变形
超材料
DNA折纸
计算机科学
拓扑(电路)
铰链
材料科学
平方(代数)
自由度(物理和化学)
执行机构
纳米技术
机械工程
人工智能
工程类
几何学
物理
电气工程
光电子学
量子力学
数学
纳米结构
作者
Li‐Chen Wang,Wei‐Li Song,Yajing Zhang,Meijun Qu,Zeang Zhao,Mingji Chen,Yazheng Yang,Haosen Chen,Daining Fang
标识
DOI:10.1002/adfm.201909087
摘要
Abstract Origami structures offer valuable applications in many fields, ranging from metamaterials to robotics. The multistable characteristics of origami structures have been pursued for acquiring unique reconfigurable features. For achieving this goal, an unusual polymeric tristable origami structure is demonstrated using a classic square‐twist origami configuration. By manipulating both material properties and geometric parameters of the heteropolymer structures, a design principle for tailoring the multistable configuration in the square‐twist origami is established based on variation of the structural potential energy. Under thermal triggering, the stiffness of the deformable structure is dramatically reduced, which causes an increase in the structural degree of freedom, allowing for self‐deployment via release of the prestored energy in the elastic twisted hinges. Utilizing such unique features and design principles, a prototype of frequency reconfigurable origami antenna of five diverse operating modes and a programmable multiple‐input multiple‐output communication system is subsequently designed and assembled, aiming to substantially promote the channel capacity and communication reliability. The findings and results firmly provide a remarkable design principle and strategy for advancing active origami structures and devices in shape‐morphing systems.
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