CMA-ES-based topology optimization accelerated by spectral level-set-boundary modeling

CMA-ES-based topology optimization accelerated by spectral level-set-boundary modeling

Topology optimization commonly encounters several challenges, such as ill-posedness, grayscale issues, interdependencies among design variables, multimodality, and the curse of dimensionality. Furthermore, addressing the latter two concurrently presents considerable difficulty. In this study, we int...

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Bibliographic Details
Published in:Computer methods in applied mechanics and engineering Vol. 432; p. 117331
Main Authors: Tanaka, Shin, Fujii, Garuda
Format: Journal Article
Language:English
Published: Elsevier B.V 01-12-2024
Subjects:
Body-fitted mesh
CMA-ES
Explicit boundary modeling
Perimeter constraint
Spectral level-set method
Topology optimization
Explicit boundary modeling
Topology optimization
Spectral level-set method
Body-fitted mesh
CMA-ES
Perimeter constraint
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Summary:Topology optimization commonly encounters several challenges, such as ill-posedness, grayscale issues, interdependencies among design variables, multimodality, and the curse of dimensionality. Furthermore, addressing the latter two concurrently presents considerable difficulty. In this study, we introduce a framework aimed at mitigating all the above obstacles simultaneously. The objective is to achieve optimal configurations in a notably reduced timeframe eliminating the need for the initial trial-and-error iterations. The topology optimization approach we propose is implemented via precise structural boundary modeling utilizing a body-fitted mesh generated using a Fourier series expanded level-set method. This methodology expedites the exploration of optimal solutions. We employ the covariance matrix adaptation-evolution strategy to address multimodality, thereby enhancing the optimization process. The implementation of the Fourier-series-expanded level-set method reduces the number of design variables while maintaining accuracy in finite-element analyses by replacing design variables from discretized level-set functions with the coefficients of the Fourier series expansion. To facilitate the exploration of optimal solutions, a method is also introduced for handling box constraints through an adaptive penalty function. To demonstrate the effectiveness of the proposed scheme, we address three distinct problems: mean compliance minimization, heat flux manipulation, and the control of electromagnetic wave scattering. Despite each system being governed by different equations, topology optimization method consistently yields notable acceleration in computational efficiency across all scenarios, and remarkably without requiring initial guesses. [Display omitted] •An acceleration scheme for CMA-ES-based topology optimization is presented.•Without trial-and-error, optimization problems are solved within reasonable times.•Oscillatory boundaries in configurations were suppressed by the perimeter constraint.•Box constraints are presented to utilize in spectral level-set-boundary modeling.
ISSN:0045-7825
DOI:10.1016/j.cma.2024.117331