Add to ORKGThe main focus of this work lies in the simulation of the deformation of mechanical components which consist of nonlinear elastic, incompressible material and that are subject to large deformations. Starting from a nonlinear formulation one can derive a discrete problem by using linearisation techniques and an adaptive mixed finite element method. This turns out to be a saddle point problem that can be solved via a Bramble-Pasciak conjugate gradient method. With some modifications the simulation can be improved.:1. Introduction 2. Basics 3. Mixed variational formulation 4. Solution method 5. Error estimation 6. LBB conditions 7. Improvement suggestion
© Published under licence by IOP Publishing Ltd. The work is concerned with development of algorithm...
A least-squares mixed finite element method for linear elasticity, based on a stress-displacement fo...
In this work, we bridge standard Adaptive Mesh Refinement and coarsening (AMR) on scalable octree ba...
The main focus of this work lies in the simulation of the deformation of mechanical components which...
The main focus of this work lies in the simulation of the deformation of mechanical components which...
This thesis investigates the numerical simulation of three-dimensional, mechanical deformation probl...
This thesis investigates the numerical simulation of three-dimensional, mechanical deformation probl...
Fast simulation of (nearly) incompressible nonlinear elastic material at large strain via adaptive m...
The subject of this thesis are adaptive mixed finite element methods for incompressible and nearly i...
This thesis investigates the numerical simulation of three-dimensional, mechanical deformation probl...
Abstract. A nite element method is considered for dealing with nearly in-compressible material. In t...
Several finite element methods for large deformation elastic problems in the nearly incompressible a...
Several finite element methods for large deformation elastic problems in the nearly incompressible a...
In this note a mixed finite element formulation is described for coping with (nearly) incompressible...
© Published under licence by IOP Publishing Ltd. The work is concerned with development of algorithm...
© Published under licence by IOP Publishing Ltd. The work is concerned with development of algorithm...
A least-squares mixed finite element method for linear elasticity, based on a stress-displacement fo...
In this work, we bridge standard Adaptive Mesh Refinement and coarsening (AMR) on scalable octree ba...
The main focus of this work lies in the simulation of the deformation of mechanical components which...
The main focus of this work lies in the simulation of the deformation of mechanical components which...
This thesis investigates the numerical simulation of three-dimensional, mechanical deformation probl...
This thesis investigates the numerical simulation of three-dimensional, mechanical deformation probl...
Fast simulation of (nearly) incompressible nonlinear elastic material at large strain via adaptive m...
The subject of this thesis are adaptive mixed finite element methods for incompressible and nearly i...
This thesis investigates the numerical simulation of three-dimensional, mechanical deformation probl...
Abstract. A nite element method is considered for dealing with nearly in-compressible material. In t...
Several finite element methods for large deformation elastic problems in the nearly incompressible a...
Several finite element methods for large deformation elastic problems in the nearly incompressible a...
In this note a mixed finite element formulation is described for coping with (nearly) incompressible...
© Published under licence by IOP Publishing Ltd. The work is concerned with development of algorithm...
© Published under licence by IOP Publishing Ltd. The work is concerned with development of algorithm...
A least-squares mixed finite element method for linear elasticity, based on a stress-displacement fo...
In this work, we bridge standard Adaptive Mesh Refinement and coarsening (AMR) on scalable octree ba...