Add to ORKGThe finite element discretization of the incompressible steady-state Navier-Stokes equations yields a non-linear problem, due to the convective terms in the momentum equations. Several methods may be used to solve this non-linear problem. In this work we study Inexact Newton-type methods, associated with the SUPG/PSPG stabilized finite element formulation. The resulting systems of equations are solved iteratively by a preconditioned Krylov-space method such as GMRES. Numerical experiments are shown to validate our approach. Performance of the nonlinear strategies is accessed by numerical tests. We concluded that Inexact Newton-type methods are more efficient than conventional Newton-type methods
In this work we study the numerical solution of nonlinear systems arising from stabilized FEM discre...
In this paper we present effective preconditioning techniques for solving the nonsymmetric systems t...
We analyze a class of modified augmented Lagrangian-based preconditioners for both stable and stabil...
Abstract. Globalized inexact Newton methods are well suited for solving large-scale systems of nonli...
The solution of the governing steady transport equations for momentum, heat and mass transfer in flo...
This thesis approaches the solution of the linearized finite element discretization of the Navier-St...
Abstract. The parallel edge-based solution of 3D incompressible Navier-Stokes equations is presented...
Finite element methods with stabilization techniques for the stationary Navier–Stokes equations are ...
Fully coupled, Newton-Krylov algorithms are investigated for solving strongly coupled, nonlinear sys...
We discuss in this paper some implementation aspects of a finite element formulation for the incompr...
This tutorial for the deal.II finite element library demonstrates efficient linear and nonlinear sol...
This paper deals with fast and reliable numerical solution methods for the incompressible non-Newton...
grantor: University of TorontoAn efficient inexact-Newton-Krylov algorithm is presented fo...
Abstract. Inexact Newton algorithms are commonly used for solving large sparse nonlinear system of e...
The cG(1)cG(1)-method is a finite element method for solving the incompressible Navier-Stokes equati...
In this work we study the numerical solution of nonlinear systems arising from stabilized FEM discre...
In this paper we present effective preconditioning techniques for solving the nonsymmetric systems t...
We analyze a class of modified augmented Lagrangian-based preconditioners for both stable and stabil...
Abstract. Globalized inexact Newton methods are well suited for solving large-scale systems of nonli...
The solution of the governing steady transport equations for momentum, heat and mass transfer in flo...
This thesis approaches the solution of the linearized finite element discretization of the Navier-St...
Abstract. The parallel edge-based solution of 3D incompressible Navier-Stokes equations is presented...
Finite element methods with stabilization techniques for the stationary Navier–Stokes equations are ...
Fully coupled, Newton-Krylov algorithms are investigated for solving strongly coupled, nonlinear sys...
We discuss in this paper some implementation aspects of a finite element formulation for the incompr...
This tutorial for the deal.II finite element library demonstrates efficient linear and nonlinear sol...
This paper deals with fast and reliable numerical solution methods for the incompressible non-Newton...
grantor: University of TorontoAn efficient inexact-Newton-Krylov algorithm is presented fo...
Abstract. Inexact Newton algorithms are commonly used for solving large sparse nonlinear system of e...
The cG(1)cG(1)-method is a finite element method for solving the incompressible Navier-Stokes equati...
In this work we study the numerical solution of nonlinear systems arising from stabilized FEM discre...
In this paper we present effective preconditioning techniques for solving the nonsymmetric systems t...
We analyze a class of modified augmented Lagrangian-based preconditioners for both stable and stabil...