DL-MSTO+: A deep learning-based multi-scale topology optimization framework via positive definiteness ensured material representation network
- Authors
- Seo, Minsik; Min, Seungjae
- Issue Date
- Oct-2023
- Publisher
- Elsevier B.V.
- Keywords
- Deep learning; Homogenization; Multi-scale; Neural networks; Topology optimization
- Citation
- Computer Methods in Applied Mechanics and Engineering, v.415, pp.1 - 39
- Indexed
- SCIE
SCOPUS
- Journal Title
- Computer Methods in Applied Mechanics and Engineering
- Volume
- 415
- Start Page
- 1
- End Page
- 39
- URI
- https://scholarworks.bwise.kr/hanyang/handle/2021.sw.hanyang/192981
- DOI
- 10.1016/j.cma.2023.116276
- ISSN
- 0045-7825
- Abstract
- A multi-scale approach to topology optimization has recently emerged due to its lightweight, robust, and multi-functional characteristics. Considering material diversity, an increasing number of materials leads to a computational burden due to numerous design variables and homogenization equations. This study proposes DL-MSTO+, a deep learning-based multi-scale topology optimization framework. The framework consists of two distinct deep neural networks for multi-scale topology optimization problems to reduce the dimensionality of design variables and predict homogenized material properties. First, a generator network learns the low-dimensional representation of a material microstructure in an unsupervised manner. Thus, the trained generator produces a micro-structural image from a low-dimensional vector. Second, a predictor network is trained in a supervised manner to predict the homogenized elasticity matrix for a given micro-structural image. Additionally, the predictor is specifically designed to ensure the positive definiteness of the predicted elasticity matrix. Lastly, the networks are integrated into the algorithm to improve the efficiency of multi-scale topology optimization. The numerical experiments demonstrate higher efficiency for the proposed algorithm than the conventional multi-scale approach. Moreover, the proposed method provides connectable multi-scale designs, and the low-dimensional latent representation enables semantic interpolation between solutions.
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