FAS-A Fully Actuated Segment for Tendon-Driven Continuum Robots

We propose a segment design that combines two distinct characteristics of tendon-driven continuum robots, i.e. variable length and non-straight tendon routing, into a single segment by enabling rotation of its backbone. As a result, this segment can vary its helical tendon routing and has four degre...

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Bibliographic Details
Published in:Frontiers in robotics and AI 2022-04, Vol.9, p.873446-873446
Main Authors: Grassmann, Reinhard M, Rao, Priyanka, Peyron, Quentin, Burgner-Kahrs, Jessica
Format: Article
Language:English
Subjects:
continuum robot manipulator
degrees of freedom
design
helical tendon routing
Robotics and AI
soft manipulator
tendon actuation
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Summary:We propose a segment design that combines two distinct characteristics of tendon-driven continuum robots, i.e. variable length and non-straight tendon routing, into a single segment by enabling rotation of its backbone. As a result, this segment can vary its helical tendon routing and has four degrees-of-freedom, while maintaining a small-scale design with an overall outer diameter of 7 mm thanks to an extrinsic actuation principle. In simulation and on prototypes, we observe improved motion capabilities, as evidenced by position redundancy and follow-the-leader deployment along spatially tortuous paths. To demonstrate the latter on a physical prototype, a simple, yet effective area-based error measure for follow-the-leader deployment is proposed to evaluate the performance. Furthermore, we derive a static model which is used to underpin the observed motion capabilities. In summary, our segment design extends previous designs with minimal hardware overhead, while either archiving similar accuracy in position errors and planar follow-the-leader deployment, or exhibiting superior motion capabilities due to position redundancy and spatial follow-the-leader deployment.
ISSN:2296-9144
2296-9144
DOI:10.3389/frobt.2022.873446