AbstractIn this paper, we propose some least-squares finite element procedures for linear and nonlinear parabolic equations based on first-order systems. By selecting the least-squares functional properly each proposed procedure can be split into two independent symmetric positive definite sub-procedures, one of which is for the primary unknown variable u and the other is for the expanded flux unknown variable σ. Optimal order error estimates are developed. Finally we give some numerical examples which are in good agreement with the theoretical analysis
. For least-squares mixed finite element methods for the first-order system formulation of second-or...
Abstract. Least-squares finite element methods (LSFEMs) for scalar linear partial differential equat...
AbstractWe study the primal mixed finite-element approximation of the second-order elliptic problem ...
AbstractIn this paper, we propose some least-squares finite element procedures for linear and nonlin...
An optimal least squares finite element method is proposed for two dimensional and three dimensional...
AbstractA theoretical framework for the least squares solution of first order elliptic systems is pr...
AbstractA least squares finite element scheme for a boundary value problem associated with a second-...
AbstractFully discrete mixed finite element method is considered to approximate the solution of a no...
In this article, an adaptive least-squares mixed finite element method is studied for pseudo-parabol...
Abstract. Least-squares finite element methods for first-order formulations of the Poisson equation ...
. A least-squares mixed finite element formulation is applied to the nonlinear elliptic problems ari...
AbstractMixed finite element methods are considered to approximate the solution of fully nonlinear s...
AbstractIn this paper, we introduce two split least-squares Galerkin finite element procedures for p...
summary:Natural superconvergence of the least-squares finite element method is surveyed for the one-...
AbstractA nonstandard-type “least'squares” finite-element method is proposed for the solution of fir...
. For least-squares mixed finite element methods for the first-order system formulation of second-or...
Abstract. Least-squares finite element methods (LSFEMs) for scalar linear partial differential equat...
AbstractWe study the primal mixed finite-element approximation of the second-order elliptic problem ...
AbstractIn this paper, we propose some least-squares finite element procedures for linear and nonlin...
An optimal least squares finite element method is proposed for two dimensional and three dimensional...
AbstractA theoretical framework for the least squares solution of first order elliptic systems is pr...
AbstractA least squares finite element scheme for a boundary value problem associated with a second-...
AbstractFully discrete mixed finite element method is considered to approximate the solution of a no...
In this article, an adaptive least-squares mixed finite element method is studied for pseudo-parabol...
Abstract. Least-squares finite element methods for first-order formulations of the Poisson equation ...
. A least-squares mixed finite element formulation is applied to the nonlinear elliptic problems ari...
AbstractMixed finite element methods are considered to approximate the solution of fully nonlinear s...
AbstractIn this paper, we introduce two split least-squares Galerkin finite element procedures for p...
summary:Natural superconvergence of the least-squares finite element method is surveyed for the one-...
AbstractA nonstandard-type “least'squares” finite-element method is proposed for the solution of fir...
. For least-squares mixed finite element methods for the first-order system formulation of second-or...
Abstract. Least-squares finite element methods (LSFEMs) for scalar linear partial differential equat...
AbstractWe study the primal mixed finite-element approximation of the second-order elliptic problem ...