Center of Gravity-based Approach for Modeling Dynamics of Multisection Continuum Arms
Isuru S. Godage, Robert J. Webster III, Ian D. Walker

TL;DR
This paper introduces a fast, stable, and accurate center of gravity-based dynamic model for multisection continuum arms, enabling real-time control and broadening their practical applications beyond laboratory settings.
Contribution
It presents the first sub real-time dynamic model for variable-length multisection continuum arms based on a smooth continuous deformation approach.
Findings
Model runs at 9.5 kHz, 6-8 times faster than real-time.
Validated numerically and experimentally for a three-section arm.
Achieves high accuracy and computational efficiency for real-time control.
Abstract
Multisection continuum arms offer complementary characteristics to those of traditional rigid-bodied robots. Inspired by biological appendages, such as elephant trunks and octopus arms, these robots trade rigidity for compliance, accuracy for safety, and therefore exhibit strong potential for applications in human-occupied spaces. Prior work has demonstrated their superiority in operation in congested spaces and manipulation of irregularly-shaped objects. However, they are yet to be widely applied outside laboratory spaces. One key reason is that, due to compliance, they are difficult to control. Sophisticated and numerically efficient dynamic models are a necessity to implement dynamic control. In this paper, we propose a novel, numerically stable, center of gravity-based dynamic model for variable-length multisection continuum arms. The model can accommodate continuum robots having…
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