Pragmatic generative optimization of novel structural lattice metamaterials with machine learning
Metamaterials, otherwise known as architected or programmable materials, enable designers to tailor mesoscale topology and shape to achieve unique material properties that are not present in nature. Additionally, with the recent proliferation of additive manufacturing tools across industrial sectors...
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Elsevier
2021-05-01
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| Series: | Materials & Design |
| Online Access: | http://www.sciencedirect.com/science/article/pii/S0264127521001854 |
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doaj-894b1237550c4c7eaa5cef47d9e45f702021-04-12T04:20:31ZengElsevierMaterials & Design0264-12752021-05-01203109632Pragmatic generative optimization of novel structural lattice metamaterials with machine learningAnthony P. Garland0Benjamin C. White1Scott C. Jensen2Brad L. Boyce3Sandia National Laboratories, Albuquerque, NM 87185, United States of AmericaSandia National Laboratories, Albuquerque, NM 87185, United States of AmericaSandia National Laboratories, Albuquerque, NM 87185, United States of AmericaCorresponding author.; Sandia National Laboratories, Albuquerque, NM 87185, United States of AmericaMetamaterials, otherwise known as architected or programmable materials, enable designers to tailor mesoscale topology and shape to achieve unique material properties that are not present in nature. Additionally, with the recent proliferation of additive manufacturing tools across industrial sectors, the ability to readily fabricate geometrically complex metamaterials is now possible. However, in many high-performance applications involving complex multi-physics interactions, design of novel lattice metamaterials is still difficult. Design is primarily guided by human intuition or gradient optimization for simple problems. In this work, we show how machine learning guides discovery of new unit cells that are Pareto optimal for multiple competing objectives; specifically, maximizing elastic stiffness during static loading and minimizing wave speed through the metamaterial during an impact event. Additionally, we show that our artificial intelligence approach works with relatively few (3500) simulation calls.http://www.sciencedirect.com/science/article/pii/S0264127521001854 |
| collection |
DOAJ |
| language |
English |
| format |
Article |
| sources |
DOAJ |
| author |
Anthony P. Garland Benjamin C. White Scott C. Jensen Brad L. Boyce |
| spellingShingle |
Anthony P. Garland Benjamin C. White Scott C. Jensen Brad L. Boyce Pragmatic generative optimization of novel structural lattice metamaterials with machine learning Materials & Design |
| author_facet |
Anthony P. Garland Benjamin C. White Scott C. Jensen Brad L. Boyce |
| author_sort |
Anthony P. Garland |
| title |
Pragmatic generative optimization of novel structural lattice metamaterials with machine learning |
| title_short |
Pragmatic generative optimization of novel structural lattice metamaterials with machine learning |
| title_full |
Pragmatic generative optimization of novel structural lattice metamaterials with machine learning |
| title_fullStr |
Pragmatic generative optimization of novel structural lattice metamaterials with machine learning |
| title_full_unstemmed |
Pragmatic generative optimization of novel structural lattice metamaterials with machine learning |
| title_sort |
pragmatic generative optimization of novel structural lattice metamaterials with machine learning |
| publisher |
Elsevier |
| series |
Materials & Design |
| issn |
0264-1275 |
| publishDate |
2021-05-01 |
| description |
Metamaterials, otherwise known as architected or programmable materials, enable designers to tailor mesoscale topology and shape to achieve unique material properties that are not present in nature. Additionally, with the recent proliferation of additive manufacturing tools across industrial sectors, the ability to readily fabricate geometrically complex metamaterials is now possible. However, in many high-performance applications involving complex multi-physics interactions, design of novel lattice metamaterials is still difficult. Design is primarily guided by human intuition or gradient optimization for simple problems. In this work, we show how machine learning guides discovery of new unit cells that are Pareto optimal for multiple competing objectives; specifically, maximizing elastic stiffness during static loading and minimizing wave speed through the metamaterial during an impact event. Additionally, we show that our artificial intelligence approach works with relatively few (3500) simulation calls. |
| url |
http://www.sciencedirect.com/science/article/pii/S0264127521001854 |
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