Running Gait and Control of Quadruped Robot Based on SLIP Model

He, Xiaolong; Li, Xinjie; Wang, Xiangji; Meng, Fantuo; Guan, Xikang; Jiang, Zhenyu; Yuan, Lipeng; Ba, Kaixian; Ma, Guoliang; Yu, Bin

doi:10.3390/biomimetics9010024

Cited by 1 publication

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References 29 publications

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“…In addition to movement dynamics, researchers have looked at biomechanics and control mechanisms inspired by living organisms. X He et al [14]. investigated the concepts of dynamic walking and running in quadruped robots, taking inspiration from animal locomotion to create efficient and adaptive gait patterns.…”

Section: Related Workmentioning

confidence: 99%

Numerical Simulation of Motion Test of Bionic Amphibious Quadruped Robot

Jie Zhao

2024

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Bionic amphibious quadruped robots are a huge leap in robotics, with the ability to navigate various terrains with agility and efficiency. In this study, the researchers utilized numerical simulations of motion tests to assess the locomotion skills of these extraordinary robotic systems. They learned a lot about their functioning and problems by rigorously analyzing performance parameters across various terrains and conditions, such as terrain adaptability, traversal speed, energy efficiency, stability, and manoeuvrability. The results they obtained highlighted the importance of adaptive control algorithms and mechanical designs in maximizing traversal speed and energy economy, especially while negotiating difficult terrains. In addition, the study demonstrated the interdisciplinary character of research in bionic amphibious quadruped robots, drawing on insights from biomechanics, control theory, robotics, and computational modelling. By combining previous research and utilizing computational simulation approaches, they opened the road for the creation of versatile and durable robotic systems capable of navigating difficult terrains and surroundings with precision and efficiency. Future research efforts could focus on improving design and control, investigating novel propulsion mechanisms, adaptive locomotion tactics, and biomimetic control algorithms to improve performance and adaptability. Addressing the challenges identified in the research and seizing opportunities for innovation will drive the development of robotic systems that push the limits of locomotion capabilities and open up new possibilities for applications in exploration, search and rescue, environmental monitoring, and beyond.

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Section: Related Workmentioning

confidence: 99%

Numerical Simulation of Motion Test of Bionic Amphibious Quadruped Robot

Jie Zhao

2024

jes

View full text Add to dashboard Cite

show abstract

Running Gait and Control of Quadruped Robot Based on SLIP Model

Cited by 1 publication

References 29 publications

Numerical Simulation of Motion Test of Bionic Amphibious Quadruped Robot

Numerical Simulation of Motion Test of Bionic Amphibious Quadruped Robot

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