TY - GEN
T1 - Achieving High Stiffness Range of Force Feedback Gloves using Variable Stiffness Mechanism
AU - Guo, Yuan
AU - Wang, Dangxiao
AU - Wang, Ziqi
AU - Yang, Xiuping
AU - Wang, Haitong
AU - Zhang, Yuru
AU - Xu, Weiliang
N1 - Publisher Copyright:
© 2019 IEEE.
PY - 2019/7
Y1 - 2019/7
N2 - Force feedback glove is a promising interface for producing immersive haptic sensation in virtual reality and teleoperation systems. One open problem of existing gloves is to simulate virtual objects with adjustable stiffness in a fast dynamic response, along with lightweight and good back-drivability. In this paper, we introduce a leverage pivot modulating mechanism to achieve variable stiffness simulation for force feedback gloves. To simulate free space operation, the revolute pairs of the mechanism move in the unlocked state, which allows the user to clench his/her fist or fully extend fingers. To simulate constrained space operation, the revolute pairs are locked and passive feedback forces are generated at the fingertip. The total weight of the single-finger prototype glove is 55g. Experimental results show that the backdrive force of the glove is less than 0.069N in the free space, and the fingertip force reaches up to 12.76N in the constrained space. The stiffness of the glove is tuned by changing its structural stiffness, which ranges from 136.96Nmm/rad to 3368.99Nmm/rad.
AB - Force feedback glove is a promising interface for producing immersive haptic sensation in virtual reality and teleoperation systems. One open problem of existing gloves is to simulate virtual objects with adjustable stiffness in a fast dynamic response, along with lightweight and good back-drivability. In this paper, we introduce a leverage pivot modulating mechanism to achieve variable stiffness simulation for force feedback gloves. To simulate free space operation, the revolute pairs of the mechanism move in the unlocked state, which allows the user to clench his/her fist or fully extend fingers. To simulate constrained space operation, the revolute pairs are locked and passive feedback forces are generated at the fingertip. The total weight of the single-finger prototype glove is 55g. Experimental results show that the backdrive force of the glove is less than 0.069N in the free space, and the fingertip force reaches up to 12.76N in the constrained space. The stiffness of the glove is tuned by changing its structural stiffness, which ranges from 136.96Nmm/rad to 3368.99Nmm/rad.
UR - https://www.scopus.com/pages/publications/85072764040
U2 - 10.1109/WHC.2019.8816160
DO - 10.1109/WHC.2019.8816160
M3 - 会议稿件
AN - SCOPUS:85072764040
T3 - 2019 IEEE World Haptics Conference, WHC 2019
SP - 205
EP - 210
BT - 2019 IEEE World Haptics Conference, WHC 2019
PB - Institute of Electrical and Electronics Engineers Inc.
T2 - 2019 IEEE World Haptics Conference, WHC 2019
Y2 - 9 July 2019 through 12 July 2019
ER -