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Machine learning-enabled forward prediction and inverse design of 4D-printed active plates

Author

Listed:
  • Xiaohao Sun

    (Georgia Institute of Technology)

  • Liang Yue

    (Georgia Institute of Technology)

  • Luxia Yu

    (Georgia Institute of Technology)

  • Connor T. Forte

    (Georgia Institute of Technology)

  • Connor D. Armstrong

    (Georgia Institute of Technology)

  • Kun Zhou

    (Nanyang Technological University)

  • Frédéric Demoly

    (UTBM
    Institut universitaire de France (IUF))

  • Ruike Renee Zhao

    (Stanford University)

  • H. Jerry Qi

    (Georgia Institute of Technology)

Abstract

Shape transformations of active composites (ACs) depend on the spatial distribution of constituent materials. Voxel-level complex material distributions can be encoded by 3D printing, offering enormous freedom for possible shape-change 4D-printed ACs. However, efficiently designing the material distribution to achieve desired 3D shape changes is significantly challenging yet greatly needed. Here, we present an approach that combines machine learning (ML) with both gradient-descent (GD) and evolutionary algorithm (EA) to design AC plates with 3D shape changes. A residual network ML model is developed for the forward shape prediction. A global-subdomain design strategy with ML-GD and ML-EA is then used for the inverse material-distribution design. For a variety of numerically generated target shapes, both ML-GD and ML-EA demonstrate high efficiency. By further combining ML-EA with a normal distance-based loss function, optimized designs are achieved for multiple irregular target shapes. Our approach thus provides a highly efficient tool for the design of 4D-printed active composites.

Suggested Citation

  • Xiaohao Sun & Liang Yue & Luxia Yu & Connor T. Forte & Connor D. Armstrong & Kun Zhou & Frédéric Demoly & Ruike Renee Zhao & H. Jerry Qi, 2024. "Machine learning-enabled forward prediction and inverse design of 4D-printed active plates," Nature Communications, Nature, vol. 15(1), pages 1-15, December.
    • Handle: RePEc:nat:natcom:v:15:y:2024:i:1:d:10.1038_s41467-024-49775-z
    DOI: 10.1038/s41467-024-49775-z
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    References listed on IDEAS

    as
    1. Andreas Lendlein & Hongyan Jiang & Oliver Jünger & Robert Langer, 2005. "Light-induced shape-memory polymers," Nature, Nature, vol. 434(7035), pages 879-882, April.
    2. Qiji Ze & Shuai Wu & Jize Dai & Sophie Leanza & Gentaro Ikeda & Phillip C. Yang & Gianluca Iaccarino & Ruike Renee Zhao, 2022. "Spinning-enabled wireless amphibious origami millirobot," Nature Communications, Nature, vol. 13(1), pages 1-9, December.
    3. Yun Bai & Heling Wang & Yeguang Xue & Yuxin Pan & Jin-Tae Kim & Xinchen Ni & Tzu-Li Liu & Yiyuan Yang & Mengdi Han & Yonggang Huang & John A. Rogers & Xiaoyue Ni, 2022. "A dynamically reprogrammable surface with self-evolving shape morphing," Nature, Nature, vol. 609(7928), pages 701-708, September.
    4. Liang Yue & S. Macrae Montgomery & Xiaohao Sun & Luxia Yu & Yuyang Song & Tsuyoshi Nomura & Masato Tanaka & H. Jerry Qi, 2023. "Single-vat single-cure grayscale digital light processing 3D printing of materials with large property difference and high stretchability," Nature Communications, Nature, vol. 14(1), pages 1-12, December.
    5. Amirali Nojoomi & Junha Jeon & Kyungsuk Yum, 2021. "2D material programming for 3D shaping," Nature Communications, Nature, vol. 12(1), pages 1-8, December.
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