Thickness control in structural optimization via a level set method

G. Allaire; F. Jouve; G. Michailidis

doi:10.1007/s00158-016-1453-y

Thickness control in structural optimization via a level set method

G. Allaire
, F. Jouve
, G. Michailidis

UPMC Université de Paris VI
Ecole polytechnique
Renault

Research output: Contribution to journal › Article › peer-review

Abstract

In the context of structural optimization via a level-set method we propose a framework to handle geometric constraints related to a notion of local thickness. The local thickness is calculated using the signed distance function to the shape. We formulate global constraints using integral functionals and compute their shape derivatives. We discuss different strategies and possible approximations to handle the geometric constraints. We implement our approach in two and three space dimensions for a model of linearized elasticity. As can be expected, the resulting optimized shapes are strongly dependent on the initial guesses and on the specific treatment of the constraints since, in particular, some topological changes may be prevented by those constraints.

Original language	English
Pages (from-to)	1349-1382
Number of pages	34
Journal	Structural and Multidisciplinary Optimization
Volume	53
Issue number	6
DOIs	https://doi.org/10.1007/s00158-016-1453-y
Publication status	Published - 1 Jun 2016

Keywords

Level-set method
Shape and topology optimization
Signed distance function
Thickness control

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10.1007/s00158-016-1453-y

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keywords = "Level-set method, Shape and topology optimization, Signed distance function, Thickness control",

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AU - Michailidis, G.

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N2 - In the context of structural optimization via a level-set method we propose a framework to handle geometric constraints related to a notion of local thickness. The local thickness is calculated using the signed distance function to the shape. We formulate global constraints using integral functionals and compute their shape derivatives. We discuss different strategies and possible approximations to handle the geometric constraints. We implement our approach in two and three space dimensions for a model of linearized elasticity. As can be expected, the resulting optimized shapes are strongly dependent on the initial guesses and on the specific treatment of the constraints since, in particular, some topological changes may be prevented by those constraints.

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KW - Shape and topology optimization

KW - Signed distance function

KW - Thickness control

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JO - Structural and Multidisciplinary Optimization

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ER -

Thickness control in structural optimization via a level set method

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Keywords

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