TY - GEN
T1 - An efficient locomotion strategy for six-strut tensegrity robots
AU - Zhao, Yongjia
AU - Zhou, Suiping
AU - Lin, Changhong
AU - Li, Daiwei
N1 - Publisher Copyright:
© 2017 IEEE.
PY - 2017/8/4
Y1 - 2017/8/4
N2 - Tensegrity is a balanced mechanical structure composed of a set of rigid members that are connected by elastic tensile members. Tensegrity-like robots have received significant attention for its light-weight, robustness and deployability. However, the locomotion control of a tensegrity robot is still a challenging problem due to the complex nonlinear coupling among the struts and cables. In this paper, a straightforward, easy to implement compare-and-search based strategy for six-strut tensegrity robot is proposed to achieve continuous rolling toward given targets without developing step-wise locomotion policies for different adjacent relationship separately. To validate the proposed strategy, simulation experiments have been performed. Results show that the strategy works well on rough terrains and it is robust to external disturbances. In particular, the proposed strategy allows the robot to escape from the trap by jumping in certain situations. A physical prototype robot is also built based on the proposed strategy.
AB - Tensegrity is a balanced mechanical structure composed of a set of rigid members that are connected by elastic tensile members. Tensegrity-like robots have received significant attention for its light-weight, robustness and deployability. However, the locomotion control of a tensegrity robot is still a challenging problem due to the complex nonlinear coupling among the struts and cables. In this paper, a straightforward, easy to implement compare-and-search based strategy for six-strut tensegrity robot is proposed to achieve continuous rolling toward given targets without developing step-wise locomotion policies for different adjacent relationship separately. To validate the proposed strategy, simulation experiments have been performed. Results show that the strategy works well on rough terrains and it is robust to external disturbances. In particular, the proposed strategy allows the robot to escape from the trap by jumping in certain situations. A physical prototype robot is also built based on the proposed strategy.
UR - https://www.scopus.com/pages/publications/85029906647
U2 - 10.1109/ICCA.2017.8003096
DO - 10.1109/ICCA.2017.8003096
M3 - 会议稿件
AN - SCOPUS:85029906647
T3 - IEEE International Conference on Control and Automation, ICCA
SP - 413
EP - 418
BT - 2017 13th IEEE International Conference on Control and Automation, ICCA 2017
PB - IEEE Computer Society
T2 - 13th IEEE International Conference on Control and Automation, ICCA 2017
Y2 - 3 July 2017 through 6 July 2017
ER -