Data-driven design of topologically optimized auxetic metamaterials for tailored stress–strain and Poisson’s ratio-strain behaviors

Data-driven design of topologically optimized auxetic metamaterials for tailored stress–strain and Poisson’s ratio-strain behaviors

Conventional topology optimization methods often struggle to achieve simultaneous customization of stress–strain and Poisson’s ratio–strain curves in auxetic metamaterials, due to the complexity of nonlinear analysis, multi-objective coupling, and high computational costs. To overcome these limitati...

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Bibliographic Details
Main Authors: Yueyou Tang, Anfu Zhang, Qi Zhou, Mu He, Liang Xia
Format: Article
Language:English
Published: Elsevier 2025-08-01
Series:Materials & Design
Subjects:
Auxetic metamaterials
Customization
Stress–strain curves
Poisson’s ratio–strain curves
Neural networks
Topology optimization
Online Access:http://www.sciencedirect.com/science/article/pii/S0264127525007105
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Summary:Conventional topology optimization methods often struggle to achieve simultaneous customization of stress–strain and Poisson’s ratio–strain curves in auxetic metamaterials, due to the complexity of nonlinear analysis, multi-objective coupling, and high computational costs. To overcome these limitations, present work proposes a physics–data collaborative design framework that integrates nonlinear topology optimization with neural networks. This framework first generates baseline configuration approximating the target mechanical behavior via nonlinear topology optimization, thereby establishing a physically reliable initial design space. High-precision neural networks are then trained using geometric features extracted through PCA (principal component analysis), enabling real-time, simultaneous prediction of stress–strain and Poisson’s ratio–strain responses. By combining evolutionary strategies with an adaptive learning factor, we construct an efficient global optimization model that enables high-accuracy coupled customization of both curves under finite deformation. Compression experiments on polyurethane specimens fabricated via precision milling validate the feasibility of the proposed method, showing an average curve-matching accuracy of 98.2% between the experimental and target curves. Compared to traditional topology optimization, our approach improves customization accuracy by 71.51% to 93.24%, achieves simultaneous coupling of both mechanical responses, and delivers an overall design accuracy exceeding 99%.
ISSN:0264-1275

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