheme is utilized in the solution of equations resulting from the p-version of the finite element method. The advantage of this approach is that it is possible to attain the speed of multigrid techniques in the solution of systems of equations without generating a sequence of