基于深度学习的晶格超材料反向设计用于调整带隙

IF 4.3 3区 工程技术 Q2 MATERIALS SCIENCE, MULTIDISCIPLINARY Extreme Mechanics Letters Pub Date : 2024-05-07 DOI:10.1016/j.eml.2024.102165
Kai Zhang , Yaoyao Guo , Xiangbing Liu , Fang Hong , Xiuhui Hou , Zichen Deng
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引用次数: 0

摘要

本文利用深度学习神经网络预测超材料晶格的带状结构,并在带隙调制中采用主动反向设计。本文提出了超材料晶格的参数化设计方法,以获得丰富的设计空间。通过有限元法(FEM)计算相应的带结构数据,构建数据集。通过构建和训练全连接神经网络和卷积神经网络(CNN),我们成功地绕过了复杂的理论或数值方法,建立了超材料晶格几何参数与带状结构数据之间的映射关系。通过将训练好的神经网络模型与带隙调整的逆向设计方法相结合,输入目标带结构即可直接获得超材料晶格的几何参数。最后,设计了三个目标带结构,并通过有限元仿真和实验进行了验证,从而验证了反向设计方法的有效性。这种设计方法可以扩展到其他超材料特性的设计。
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Deep learning-based inverse design of lattice metamaterials for tuning bandgap

In this paper, deep learning neural networks is used to predict the band structure of metamaterial lattices, and proactive inverse design is employed in bandgap modulation. A parametric design of the metamaterial lattice is proposed to achieve a rich design space. The corresponding band structure data is calculated by finite element method (FEM) to construct the data set. We successfully bypass complex theoretical or numerical methods to establish the mapping relationship between the lattice geometry parameters of metamaterials and the band structure data by constructing and training fully connected neural networks and convolutional neural networks (CNN). By combining the trained neural network model into an inverse design method of bandgap tuning, the geometric parameters of the metamaterial lattice can be obtained directly by inputting the target band structure. Finally, three object band structures are designed and verified by finite element simulation and experiment, which verifies the effectiveness of the inverse design method. This design approach can be extended to design other metamaterial properties.

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来源期刊
Extreme Mechanics Letters
Extreme Mechanics Letters Engineering-Mechanics of Materials
CiteScore
9.20
自引率
4.30%
发文量
179
审稿时长
45 days
期刊介绍: Extreme Mechanics Letters (EML) enables rapid communication of research that highlights the role of mechanics in multi-disciplinary areas across materials science, physics, chemistry, biology, medicine and engineering. Emphasis is on the impact, depth and originality of new concepts, methods and observations at the forefront of applied sciences.
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