Abstract. In this paper, we revisit an auxiliary space preconditioning method proposed by Xu [Computing 56, 1996], in which low-order finite element spaces are employed as auxiliary spaces for solving linear algebraic systems arising from high-order finite element discretizations. We provide a new convergence rate estimate and parallel implementation of the proposed algorithm. We show that this method is user-friendly and can play an important role in a variety of Poisson-based solvers for more challenging problems such as the Navier– Stokes equation. We investigate the performance of the proposed algorithm using the Poisson equation and the Stokes equation on 3D unstructured grids. Numerical results demonstrate the advantages of the propos...
An algebraic linelet preconditioner is presented, which works in parallel regardless of the mesh’s ...
Solving the linear elasticity and Stokes equations by an optimal domain decomposition method derived...
We propose a family of preconditioners for linear systems of equations arising from a piecewise poly...
We introduce a two-level preconditioner for the efficient solution of large scale saddle-point linea...
High-order spectral element methods (SEM) while very accurate for computational fluid dynamics (CFD)...
We are interested in the numerical solution of the unsteady Navier–Stokes equations on large scale p...
This paper presents detailed aspects regarding the implementation of the Finite Element Method (FEM)...
Preconditioning for the Pressure Poisson Equation, used with the fractional step Navier--Stokes solv...
This paper presents an efficient numerical solver for the finite element approximation of the incomp...
We outline a new class of robust and efficient methods for solving subproblems that arise in the lin...
We analyze a class of modified augmented Lagrangian-based preconditioners for both stable and stabil...
We study a parallel implementation of different preconditioning techniques for the iterative solutio...
We derive and analyze a block diagonal preconditioner for the linear problems arising from a discon...
We present optimal preconditioners for a recently introduced hybridized discontinuous Galerkin finit...
An algebraic linelet preconditioner is presented, which works in parallel regardless of the mesh’s ...
Solving the linear elasticity and Stokes equations by an optimal domain decomposition method derived...
We propose a family of preconditioners for linear systems of equations arising from a piecewise poly...
We introduce a two-level preconditioner for the efficient solution of large scale saddle-point linea...
High-order spectral element methods (SEM) while very accurate for computational fluid dynamics (CFD)...
We are interested in the numerical solution of the unsteady Navier–Stokes equations on large scale p...
This paper presents detailed aspects regarding the implementation of the Finite Element Method (FEM)...
Preconditioning for the Pressure Poisson Equation, used with the fractional step Navier--Stokes solv...
This paper presents an efficient numerical solver for the finite element approximation of the incomp...
We outline a new class of robust and efficient methods for solving subproblems that arise in the lin...
We analyze a class of modified augmented Lagrangian-based preconditioners for both stable and stabil...
We study a parallel implementation of different preconditioning techniques for the iterative solutio...
We derive and analyze a block diagonal preconditioner for the linear problems arising from a discon...
We present optimal preconditioners for a recently introduced hybridized discontinuous Galerkin finit...
An algebraic linelet preconditioner is presented, which works in parallel regardless of the mesh’s ...
Solving the linear elasticity and Stokes equations by an optimal domain decomposition method derived...
We propose a family of preconditioners for linear systems of equations arising from a piecewise poly...