Add to ORKGIn this article, we consider the problem of optimal design of a compliant structure under a volume constraint, within the framework of linear elasticity. We introduce the pure displacement and the dual mixed formulations of the linear elasticity problem and we compute the volumetric expressions of the shape gradient of the compliance by means of the velocity method. A preliminary qualitative comparison of the two expressions of the shape gradient is performed through some numerical simulations using the Boundary Variation Algorithm
Gradient-based shape optimization strategies rely on the computation of the so-called shape gradient...
We describe numerical analysis methods for multiobjective shape optimization of linear elastic struc...
We describe numerical analysis methods for multiobjective shape optimization of linear elastic struc...
In this article, we consider the problem of optimal design of a compliant structure under a volume c...
In this article, we consider the problem of optimal design of a compliant structure under a volume c...
In this article, we consider the problem of optimal design of a compliant structure under a volume c...
In this article, we consider the problem of optimal design of a compliant structure under a volume c...
In this article, we consider the problem of optimal design of a compliant structure under a volume c...
The main purpose of this article is to present a numerical method for geometrical shape optimization...
The main purpose of this article is to present a numerical method for geometrical shape optimization...
We describe numerical analysis methods for multiobjective shape optimization of linear elastic struc...
Gradient-based shape optimization strategies rely on the computation of the so-called shape gradient...
Gradient-based shape optimization strategies rely on the computation of the so-called shape gradient...
Gradient-based shape optimization strategies rely on the computation of the so-called shape gradient...
Gradient-based shape optimization strategies rely on the computation of the so-called shape gradient...
Gradient-based shape optimization strategies rely on the computation of the so-called shape gradient...
We describe numerical analysis methods for multiobjective shape optimization of linear elastic struc...
We describe numerical analysis methods for multiobjective shape optimization of linear elastic struc...
In this article, we consider the problem of optimal design of a compliant structure under a volume c...
In this article, we consider the problem of optimal design of a compliant structure under a volume c...
In this article, we consider the problem of optimal design of a compliant structure under a volume c...
In this article, we consider the problem of optimal design of a compliant structure under a volume c...
In this article, we consider the problem of optimal design of a compliant structure under a volume c...
The main purpose of this article is to present a numerical method for geometrical shape optimization...
The main purpose of this article is to present a numerical method for geometrical shape optimization...
We describe numerical analysis methods for multiobjective shape optimization of linear elastic struc...
Gradient-based shape optimization strategies rely on the computation of the so-called shape gradient...
Gradient-based shape optimization strategies rely on the computation of the so-called shape gradient...
Gradient-based shape optimization strategies rely on the computation of the so-called shape gradient...
Gradient-based shape optimization strategies rely on the computation of the so-called shape gradient...
Gradient-based shape optimization strategies rely on the computation of the so-called shape gradient...
We describe numerical analysis methods for multiobjective shape optimization of linear elastic struc...
We describe numerical analysis methods for multiobjective shape optimization of linear elastic struc...