Jigsaw puzzle design of pluripotent origami

Origami is rapidly transforming the design of robots 1 , 2 , deployable structures 3 – 6 and metamaterials 7 – 14 . However, as foldability requires a large number of complex compatibility conditions that are difficult to satisfy, the design of crease patterns is limited to heuristics and computer o...

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Bibliographic Details
Published in:Nature physics 2020-01, Vol.16 (1), p.63-68
Main Authors: Dieleman, Peter, Vasmel, Niek, Waitukaitis, Scott, van Hecke, Martin
Format: Article
Language:English
Subjects:
639/766/530/2801
639/766/530/2803
Atomic
Classical and Continuum Physics
Combinatorial analysis
Complex Systems
Condensed Matter Physics
Design
Folding
Jigsaw puzzles
Letter
Mathematical and Computational Physics
Metamaterials
Molecular
Optical and Plasma Physics
Optimization
Origami
Physics
Physics and Astronomy
Shape recognition
Theoretical
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Summary:Origami is rapidly transforming the design of robots 1 , 2 , deployable structures 3 – 6 and metamaterials 7 – 14 . However, as foldability requires a large number of complex compatibility conditions that are difficult to satisfy, the design of crease patterns is limited to heuristics and computer optimization. Here we introduce a systematic strategy that enables intuitive and effective design of complex crease patterns that are guaranteed to fold. First, we exploit symmetries to construct 140 distinct foldable motifs, and represent these as jigsaw puzzle pieces. We then show that when these pieces are fitted together they encode foldable crease patterns. This maps origami design to solving combinatorial problems, which allows us to systematically create, count and classify a vast number of crease patterns. We show that all of these crease patterns are pluripotent—capable of folding into multiple shapes—and solve exactly for the number of possible shapes for each pattern. Finally, we employ our framework to rationally design a crease pattern that folds into two independently defined target shapes, and fabricate such pluripotent origami. Our results provide physicists, mathematicians and engineers with a powerful new design strategy. The crease patterns for origami-based mechanical metamaterials can fold into myriad 3D shapes, but predicting foldability is no simple task. A framework for designing foldable patterns offers a neat alternative to extensive computer optimization.
ISSN:1745-2473
1745-2481
DOI:10.1038/s41567-019-0677-3