We solve the problem of finding and justifying an optimal fully discrete finite-element procedure for approximating annulus-like, possibly unstable, minimal surfaces. In a previous paper we introduced the general framework, obtained some preliminary estimates, developed the ideas used for the algorithm, and gave numerical results. In this paper we prove convergence estimates
Abstract. We discuss the Douglas–Rachford algorithm to solve the feasibility problem for two closed ...
International audienceWe focus on the Discrete Duality Finite Volume (DDFV) method whose particulari...
We address the numerical approximation by finite-element methods of an optimal design problem for a ...
Abstract. We solve the problem of finding and justifying an optimal fully discrete finite element pr...
We solve the problem of finding and justifying an optimal fully discrete finite element procedure fo...
We solve the problem of finding and justifying an optimal fully discrete finite element procedure fo...
We prove optimal convergence results for discrete approximations to (possibly unstable) minimal surf...
In this paper we prove the L² convergence rates for a fully discrete finite element procedure for a...
This paper proposes an algorithm for solving structured optimization problems, which covers both the...
This work is concerned with the approximation and the numerical computation of polygonal minimal sur...
We present a finite element discretization scheme for the compressible and incompressible elasticity...
International audienceWe discuss the Douglas–Rachford algorithm to solve the feasibility problem for...
This work is concerned with the convergence behavior of the solutions to parametric variational prob...
We propose and analyze a fully discrete finite element scheme for the phase field model describing t...
The Douglas–Rachford algorithm is a classical and very successful method for solving optimization an...
Abstract. We discuss the Douglas–Rachford algorithm to solve the feasibility problem for two closed ...
International audienceWe focus on the Discrete Duality Finite Volume (DDFV) method whose particulari...
We address the numerical approximation by finite-element methods of an optimal design problem for a ...
Abstract. We solve the problem of finding and justifying an optimal fully discrete finite element pr...
We solve the problem of finding and justifying an optimal fully discrete finite element procedure fo...
We solve the problem of finding and justifying an optimal fully discrete finite element procedure fo...
We prove optimal convergence results for discrete approximations to (possibly unstable) minimal surf...
In this paper we prove the L² convergence rates for a fully discrete finite element procedure for a...
This paper proposes an algorithm for solving structured optimization problems, which covers both the...
This work is concerned with the approximation and the numerical computation of polygonal minimal sur...
We present a finite element discretization scheme for the compressible and incompressible elasticity...
International audienceWe discuss the Douglas–Rachford algorithm to solve the feasibility problem for...
This work is concerned with the convergence behavior of the solutions to parametric variational prob...
We propose and analyze a fully discrete finite element scheme for the phase field model describing t...
The Douglas–Rachford algorithm is a classical and very successful method for solving optimization an...
Abstract. We discuss the Douglas–Rachford algorithm to solve the feasibility problem for two closed ...
International audienceWe focus on the Discrete Duality Finite Volume (DDFV) method whose particulari...
We address the numerical approximation by finite-element methods of an optimal design problem for a ...