Gustavo A. Medrano-Cerda scite author profile

Variable length multisection continuum arms are a class of continuum robotic manipulators that generate motion by structural mechanical deformation. Unlike most continuum robots, the sections of these arms do not have (central) supporting flexible backbone, and are actuated by multiple variable length actuators. Because of the constraining nature of actuators, the continuum sections can bend and/or elongate (compress) depending on the elongation/contraction characteristics of the actuators being used. Continuum arms have a number of distinctive differences with respect to traditional rigid arms namely: smooth bending, high inherent compliance, and adaptive whole arm grasping. However, due to numerical instability and the complexity of curve parametric models, there are no spatial dynamic models for multisection continuum arms. This paper introduces novel spatial dynamics and applies these to variable length multisection continuum arms with any number of sections. An efficient recursive computational scheme for deriving the equations of motion is presented. This is applied in a general form based on structurally accurate and numerically well posed modal kinematics that assumes circular arc deformation of continuum sections without torsion. It is shown that the proposed modal dynamics are highly scalable, producing efficient and accurate numerical results. The spatial dynamic simulation results are experimentally validated using a pneumatic muscle actuated multisection prototype continuum arm. For the first time this enables investigation of spatial dynamic effects in this class of continuum arms.

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Gain Scheduling Control for a Class of Variable Stiffness Actuators Based on Lever Mechanisms

Sardellitti

Medrano-Cerda

Tsagarakis

et al. 2013

IEEE Trans. Robot.

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The Liverpool Telescope: performance and first results

Steele

Smith

Rees³

et al. 2004

294

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Shape function-based kinematics and dynamics for variable length continuum robotic arms

Godage

Branson

Guglielmino

et al. 2011

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Stability and performance of the compliance controller of the quadruped robot HyQ

Boaventura

Medrano-Cerda

Semini

et al. 2013

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