期刊文献+

圆周对称分布六腿机器人三种典型行走步态步长及稳定性分析 被引量:21

Stride Size and Stability Analysis of a Radially Symmetrical Hexapod Robot in Three Typical Gaits
原文传递
导出
摘要 针对现有圆周对称分布六腿步行机器人步长研究中存在的缺点和不足,提出了并联机构支链工作空间相交法,将由机器人本体、支撑腿和地面组成的并联机构分割成不同的分支,利用各分支工作空间求交,从而确定机器人在某一本体高度上的步长和稳定裕度.该方法可在已知机器人立足点和本体高度的情况下求得机器人的最大可行步长和稳定裕度,也可以求得机器人在某一本体高度上的极限可行步长和在这种情况下的立足点的位置,还可以根据已知步长和机器人本体高度来确定最大稳定裕度和最大稳定裕度下的立足点的位置.这种方法为圆周对称分布六腿机器人采用不同步态行走过程中立足点、本体高度和步长的选取提供重要参考. For the shortcomings and the insufficiencies in study of stride size of radially symmetrical hexapod robots, a workspace intersection method for parallel mechanism is proposed. In the method, the parallel mechanism composed of robot body, supporting legs and ground is divided into different branches, and according to the intersections of the workspaces of all the branches, and the stride size and stability margin of the robot can be deduced at any body height. By using this method, the maximum feasible stride size and stability margin can be obtained when the body height and the footholds are known. And its extreme stride size and the corresponding footholds at a certain body height can be solved. Meanwhile, the maximum stability margin and the corresponding suitable footholds can be determined while the stride size and body height are certain. This method provides a good reference for the radially symmetrical hexapod robot to choose suitable footholds, body height and stride size while walking in different gaits.
出处 《机器人》 EI CSCD 北大核心 2012年第2期231-241,256,共12页 Robot
基金 国家863计划资助项目(2006AA04Z207) 中意政府重大科技合作计划资助项目
关键词 六腿机器人 圆周对称分布结构 几何法 步长 稳定裕度 hexapod robot radially symmetrical structure geometrical method stride size stability margin
  • 相关文献

参考文献13

  • 1Kamikawa K,Arai T,Inoue K,et al.Omni-directional gait of multi-legged rescue robot[C]//IEEE International Conference on Robotics & Automation.Piscataway,NJ,USA:IEEE,2004: 2171-2176.
  • 2Yang J M,Kim J H.Fault-tolerant locomotion of the hexapod robot[J].IEEE Transactions on Systems,Man,and Cybernetics, Part B,1998,28(1):109-116.
  • 3Hirose S.Three basic types of locomotion in mobile robots [C]//5th International Conference on Advanced Robotics.Piscataway, NJ,USA:IEEE,1991:12-17.
  • 4Yang J M,Kim J H.A strategy of optimal fault tolerant gait for the hexapod robot in crab walking[C]//IEEE International Conference on Robotics and Automation.Piscataway,NJ,USA: IEEE,1998:1695-1700.
  • 5Chu S K K,Pang G K H.Comparison between different model of hexapod robot in fault-tolerant gait[J].IEEE Transactions on Systems,Man,and Cybernetics,Part A,2002,32(6):752-756.
  • 6Roy S S,Singh A K,Pratihar D K,et al.Analysis of sixlegged walking robots[C]//National Conference on Machines and Mechanisms.2009:259-265.
  • 7丁希仑,王志英,Alberto ROVETTA.六边形对称分布六腿机器人的典型步态及其运动性能分析[J].机器人,2010,32(6):759-765. 被引量:18
  • 8Chen X D.Novel formulation of static stability for a walking quadruped robot[J].Chinese Journal of Mechanical Engineering: English Edition,2003,16(2):120-122.
  • 9Lee T T,Liao C M,Chen T K.On the stabihty properties of hexapod tripod gait[J].IEEE Journal of Robotics and Automation, 1988,4(4):427-434.
  • 10Preumont A,Alexandre P,Ghuys D.Gait analysis and implementation of a six leg walking machine[C]//5th International Conference on Advanced Robotics.Piscataway,NJ,USA: IEEE,1991:941-945.

二级参考文献33

  • 1Hirose S.Three basic types of locomotion in mobile robots[C] //Sth International Conference on Advanced Robotics.Piscataway,NJ,USA:IEEE,1991:12-17.
  • 2Lee B H,Lee I K.The implementation of the gaits and body structure for hexapod robot[C] //IEEE International Symposium on Industrial Electronics.Piscataway,NJ,USA:IEEE,2001:1959-1964.
  • 3Lee T T,Liao C M,Chen T K.On the stability properties of hexapod tripod gait[J].IEEE Journal of Robotics and Automation,1988,4(4):427-434.
  • 4Lee W J,Orin D E.Omnidirectional supervisory control of a multilegged vehicle using periodic gaits[C] //IEEE Journal of Robotics and Automation,1988,4(6):635-642.
  • 5Kamikawa K,Arai T,Inoue K,et al.Omni-directional gait of multi-legged rescue robot[C] //IEEE International Conference on Robotics and Automation.Piscataway,NJ,USA:IEEE,2004:2171-2176.
  • 6Bares J,Hebert M,Kanade T,et al.Ambler-An autonomous rover for planetary exploration[J].Computer,1989,22(6):18-26.
  • 7Erden M S,Leblebicioglu K.Free gait generation with reinforcement learning for a six-legged robot[J].Robotics and Autonomous Systems,2008,56(3):199-212.
  • 8McGhee R B,Iswandhi G I.Adaptive locomotion of a multilegged robot over rough terrain[J].IEEE Transactions on Systerns,Man,and Cybernetics,1979,9(4):176-182.
  • 9Porta J M,Celaya E.Reactive free-gait generation to follow arbitrary trajectories with a hexapod robot[J].Robotics and Autonomous Systems,2004,47(4):187-201.
  • 10Yang J M,Kim J H.Fault-tolerant locomotion of the hexapod robot[J].IEEE Transactions on Systems,Man,and Cybernetics,Part B,1998,28(1):109-116.

共引文献39

同被引文献159

引证文献21

二级引证文献206

相关作者

内容加载中请稍等...

相关机构

内容加载中请稍等...

相关主题

内容加载中请稍等...

浏览历史

内容加载中请稍等...
;
使用帮助 返回顶部