Equilibrium Conformations of Concentric-tube Continuum Robots. Rucker, D. C., Robert J. Webster, I., Chirikjian, G. S., & Cowan, N. J. The International Journal of Robotics Research, 29(10):1263–1280, September, 2010.
Equilibrium Conformations of Concentric-tube Continuum Robots [link]Paper  doi  abstract   bibtex   
Robots consisting of several concentric, preshaped, elastic tubes can work dexterously in narrow, constrained, and/or winding spaces, as are commonly found in minimally invasive surgery. Previous models of these “active cannulas” assume piecewise constant precurvature of component tubes and neglect torsion in curved sections of the device. In this paper we develop a new coordinate-free energy formulation that accounts for general preshaping of an arbitrary number of component tubes, and which explicitly includes both bending and torsion throughout the device. We show that previously reported models are special cases of our formulation, and then explore in detail the implications of torsional flexibility for the special case of two tubes. Experiments demonstrate that this framework is more descriptive of physical prototype behavior than previous models1 it reduces model prediction error by 82% over the calibrated bending-only model, and 17% over the calibrated transmissional torsion model in a set of experiments.
@article{rucker_equilibrium_2010,
	title = {Equilibrium {Conformations} of {Concentric}-tube {Continuum} {Robots}},
	volume = {29},
	issn = {0278-3649},
	url = {https://doi.org/10.1177/0278364910367543},
	doi = {10.1177/0278364910367543},
	abstract = {Robots consisting of several concentric, preshaped, elastic tubes can work dexterously in narrow, constrained, and/or winding spaces, as are commonly found in minimally invasive surgery. Previous models of these “active cannulas” assume piecewise constant precurvature of component tubes and neglect torsion in curved sections of the device. In this paper we develop a new coordinate-free energy formulation that accounts for general preshaping of an arbitrary number of component tubes, and which explicitly includes both bending and torsion throughout the device. We show that previously reported models are special cases of our formulation, and then explore in detail the implications of torsional flexibility for the special case of two tubes. Experiments demonstrate that this framework is more descriptive of physical prototype behavior than previous models1 it reduces model prediction error by 82\% over the calibrated bending-only model, and 17\% over the calibrated transmissional torsion model in a set of experiments.},
	language = {en},
	number = {10},
	urldate = {2018-03-24TZ},
	journal = {The International Journal of Robotics Research},
	author = {Rucker, D. Caleb and Robert J. Webster, III and Chirikjian, Gregory S. and Cowan, Noah J.},
	month = sep,
	year = {2010},
	pages = {1263--1280}
}

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