We use a local orthogonal decomposition (LOD) technique to derive a finite element method for planar linear elasticity problems with strongly heterogeneous material data and inhomogeneous Dirichlet and Neumann boundary conditions. These problems are becoming more and more relevant due to the increasing use of composite materials. We apply our generalized finite element method in numerical experiments and observe opti-mal convergence rates in the energy norm. We also prove an a posteriori error estimate for the method and use it to propose a basic adaptive algorithm for error reduction
The simulation of the behavior of heterogeneous and composite materials poses a number of challenges...
The application behind the subject of this thesis are multiscale simulations on highly heterogeneous...
In this paper we propose and analyze a localized orthogonal decomposition (LOD) method for solving s...
We use a local orthogonal decomposition (LOD) technique to derive a finite element method for planar...
We propose a generalized finite element method for linear elasticity equations with highly varying a...
We propose and analyze a generalized finite element method designed for linear quasistatic thermoela...
We propose and analyze a generalized finite element method designed for linear quasistatic thermoela...
In this work we extend the multiscale finite element method (MsFEM) as formulated by Hou and Wu in ...
In this paper we present algorithms for an efficient implementation of the Localized Orthogonal Deco...
We extend the multiscale finite element method (MsFEM) as formulated by Hou and Wu in [Hou T.Y., Wu ...
We extend the multiscale finite element method with oscillatory boundary conditions, introduced for ...
We consider a large-scale quadratic eigenvalue problem (QEP), formulated using P1 finite elements on...
We consider a large-scale quadratic eigenvalue problem (QEP), formulated using P1 finite e...
A linear nonconforming (conforming) displacement finite element method for the pure displacement (pu...
This work proposes a family of multiscale hybrid-mixed methods for the two-dimensional linear elasti...
The simulation of the behavior of heterogeneous and composite materials poses a number of challenges...
The application behind the subject of this thesis are multiscale simulations on highly heterogeneous...
In this paper we propose and analyze a localized orthogonal decomposition (LOD) method for solving s...
We use a local orthogonal decomposition (LOD) technique to derive a finite element method for planar...
We propose a generalized finite element method for linear elasticity equations with highly varying a...
We propose and analyze a generalized finite element method designed for linear quasistatic thermoela...
We propose and analyze a generalized finite element method designed for linear quasistatic thermoela...
In this work we extend the multiscale finite element method (MsFEM) as formulated by Hou and Wu in ...
In this paper we present algorithms for an efficient implementation of the Localized Orthogonal Deco...
We extend the multiscale finite element method (MsFEM) as formulated by Hou and Wu in [Hou T.Y., Wu ...
We extend the multiscale finite element method with oscillatory boundary conditions, introduced for ...
We consider a large-scale quadratic eigenvalue problem (QEP), formulated using P1 finite elements on...
We consider a large-scale quadratic eigenvalue problem (QEP), formulated using P1 finite e...
A linear nonconforming (conforming) displacement finite element method for the pure displacement (pu...
This work proposes a family of multiscale hybrid-mixed methods for the two-dimensional linear elasti...
The simulation of the behavior of heterogeneous and composite materials poses a number of challenges...
The application behind the subject of this thesis are multiscale simulations on highly heterogeneous...
In this paper we propose and analyze a localized orthogonal decomposition (LOD) method for solving s...