计算机科学
反向
实现(概率)
过程(计算)
超材料
设计过程
工程设计过程
生成模型
非线性系统
3D打印
忠诚
生成语法
机械工程
材料科学
人工智能
在制品
数学
工程类
物理
几何学
操作系统
统计
电信
量子力学
光电子学
运营管理
作者
Chan Soo Ha,Desheng Yao,Zhenpeng Xu,Chenang Liu,Han Liu,Daniel Elkins,Matthew Kile,V.S. Deshpande,Zhenyu Kong,Mathieu Bauchy,Xiaoyu Zheng
标识
DOI:10.1038/s41467-023-40854-1
摘要
Designing and printing metamaterials with customizable architectures enables the realization of unprecedented mechanical behaviors that transcend those of their constituent materials. These behaviors are recorded in the form of response curves, with stress-strain curves describing their quasi-static footprint. However, existing inverse design approaches are yet matured to capture the full desired behaviors due to challenges stemmed from multiple design objectives, nonlinear behavior, and process-dependent manufacturing errors. Here, we report a rapid inverse design methodology, leveraging generative machine learning and desktop additive manufacturing, which enables the creation of nearly all possible uniaxial compressive stress‒strain curve cases while accounting for process-dependent errors from printing. Results show that mechanical behavior with full tailorability can be achieved with nearly 90% fidelity between target and experimentally measured results. Our approach represents a starting point to inverse design materials that meet prescribed yet complex behaviors and potentially bypasses iterative design-manufacturing cycles.
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