Flip procedure in geometric approximation of multiple-component shapes – Application to multiple-inclusion detection

Pierre Bonnelie; Loïc Bourdin; Fabien Caubet; Olivier Ruatta

doi:10.5802/smai-jcm.16

Pierre Bonnelie ¹; Loïc Bourdin ¹; Fabien Caubet ²; Olivier Ruatta ¹

¹ Institut de recherche XLIM. Pôle Mathématiques-Informatique-Image. UMR CNRS 7252. Université de Limoges, France.
² Institut de Mathématiques de Toulouse. UMR CNRS 5219. Université de Toulouse, France.

The SMAI Journal of computational mathematics, Volume 2 (2016), pp. 255-276.

Abstract

We are interested in geometric approximation by parameterization of two-dimensional multiple-component shapes, in particular when the number of components is a priori unknown. Starting a standard method based on successive shape deformations with a one-component initial shape in order to approximate a multiple-component target shape usually leads the deformation flow to make the boundary evolve until it surrounds all the components of the target shape. This classical phenomenon tends to create double points on the boundary of the approximated shape.

In order to improve the approximation of multiple-component shapes (without any knowledge on the number of components in advance), we use in this paper a piecewise Bézier parameterization and we consider two procedures called intersecting control polygons detection and flip procedure. The first one allows to prevent potential collisions between two parts of the boundary of the approximated shape, and the second one permits to change its topology by dividing a one-component shape into a two-component shape.

For an experimental purpose, we include these two processes in a basic geometrical shape optimization algorithm and test it on the classical inverse obstacle problem. This new approach allows to obtain a numerical approximation of the unknown inclusion, detecting both the topology (i.e. the number of connected components) and the shape of the obstacle. Several numerical simulations are performed.

Published online: 2016-12-04

MR Zbl

DOI: 10.5802/smai-jcm.16

Classification: 68U05, 68W25, 49Q10, 65N21
Keywords: Shape approximation; free-form shapes; multiple-component shapes; Bézier curves; intersecting control polygons detection; flip procedure; inverse obstacle problem; shape optimization

Author's affiliations:

Pierre Bonnelie ¹; Loïc Bourdin ¹; Fabien Caubet ²; Olivier Ruatta ¹

¹ Institut de recherche XLIM. Pôle Mathématiques-Informatique-Image. UMR CNRS 7252. Université de Limoges, France.
² Institut de Mathématiques de Toulouse. UMR CNRS 5219. Université de Toulouse, France.

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     author = {Pierre Bonnelie and Lo{\"\i}c Bourdin and Fabien Caubet and Olivier Ruatta},
     title = {Flip procedure in geometric approximation of multiple-component shapes {\textendash} {Application} to multiple-inclusion detection},
     journal = {The SMAI Journal of computational mathematics},
     pages = {255--276},
     publisher = {Soci\'et\'e de Math\'ematiques Appliqu\'ees et Industrielles},
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     year = {2016},
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Pierre Bonnelie; Loïc Bourdin; Fabien Caubet; Olivier Ruatta. Flip procedure in geometric approximation of multiple-component shapes – Application to multiple-inclusion detection. The SMAI Journal of computational mathematics, Volume 2 (2016), pp. 255-276. doi : 10.5802/smai-jcm.16. https://smai-jcm.centre-mersenne.org/articles/10.5802/smai-jcm.16/

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