J4 ›› 2014, Vol. 11 ›› Issue (2): 176-187.doi: 10.1016/S1672-6529(14)60041-X

• 论文 • 上一篇    下一篇

Development of a Bionic Hexapod Robot for Walking on Unstructured Terrain

He Zhang, Yubin Liu, Jie Zhao, Jie Chen, Jihong Yan   

  1. State Key Lab of Robotics and System, Harbin Institute of Technology, Harbin 150080, P. R. China
  • 出版日期:2014-03-30 发布日期:2014-04-10

Development of a Bionic Hexapod Robot for Walking on Unstructured Terrain

He Zhang, Yubin Liu, Jie Zhao, Jie Chen, Jihong Yan   

  1. State Key Lab of Robotics and System, Harbin Institute of Technology, Harbin 150080, P. R. China
  • Online:2014-03-30 Published:2014-04-10
  • Contact: Jie Chen E-mail:jchen@hit.edu.cn
  • About author:He Zhang, Yubin Liu, Jie Zhao, Jie Chen, Jihong Yan

摘要:

This paper reports the design methodology and control strategy in the development of a novel hexapod robot HITCR-II that is suitable for walking on unstructured terrain. First, the entire sensor system is designed to equip the robot with the perception of external environment and its internal states. The structure parameters are optimized for improving the dexterity of the robot. Second, a foot-force distribution model and a compensation model are built to achieve posture control. The two models are capable of effectively improving the stability of hexapod walking on unstructured terrain. Finally, the Posture Control strategy based on Force Distribution and Compensation (PCFDC) is applied to the HITCR-II hexapod robot. The experimental results show that the robot can effectively restrain the vibration of trunk and keep stable while walking and crossing over the un-structured terrains.

关键词: hexapod robot, structure optimization, posture controlΙforce distribution, force compensation

Abstract:

This paper reports the design methodology and control strategy in the development of a novel hexapod robot HITCR-II that is suitable for walking on unstructured terrain. First, the entire sensor system is designed to equip the robot with the perception of external environment and its internal states. The structure parameters are optimized for improving the dexterity of the robot. Second, a foot-force distribution model and a compensation model are built to achieve posture control. The two models are capable of effectively improving the stability of hexapod walking on unstructured terrain. Finally, the Posture Control strategy based on Force Distribution and Compensation (PCFDC) is applied to the HITCR-II hexapod robot. The experimental results show that the robot can effectively restrain the vibration of trunk and keep stable while walking and crossing over the un-structured terrains.

Key words: hexapod robot, structure optimization, posture controlΙforce distribution, force compensation