Overview

These four volumes of proceedings contain 126 papers contributed to the 8 th International Meeting on Origami Science, Mathematics and Education (8OSME), held on 16–18 July 2024 at Swinburne University of Technology in Melbourne, Australia. The papers represent current work in different disciplines of origami and they are grouped into four subject themes, Volume 1 - Engineering I , Volume 2 - Engineering II, Volume 3 - Mathematics, Computation, History and Mental Health, and Volume 4 - Design and Education.  We witness increasing interests in origami from researchers, practitioners and artists. Of a special note is the rapidly growing research in origami engineering, a distinctive field with fundamental concepts and applications related to space, mechanical, material, medical and structural engineering etc. Participants of 8OSME should find great passion and opportunity of collaborations across disciplines of origami. We hope these four volumes will inspire not just currently active researchers and artists, but also the next generation of origami scientists, mathematicians, engineers, designers, historians, and teachers.  Chapters “Fold Sensing Origami Gestures—A Case Study with Kresling Kinematics” and “Making Origami Digital Musical Instruments” are available open access under a Creative Commons Attribution 4.0 International License via link.springer.com.

Full Product Details

Author:   Guoxing Lu ,  Zhong You ,  Michael Assis
Publisher:   Springer Nature Switzerland AG
Imprint:   Springer Nature Switzerland AG
ISBN:  

9789819686605

ISBN 10:   9819686601
Pages:   480
Publication Date:   15 February 2026
Audience:   Professional and scholarly ,  College/higher education ,  Professional & Vocational ,  Postgraduate, Research & Scholarly
Format:   Paperback
Publisher's Status:   Active
Availability:   Manufactured on demand  
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Table of Contents

Chapter 1.Fold Sensing origami gestures - a case study with Kresling kinematics-Chapter 2:Design and development of a foldable and transformable hemispherical enclosure for robotic manufacturing.-Chapter 3:Chiral origami robot with wheeled and quadcopter modes.-Chapter4:A robotic origami folder for paper cranes.-Chapter 5:Miura-Bot: Modular Origami Robots for Self-Folding Miura-Ori Tessellations.- Chapter 6: Adaptive Stiffness and Shape Control of a Modular Origami-Inspired Robot.-Chapter 7:Re-programmable Matter by Folding: Magnetically-Controlled Origami that Self-Folds, Self-Unfolds, and Self-Reconfigures On-Demand.-Chapter 8:Origami Cellular Material Switching Between Single and Multiple DOF Modes.Chapter 9:A flat-foldable, transformable metamaterial from octahedral origami unit cells.-Chapter 10:Kresling-Inspired Constant Size Magnetically-Reconfigurable Metamaterials.-Chapter 11:Reconfigurable Mechanical Logic Module.-Chapter 12:A Flat Foldable Solid Consisting of Rhombitruncated Cuboctahedra and Regular Octagonal Prisms.-Chapter 13:Making origami musical instruments.- Chapter 14:Fahrenheit 1832: Folding for Fire Protection.-Chapter 15:Topological manifold based parametric design of chiral origami mechanisms.-Chapter 16:Symmetric self-folding of N-gon hypar origami.-Chapter 17:Theoretical Analysis on the Deformation of the Miura-Ori Patterned Sheet.-Chapter 18:Parametric Study of the Porous Origami-based Mechanical Metamaterials with Curvatures.-Chapter 19:Deformable Origami Structure Design Based on Two-Dimensional Geometric Face Shape Collocation.-Chapter 20:Earwig Fan Inspired Deployable Structures.-Chapter 21:Out-of-plane impact and energy absorption of origami honeycombs in Truck Mounted Attenuator.-Chapter 22:Research on construction of double cubic core and its application.-Chapter 23:Tessellation Manufacture by Sequential Quasi-Isometric Gradual Folding.-Chapter 24:New Kresling Origami Geometry: The Offset Cell.-Chapter 25:Kinematic Modeling of Cylindrical Origami Tessellations for Programmable Local Motion Control.-Chapter 26:Geometric Constructions of Bifoldable Polyhedral Complexes.-Chapter 27:From Flexagon to Flexahedron – Infinitely Turning Objects.-Chapter 28:Kinematics analysis of Rubik’s Magic puzzle and beyond.-Chapter 29:Motion analysis of Flexible Modular Origami: A Finite Particle Method Investigation.-Chapter 30:Cut design of pop-up origami with fixed planar substrate.-Chapter 31:Programming Origami Instabilities via Topology Optimization.

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Author Information

Michael Assis is a mathematical physicist and origami artist. He received his PhD from Stony Brook University in the area of statistical mechanics, with applications in combinatorics and computational mathematics. He has exhibited his original origami models in conferences in several countries, and actively contributes to research in origami mathematics. He is currently based at the University of Melbourne, working in medical research in the area of paediatric oncofertility. Guoxing Lu is a Qiushi Chair Professor in the Department of Engineering Mechanics, Zhejiang University, China. Prior to that, he was a University Distinguished Professor and Founding Director of the Impact Engineering Laboratory, Swinburne University of Technology, Australia. He held academic positions at Nanyang Technological University, Singapore. In 1989, he obtained his PhD in Structural Mechanics from the University of Cambridge.  Zhong You is a professor of Engineering Science at the University of Oxford. His research encompasses the fields of folding and origami structures, with a particular focus on the development of a systematic approach to the creation of large deployable assemblies. He served as the chairperson for 7OSME, which was held in Oxford in 2018. He obtained his PhD in structural engineering from the University of Cambridge.

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