Static-to-kinematic modeling and experimental validation of tendon-driven quasi continuum manipulators with nonconstant subsegment stiffness

Abstract: Continuum robots with high flexibility and compliance have the capability to operate in confined and cluttered environments. To enhance the load capacity while maintaining robot dexterity, we propose a novel non-constant subsegment stiffness (NSS) structure for tendon-driven quasi continuum robots (TDQCR) comprising rigid-flexible coupling subsegments. Aiming at real-time control applications, we present a novel static-to-kinematic modeling approach to gain a comprehensive understanding of the TDQCR model. The… Show more

“…The continuum robot is generally composed of several segments and each segment is driven by four cables [38]. The spring deforms elastically by pulling the actuated cables, resulting in flexible bending of the robot.…”

Collision-free path planning for cable-driven continuum robot based on improved artificial potential field

“…The continuum robot is generally composed of several segments and each segment is driven by four cables [38]. The spring deforms elastically by pulling the actuated cables, resulting in flexible bending of the robot.…”

Collision-free path planning for cable-driven continuum robot based on improved artificial potential field

Fixed-time tracking control of a cable-driven continuum manipulator with unmodeled dynamics