A robust topological derivative-based multi-material optimization approach: Optimality condition and computational algorithm

Topology optimization is a technique in the engineering area that allows obtaining optimal designs of devices, mechanisms, complex structures and even design the microstructure of an auxetic material. Classically, the focus was made on considering the problem of obtaining such designs comprised of o...

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Bibliographic Details
Published inComputer methods in applied mechanics and engineering Vol. 366; p. 113044
Main Authors Romero Onco, A.A., Giusti, S.M.
Format Journal Article
LanguageEnglish
Published Amsterdam Elsevier B.V 01.07.2020
Elsevier BV
Subjects
Algorithms
Domains
Functionals
Level-set method
Multi-material optimization
Nucleation
Optimality condition
Optimization
Piezoelectric actuators
Piezoelectricity
Robustness (mathematics)
Topological derivative
Topology optimization
Optimality condition
Topological derivative
Level-set method
Multi-material optimization
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Summary:Topology optimization is a technique in the engineering area that allows obtaining optimal designs of devices, mechanisms, complex structures and even design the microstructure of an auxetic material. Classically, the focus was made on considering the problem of obtaining such designs comprised of only one material. More recently, some efforts have been made to incorporate more than one material to the optimization problem. The present work addresses the topology optimization problem considering multiple materials on a fixed project domain. For the geometric description of the material domains, the concept of multiple level-sets has been used, meanwhile, its nucleation and evolution are governed by functions constructed from the topological derivative of a functional to be minimized. The topological optimization algorithm developed to solve the multi-material topological optimization problem is described and its optimality condition is well established. Numerical examples applied to planar elasticity, bending plate, bi-dimensional steady-state heat transfer and optimal design of piezoelectric actuator problems are presented. •Multi-material topology optimization using topological derivatives.•Algorithm based on the multi-material level-set method.•Derivation of optimality criteria.•Applications to heat transfer, planar elasticity, bending plates.•Design of multimaterial piezo actuators.
ISSN:0045-7825
1879-2138
DOI:10.1016/j.cma.2020.113044