基于球形磁关节和可调套筒的多足机器人倒立运动步态生成

IF 0.9 Q4 ROBOTICS

Journal of Robotics and Mechatronics Pub Date : 2023-10-20 DOI:10.20965/jrm.2023.p1227

Harn Sison, Photchara Ratsamee, Manabu Higashida, Yuki Uranishi, Haruo Takemura

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引用次数: 0

摘要

本文提出了一种基于球形磁关节(SMJ)的多足机器人倒立运动步态生成方法的设计与实现。选择球形永磁体产生一致的吸引力，使机器人能够在钢结构下进行倒立运动。此外，机器人的脚尖被设计为一个球关节机构，在脚尖和表面之间的任何角度都提供了灵活性。我们还引入了一个可调节的套筒机制，通过在倾斜和拉动步骤中创建一个支点，在运动期间分离脚尖。该机构有效地减小了基于套筒直径的反作用力。实验结果表明，与直接拉拔相比，使用可调套筒机构可减少46%的当前负载。针对倒立运动，构建了四足机器人和六足机器人，这两种机器人代表了多足机器人的主要类型。我们将SMJ和可调节套筒集成到这两个机器人中，使它们能够以各种步态进行倒立运动，如爬行、小跑、广场和三脚架步态。我们的分析检查了每种步态在速度和稳定性方面的特征，从而证实了所提出的SMJ的多功能性，可以应用于不同类型的有腿机器人。

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Generation of Inverted Locomotion Gait for Multi-Legged Robots Using a Spherical Magnetic Joint and Adjustable Sleeve

In this paper, we propose the design and implementation of spherical magnetic joint (SMJ)-based gait generation for the inverted locomotion of multi-legged robots. A spherical permanent magnet was selected to generate a consistent attractive force, enabling the robot to perform inverted locomotion under steel structures. Additionally, the robot’s foot tip was designed as a balljoint mechanism, providing flexibility in foot placement at any angle between the tip and surface. We also introduced an adjustable sleeve mechanism to detach the foot tip during locomotion by creating a fulcrum during the tilt and pull steps. This mechanism effectively reduced the reaction force based on the sleeve diameter. The experimental results showed a 46% decrease in the present load when using the adjustable sleeve mechanism compared to direct pulling. For inverted locomotion, a quadruped robot and a hexapod robot, which represent the predominant type of multi-legged robots, were constructed. We integrated the SMJ and adjustable sleeve into both robots, enabling them to perform inverted locomotion with various gaits such as crawling, trotting, square, and tripod gaits. Our analysis examined the characteristics of each gait in terms of velocity and stability, thereby confirming the versatility of the proposed SMJ, which can be applied to different types of legged robots.

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来源期刊

Journal of Robotics and Mechatronics ROBOTICS-

CiteScore

2.20

自引率

36.40%

发文量

134

期刊介绍： First published in 1989, the Journal of Robotics and Mechatronics (JRM) has the longest publication history in the world in this field, publishing a total of over 2,000 works exclusively on robotics and mechatronics from the first number. The Journal publishes academic papers, development reports, reviews, letters, notes, and discussions. The JRM is a peer-reviewed journal in fields such as robotics, mechatronics, automation, and system integration. Its editorial board includes wellestablished researchers and engineers in the field from the world over. The scope of the journal includes any and all topics on robotics and mechatronics. As a key technology in robotics and mechatronics, it includes actuator design, motion control, sensor design, sensor fusion, sensor networks, robot vision, audition, mechanism design, robot kinematics and dynamics, mobile robot, path planning, navigation, SLAM, robot hand, manipulator, nano/micro robot, humanoid, service and home robots, universal design, middleware, human-robot interaction, human interface, networked robotics, telerobotics, ubiquitous robot, learning, and intelligence. The scope also includes applications of robotics and automation, and system integrations in the fields of manufacturing, construction, underwater, space, agriculture, sustainability, energy conservation, ecology, rescue, hazardous environments, safety and security, dependability, medical, and welfare.