Design and implementation of symmetric legged robot for highly dynamic jumping and impact mitigation

Lei Wang; Fei Meng; Ru Kang; Ryuki Sato; Xuechao Chen; Zhangguo Yu; Aiguo Ming; Qiang Huang

doi:10.3390/s21206885

Design and implementation of symmetric legged robot for highly dynamic jumping and impact mitigation

Lei Wang
, Fei Meng^*
, Ru Kang
, Ryuki Sato
, Xuechao Chen
, Zhangguo Yu
, Aiguo Ming
, Qiang Huang

^*Corresponding author for this work

School of Mechatronical Engineering

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

8 Citations (Scopus)

Abstract

Aiming at highly dynamic locomotion and impact mitigation, this paper proposes the design and implementation of a symmetric legged robot. Based on the analysis of the three-leg topology in terms of force sensitivity, force production, and impact mitigation, the symmetric leg was designed and equipped with a high torque density actuator, which was assembled by a custom motor and two-stage planetary. Under the kinematic and dynamic constraints of the robot system, a nonlinear optimization for high jumping and impact mitigation is proposed with consideration of the peak impact force at landing. Finally, experiments revealed that the robot achieved a jump height of 1.8 m with a robust landing, and the height was equal to approximately three times the leg length.

Original language	English
Article number	6885
Journal	Sensors
Volume	21
Issue number	20
DOIs	https://doi.org/10.3390/s21206885
Publication status	Published - 1 Oct 2021

Keywords

Highly dynamic jumping
Impact mitigation
Leg topology
Legged robot
Nonlinear optimization

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10.3390/s21206885

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abstract = "Aiming at highly dynamic locomotion and impact mitigation, this paper proposes the design and implementation of a symmetric legged robot. Based on the analysis of the three-leg topology in terms of force sensitivity, force production, and impact mitigation, the symmetric leg was designed and equipped with a high torque density actuator, which was assembled by a custom motor and two-stage planetary. Under the kinematic and dynamic constraints of the robot system, a nonlinear optimization for high jumping and impact mitigation is proposed with consideration of the peak impact force at landing. Finally, experiments revealed that the robot achieved a jump height of 1.8 m with a robust landing, and the height was equal to approximately three times the leg length.",

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author = "Lei Wang and Fei Meng and Ru Kang and Ryuki Sato and Xuechao Chen and Zhangguo Yu and Aiguo Ming and Qiang Huang",

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AU - Wang, Lei

AU - Meng, Fei

AU - Kang, Ru

AU - Sato, Ryuki

AU - Chen, Xuechao

AU - Yu, Zhangguo

AU - Ming, Aiguo

AU - Huang, Qiang

PY - 2021/10/1

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N2 - Aiming at highly dynamic locomotion and impact mitigation, this paper proposes the design and implementation of a symmetric legged robot. Based on the analysis of the three-leg topology in terms of force sensitivity, force production, and impact mitigation, the symmetric leg was designed and equipped with a high torque density actuator, which was assembled by a custom motor and two-stage planetary. Under the kinematic and dynamic constraints of the robot system, a nonlinear optimization for high jumping and impact mitigation is proposed with consideration of the peak impact force at landing. Finally, experiments revealed that the robot achieved a jump height of 1.8 m with a robust landing, and the height was equal to approximately three times the leg length.

AB - Aiming at highly dynamic locomotion and impact mitigation, this paper proposes the design and implementation of a symmetric legged robot. Based on the analysis of the three-leg topology in terms of force sensitivity, force production, and impact mitigation, the symmetric leg was designed and equipped with a high torque density actuator, which was assembled by a custom motor and two-stage planetary. Under the kinematic and dynamic constraints of the robot system, a nonlinear optimization for high jumping and impact mitigation is proposed with consideration of the peak impact force at landing. Finally, experiments revealed that the robot achieved a jump height of 1.8 m with a robust landing, and the height was equal to approximately three times the leg length.

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KW - Impact mitigation

KW - Leg topology

KW - Legged robot

KW - Nonlinear optimization

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Design and implementation of symmetric legged robot for highly dynamic jumping and impact mitigation

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Keywords

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