AQuRo: A Cat-like Adaptive Quadruped Robot With Novel Bio-Inspired Capabilities

Saputra, Azhar Aulia; Takesue, Naoyuki; Wada, Kazuyoshi; Ijspeert, Auke Jan; Kubota, Naoyuki

doi:10.3389/frobt.2021.562524

Cited by 16 publications

(4 citation statements)

References 51 publications

(68 reference statements)

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“…This leads to stable quadrupedal split-belt treadmill walking. Saputra et al (2021) present central CPG-based control with multiple sensory feedback provided by exteroceptors (i.e., quad-composite time-of-flight and dual-laser range finder sensors), for detecting the surroundings and interoceptors (i.e., force and touch sensors and an inertial measurement unit (IMU)). Using this control approach, they are able to generate versatile locomotion and short-term adaptation for a cat-like quadruped robot.…”

Section: Robotic Inter-limb Cooridinationmentioning

confidence: 99%

Editorial: Biological and Robotic Inter-Limb Coordination

2022

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Section: Robotic Inter-limb Cooridinationmentioning

confidence: 99%

Editorial: Biological and Robotic Inter-Limb Coordination

2022

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“…However, the current common biological reflex process is fixed, and it is difficult for robots to adapt to complex and changeable environments. This paper focuses on the research of flexor reflex, and integrates the sensor information into the bio-reflection algorithm [12][13][14] so that the robot can flexibly change the reflection process according to the sensor information during the reflection process, so that it can obtain better stability.…”

Section: Introductionmentioning

confidence: 99%

Research on fusion control of sensor information and biological reflection based on CPG

Chen

Zhang

et al. 2023

Advances in Mechanical Engineering

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To enhance the environmental adaptability of the quadruped robot and realize its stability in terrain with obstacles, this paper studies the fusion of sensor information feedback and bio-reflection control algorithm. First, a central pattern generator (CPG) that generates basal rhythmic movements is constructed. Secondly, a simplified foot end that can be used to identify the touchdown and obstacle information is designed. To enhance the stability of the quadruped robot during the flexor reflex process and avoid the problem of solidification in the reflex process, the foot touch signal was introduced into the flexor reflex algorithm, which enhanced the flexibility of the reflex process. To avoid secondary collisions with obstacles, the postswing reflection process is optimized, and active obstacle avoidance is realized after the obstacle is touched. Finally, the organic fusion of sensor information feedback, CPG control network, and bio-reflection control algorithm is realized. The simulation results show that the robot’s ability to overcome obstacles is improved, the number of reflections is less, and the reflection process is more stable.

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“…Others spiral around it with a snake-like morphology [3], while some use wheels [4]. Quadruped robots often have wheel-leg structures [5] [6], which are very suitable for moving on land, but not effective for climbing.…”

Section: Introductionmentioning

confidence: 99%

Cat-paw-inspired Tree Climbing Robot Gripper

Wang

Cheng

2023

Preprint

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In this paper, we present a bioinspired design for a cat-paw-inspired tree-climbing robot gripper using a combination of soft and hard design. We draw lessons from the cat's tree-climbing action and the structural function of the cat's paw and extract and focus on the key features: the structure of the paw's skeleton, the unique structure of the end claw provides the grip ability, and the stability and friction provided by the soft tissues of the meat pad. In view of the excellent tree-climbing ability of cats, the cat-paw robot gripper in this paper is different from the traditional tree-climbing robot, which is suitable for the complex tree environment. This is also an inspiration for the paw design of the quadruped robot to complete the climbing action. In this paper, the design mainly focuses on the analysis of principle, mechanical structural design, simple motion demonstration and general control system.

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AQuRo: A Cat-like Adaptive Quadruped Robot With Novel Bio-Inspired Capabilities

Cited by 16 publications

References 51 publications

Editorial: Biological and Robotic Inter-Limb Coordination

Editorial: Biological and Robotic Inter-Limb Coordination

Research on fusion control of sensor information and biological reflection based on CPG

Cat-paw-inspired Tree Climbing Robot Gripper

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