Improving multiresolution topology optimization via multiple discretizations

Tam H. Nguyen; Glaucio H. Paulino; Junho Song; Chau H. Le

doi:10.1002/nme.4344

Improving multiresolution topology optimization via multiple discretizations

Tam H. Nguyen, Glaucio H. Paulino, Junho Song, Chau H. Le

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

Abstract

Unlike the traditional topology optimization approach that uses the same discretization for finite element analysis and design optimization, this paper proposes a framework for improving multiresolution topology optimization (iMTOP) via multiple distinct discretizations for: (1) finite elements; (2) design variables; and (3) density. This approach leads to high fidelity resolution with a relatively low computational cost. In addition, an adaptive multiresolution topology optimization (AMTOP) procedure is introduced, which consists of selective adjustment and refinement of design variable and density fields. Various two-dimensional and three-dimensional numerical examples demonstrate that the proposed schemes can significantly reduce computational cost in comparison to the existing element-based approach.

Original language	English (US)
Pages (from-to)	507-530
Number of pages	24
Journal	International Journal for Numerical Methods in Engineering
Volume	92
Issue number	6
DOIs	https://doi.org/10.1002/nme.4344
State	Published - Nov 9 2012
Externally published	Yes

Keywords

Adaptive optimization
Density mesh
Design variable
Finite elements
Multiresolution
Multiresolution topology optimization (MTOP)

ASJC Scopus subject areas

Numerical Analysis
Engineering(all)
Applied Mathematics

Online availability

10.1002/nme.4344

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title = "Improving multiresolution topology optimization via multiple discretizations",

abstract = "Unlike the traditional topology optimization approach that uses the same discretization for finite element analysis and design optimization, this paper proposes a framework for improving multiresolution topology optimization (iMTOP) via multiple distinct discretizations for: (1) finite elements; (2) design variables; and (3) density. This approach leads to high fidelity resolution with a relatively low computational cost. In addition, an adaptive multiresolution topology optimization (AMTOP) procedure is introduced, which consists of selective adjustment and refinement of design variable and density fields. Various two-dimensional and three-dimensional numerical examples demonstrate that the proposed schemes can significantly reduce computational cost in comparison to the existing element-based approach.",

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AU - Nguyen, Tam H.

AU - Paulino, Glaucio H.

AU - Song, Junho

AU - Le, Chau H.

PY - 2012/11/9

Y1 - 2012/11/9

N2 - Unlike the traditional topology optimization approach that uses the same discretization for finite element analysis and design optimization, this paper proposes a framework for improving multiresolution topology optimization (iMTOP) via multiple distinct discretizations for: (1) finite elements; (2) design variables; and (3) density. This approach leads to high fidelity resolution with a relatively low computational cost. In addition, an adaptive multiresolution topology optimization (AMTOP) procedure is introduced, which consists of selective adjustment and refinement of design variable and density fields. Various two-dimensional and three-dimensional numerical examples demonstrate that the proposed schemes can significantly reduce computational cost in comparison to the existing element-based approach.

AB - Unlike the traditional topology optimization approach that uses the same discretization for finite element analysis and design optimization, this paper proposes a framework for improving multiresolution topology optimization (iMTOP) via multiple distinct discretizations for: (1) finite elements; (2) design variables; and (3) density. This approach leads to high fidelity resolution with a relatively low computational cost. In addition, an adaptive multiresolution topology optimization (AMTOP) procedure is introduced, which consists of selective adjustment and refinement of design variable and density fields. Various two-dimensional and three-dimensional numerical examples demonstrate that the proposed schemes can significantly reduce computational cost in comparison to the existing element-based approach.

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KW - Density mesh

KW - Design variable

KW - Finite elements

KW - Multiresolution

KW - Multiresolution topology optimization (MTOP)

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Improving multiresolution topology optimization via multiple discretizations

Abstract

Keywords

ASJC Scopus subject areas

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