Versatile Motion Generation of Magnetic Origami Spring Robots in the Uniform Magnetic Field

Sishen Yuan; Sifan Cao; Junnan Xue; Shijian Su; Junyan Yan; Min Wang; Wenchao Yue; Shing Shin Cheng; Jun Liu; Jiaole Wang; Shuang Song; Max Q.H. Meng; Hongliang Ren

doi:10.1109/LRA.2022.3194318

Versatile Motion Generation of Magnetic Origami Spring Robots in the Uniform Magnetic Field

Sishen Yuan
, Sifan Cao
, Junnan Xue
, Shijian Su
, Junyan Yan
, Min Wang
, Wenchao Yue
, Shing Shin Cheng
, Jun Liu
, Jiaole Wang
, Shuang Song
, Max Q.H. Meng^*
, Hongliang Ren^*

^*Corresponding author for this work

Chinese University of Hong Kong
Harbin Institute of Technology Shenzhen
City University of Hong Kong
Southern University of Science and Technology

Research output: Contribution to journal › Article › peer-review

30 Scopus citations

Abstract

Magnetic soft robots have attracted widespread attention for their untethered, remotely operated, and compliant deformation characteristics. Earlier work has demonstrated magnetic origami robots' diverse locomotion capabilities. This letter will focus on the motion generation and open-loop control of an untethered magnetic flexible robot with a stretch-twist coupling origami spring (OS) skeleton only using uniform magnetic field control. We investigate the associated motion generation mechanism and the corresponding control signals for the magnetic spring robot (MSR). The MSR can perform in-plane crawling (Worm Crawling) and perpendicular in-plane crawling (Crab Crawling) under two-dimensional magnetic signal inputs. Moreover, the OS's stretch-twist coupling characteristic is utilized to achieve axial Rolling Motion with axial magnetization configuration. We further experimentally tested the performance of three motions with average normalized velocities of 0.34±0.039(body length/s), 0.054±0.0066(body length/s), and 1.46±0.069(body length/s), respectively.

Original language	English
Pages (from-to)	10486-10493
Number of pages	8
Journal	IEEE Robotics and Automation Letters
Volume	7
Issue number	4
DOIs	https://doi.org/10.1109/LRA.2022.3194318
State	Published - 1 Oct 2022
Externally published	Yes

Keywords

Magnetic spring robot (MSR)
crab crawling
motion generation
rolling motion
worm crawling

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10.1109/LRA.2022.3194318

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title = "Versatile Motion Generation of Magnetic Origami Spring Robots in the Uniform Magnetic Field",

abstract = "Magnetic soft robots have attracted widespread attention for their untethered, remotely operated, and compliant deformation characteristics. Earlier work has demonstrated magnetic origami robots' diverse locomotion capabilities. This letter will focus on the motion generation and open-loop control of an untethered magnetic flexible robot with a stretch-twist coupling origami spring (OS) skeleton only using uniform magnetic field control. We investigate the associated motion generation mechanism and the corresponding control signals for the magnetic spring robot (MSR). The MSR can perform in-plane crawling (Worm Crawling) and perpendicular in-plane crawling (Crab Crawling) under two-dimensional magnetic signal inputs. Moreover, the OS's stretch-twist coupling characteristic is utilized to achieve axial Rolling Motion with axial magnetization configuration. We further experimentally tested the performance of three motions with average normalized velocities of 0.34±0.039(body length/s), 0.054±0.0066(body length/s), and 1.46±0.069(body length/s), respectively.",

keywords = "Magnetic spring robot (MSR), crab crawling, motion generation, rolling motion, worm crawling",

author = "Sishen Yuan and Sifan Cao and Junnan Xue and Shijian Su and Junyan Yan and Min Wang and Wenchao Yue and Cheng, \{Shing Shin\} and Jun Liu and Jiaole Wang and Shuang Song and Meng, \{Max Q.H.\} and Hongliang Ren",

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doi = "10.1109/LRA.2022.3194318",

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T1 - Versatile Motion Generation of Magnetic Origami Spring Robots in the Uniform Magnetic Field

AU - Yuan, Sishen

AU - Cao, Sifan

AU - Xue, Junnan

AU - Su, Shijian

AU - Yan, Junyan

AU - Wang, Min

AU - Yue, Wenchao

AU - Cheng, Shing Shin

AU - Liu, Jun

AU - Wang, Jiaole

AU - Song, Shuang

AU - Meng, Max Q.H.

AU - Ren, Hongliang

PY - 2022/10/1

Y1 - 2022/10/1

N2 - Magnetic soft robots have attracted widespread attention for their untethered, remotely operated, and compliant deformation characteristics. Earlier work has demonstrated magnetic origami robots' diverse locomotion capabilities. This letter will focus on the motion generation and open-loop control of an untethered magnetic flexible robot with a stretch-twist coupling origami spring (OS) skeleton only using uniform magnetic field control. We investigate the associated motion generation mechanism and the corresponding control signals for the magnetic spring robot (MSR). The MSR can perform in-plane crawling (Worm Crawling) and perpendicular in-plane crawling (Crab Crawling) under two-dimensional magnetic signal inputs. Moreover, the OS's stretch-twist coupling characteristic is utilized to achieve axial Rolling Motion with axial magnetization configuration. We further experimentally tested the performance of three motions with average normalized velocities of 0.34±0.039(body length/s), 0.054±0.0066(body length/s), and 1.46±0.069(body length/s), respectively.

AB - Magnetic soft robots have attracted widespread attention for their untethered, remotely operated, and compliant deformation characteristics. Earlier work has demonstrated magnetic origami robots' diverse locomotion capabilities. This letter will focus on the motion generation and open-loop control of an untethered magnetic flexible robot with a stretch-twist coupling origami spring (OS) skeleton only using uniform magnetic field control. We investigate the associated motion generation mechanism and the corresponding control signals for the magnetic spring robot (MSR). The MSR can perform in-plane crawling (Worm Crawling) and perpendicular in-plane crawling (Crab Crawling) under two-dimensional magnetic signal inputs. Moreover, the OS's stretch-twist coupling characteristic is utilized to achieve axial Rolling Motion with axial magnetization configuration. We further experimentally tested the performance of three motions with average normalized velocities of 0.34±0.039(body length/s), 0.054±0.0066(body length/s), and 1.46±0.069(body length/s), respectively.

KW - Magnetic spring robot (MSR)

KW - crab crawling

KW - motion generation

KW - rolling motion

KW - worm crawling

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DO - 10.1109/LRA.2022.3194318

M3 - 文章

AN - SCOPUS:85135747417

SN - 2377-3766

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SP - 10486

EP - 10493

JO - IEEE Robotics and Automation Letters

JF - IEEE Robotics and Automation Letters

IS - 4

ER -

Versatile Motion Generation of Magnetic Origami Spring Robots in the Uniform Magnetic Field

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