Kinematics and the implementation of a modular caterpillar robot in trapezoidal wave locomotion

Hongxing Wei; Yuanyang Cui; Haiyuan Li; Jindong Tan; Yong Guan; Yong Dong Li

doi:10.5772/56727

Kinematics and the implementation of a modular caterpillar robot in trapezoidal wave locomotion

Hongxing Wei^*
, Yuanyang Cui
, Haiyuan Li
, Jindong Tan
, Yong Guan
, Yong Dong Li

^*Corresponding author for this work

School of Mechanical Engineering and Automation

Beihang University
University of Tennessee
Capital Normal University
Academy of Armored Force Engineering China

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

9 Scopus citations

Abstract

With the development of bionic engineering, research into bionic robots has become a popular topic. In this field, the design of robotic mechanisms to realize the locomotion of insects forms a significant research branch. The current paper presents a caterpillar robotic mechanism that is composed of our newly-developed self-assembly modular robots (Sambot). A trapezoidal wave locomotion gait is planned for the caterpillar mechanism and the kinematics equations are established and solved analytically for such locomotion. The variations of the kinematics quantities are illustrated and discussed. The variation of the jump of the angular acceleration indicates that it is better to apply the trapezoidal wave gait to low velocity situations. Finally, the obtained data of the kinematics quantities is used to perform the gait control locomotion experiment and the errors of the experimental data are analysed in depth.

Original language	English
Article number	A304
Journal	International Journal of Advanced Robotic Systems
Volume	10
DOIs	https://doi.org/10.5772/56727
State	Published - 1 Aug 2013

Keywords

Bionic Robots
Caterpillar Mechanism
Kinematics
Modular Self-Reconfigurable Robots

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Cite this

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title = "Kinematics and the implementation of a modular caterpillar robot in trapezoidal wave locomotion",

abstract = "With the development of bionic engineering, research into bionic robots has become a popular topic. In this field, the design of robotic mechanisms to realize the locomotion of insects forms a significant research branch. The current paper presents a caterpillar robotic mechanism that is composed of our newly-developed self-assembly modular robots (Sambot). A trapezoidal wave locomotion gait is planned for the caterpillar mechanism and the kinematics equations are established and solved analytically for such locomotion. The variations of the kinematics quantities are illustrated and discussed. The variation of the jump of the angular acceleration indicates that it is better to apply the trapezoidal wave gait to low velocity situations. Finally, the obtained data of the kinematics quantities is used to perform the gait control locomotion experiment and the errors of the experimental data are analysed in depth.",

keywords = "Bionic Robots, Caterpillar Mechanism, Kinematics, Modular Self-Reconfigurable Robots",

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AU - Wei, Hongxing

AU - Cui, Yuanyang

AU - Li, Haiyuan

AU - Tan, Jindong

AU - Guan, Yong

AU - Li, Yong Dong

PY - 2013/8/1

Y1 - 2013/8/1

N2 - With the development of bionic engineering, research into bionic robots has become a popular topic. In this field, the design of robotic mechanisms to realize the locomotion of insects forms a significant research branch. The current paper presents a caterpillar robotic mechanism that is composed of our newly-developed self-assembly modular robots (Sambot). A trapezoidal wave locomotion gait is planned for the caterpillar mechanism and the kinematics equations are established and solved analytically for such locomotion. The variations of the kinematics quantities are illustrated and discussed. The variation of the jump of the angular acceleration indicates that it is better to apply the trapezoidal wave gait to low velocity situations. Finally, the obtained data of the kinematics quantities is used to perform the gait control locomotion experiment and the errors of the experimental data are analysed in depth.

AB - With the development of bionic engineering, research into bionic robots has become a popular topic. In this field, the design of robotic mechanisms to realize the locomotion of insects forms a significant research branch. The current paper presents a caterpillar robotic mechanism that is composed of our newly-developed self-assembly modular robots (Sambot). A trapezoidal wave locomotion gait is planned for the caterpillar mechanism and the kinematics equations are established and solved analytically for such locomotion. The variations of the kinematics quantities are illustrated and discussed. The variation of the jump of the angular acceleration indicates that it is better to apply the trapezoidal wave gait to low velocity situations. Finally, the obtained data of the kinematics quantities is used to perform the gait control locomotion experiment and the errors of the experimental data are analysed in depth.

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KW - Caterpillar Mechanism

KW - Kinematics

KW - Modular Self-Reconfigurable Robots

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DO - 10.5772/56727

M3 - 文章

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VL - 10

JO - International Journal of Advanced Robotic Systems

JF - International Journal of Advanced Robotic Systems

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ER -

Kinematics and the implementation of a modular caterpillar robot in trapezoidal wave locomotion

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Keywords

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