Add to ORKGThis paper illustrates the use of an adaptive finite element method to solve a non-linear singularly perturbed boundary value problem which arises from a one-dimensional q-tensor model of liquid crystals. The adaptive non-uniform mesh is generated by equidistribution of a strictly positive monitor function which is a linear combination of a constant floor and a power of the first derivative of the numerical solution. by an appropriate selection of the monitor function parameters, we show that the computed numerical soluction converges at an otimal rate with respect to the mesh density and that the solution accuracy is robust to the size of singular perturbation paramete
We develop a fast and accurate approximation of the normally stiff equations which minimize the Land...
This paper investigates energy-minimization finite-element approaches for the com-putation of nemati...
Abstract. This paper investigates energy-minimization finite-element approaches for the com-putation...
AbstractThis paper illustrates the use of an adaptive finite element method to solve a non-linear si...
This paper illustrates the use of an adaptive finite element method to solve a non-linear singularly...
In this paper we illustrate the suitability of an adaptive moving mesh method for modelling a one-di...
This paper illustrates the use of moving mesh methods for solving partial differential equation (PDE...
This paper describes a robust and efficient numerical scheme for solving the system of six coupled p...
This thesis investigates numerical methods for various Q-tensor models of nematic liquid crystals. O...
The properties of liquid crystals can be modelled using an order parameter which describes the varia...
International audienceThis paper presents a 3D mesh adaptivity strategy on unstructured tetrahedral ...
AbstractNematic liquid crystals are aggregates of calamitic molecules and most related experimental ...
Nematic liquid crystals, hierarchic finite elements, adaptive meshes. Numerical models of liquid cry...
We analyse an energy minimisation problem recently proposed for modelling smectic-A liquid crystals....
In this paper, we develop a unified framework for the a priori and a posteriori error control of dif...
We develop a fast and accurate approximation of the normally stiff equations which minimize the Land...
This paper investigates energy-minimization finite-element approaches for the com-putation of nemati...
Abstract. This paper investigates energy-minimization finite-element approaches for the com-putation...
AbstractThis paper illustrates the use of an adaptive finite element method to solve a non-linear si...
This paper illustrates the use of an adaptive finite element method to solve a non-linear singularly...
In this paper we illustrate the suitability of an adaptive moving mesh method for modelling a one-di...
This paper illustrates the use of moving mesh methods for solving partial differential equation (PDE...
This paper describes a robust and efficient numerical scheme for solving the system of six coupled p...
This thesis investigates numerical methods for various Q-tensor models of nematic liquid crystals. O...
The properties of liquid crystals can be modelled using an order parameter which describes the varia...
International audienceThis paper presents a 3D mesh adaptivity strategy on unstructured tetrahedral ...
AbstractNematic liquid crystals are aggregates of calamitic molecules and most related experimental ...
Nematic liquid crystals, hierarchic finite elements, adaptive meshes. Numerical models of liquid cry...
We analyse an energy minimisation problem recently proposed for modelling smectic-A liquid crystals....
In this paper, we develop a unified framework for the a priori and a posteriori error control of dif...
We develop a fast and accurate approximation of the normally stiff equations which minimize the Land...
This paper investigates energy-minimization finite-element approaches for the com-putation of nemati...
Abstract. This paper investigates energy-minimization finite-element approaches for the com-putation...