Origami is a topic of rapidly growing interest in both the scientific and engineering research
communities due to its promising potential in a broad range of applications. Previous …

Origami and kirigami, the ancient techniques for making paper works of art, also provide
inspiration for routes to structural platforms in engineering applications, including foldable …

Self-folding of complex origami-inspired structures from flat states allows for the
incorporation of a multitude of surface-related functionalities into the final 3D device. Several …

Self‐folding is a powerful approach to fabricate materials with complex 3D forms and
advanced properties using planar patterning steps, but suffers from intrinsic limitations in …

Origami engineering principles have recently been applied to a wide range of applications,
including soft robots, stretchable electronics, and mechanical metamaterials. In order to …

Origami robots are created using folding processes, which provide a simple approach to
fabricating a wide range of robot morphologies. Inspired by biological systems, engineers …

Integrating origami principles within traditional microfabrication methods can produce shape
morphing microscale metamaterials and 3D systems with complex geometries and …

DOI: 10.1002/adma. 201403510 systematic principles, for the design of complex and
functional 3D forms. However, while numerous routes have been developed to drive self …

Over the past decade, there has been an obvious expansion in the exploration and
application of mathematical and computational origami.“Ted Talks,” documentaries such as …

Deployability, multifunctionality, and tunability are features that can be explored in the
design space of origami engineering solutions. These features arise from the shape …