Tendon-driven continuum robots with extensible sections-A model-based evaluation of path-following motions

Research output: Contribution to journalArticleResearchpeer review

Authors

  • Ernar Amanov
  • Thien-Dang Nguyen
  • Jessica Burgner-Kahrs

Research Organisations

External Research Organisations

  • University of Toronto
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Details

Original languageEnglish
Pages (from-to)7-23
Number of pages17
JournalInternational Journal of Robotics Research
Volume40
Issue number1
Early online date17 Nov 2019
Publication statusPublished - 1 Jan 2021

Abstract

Continuum robots are highly miniaturizable, exhibit non-linear shapes with several curves, and are flexible and compliant. In particular, concentric-tube and tendon-driven continuum robots can be designed on a small scale with diameters of below 10 mm. A small diameter-to-length ratio enables insertion of these robots through small entry points in order to reach hardly accessible regions by avoiding obstacles. This scenario can often be found in minimally invasive surgery and technical inspections. However, to reach the target region, a deployment along a narrow tortuous path is often required. Common tendon-driven continuum robots are intrinsically incapable of such deployment and concentric-tube continuum robots require special path conditions and intensive parameter optimization. Other proposed robot types, such as hyper-redundant and pneumatically actuated robots, exhibit less favorable diameter-to-length ratios and are thus not suitable for those tasks. Since the limiting factors are found in the design of continuum robots, we propose a novel tendon-driven continuum robot design, which features an additional degree of freedom in each robot section. The backbone is composed of straight, concentrically arranged tubes, each of which composes a section and is used to adapt its length. We present a three-section continuum robot prototype with a diameter of 7 mm, determine its follow-the-leader capabilities theoretically, and validate the results experimentally using model-based control. For our 165 mm long robot prototype, the repeatability is below 2.38 mm. The model accuracy reaches a median of 3.16% over 25 configurations with respect to robot length. The path-following error over five curvilinear paths results in median errors of 2.59% with respect to robot length.

Keywords

    Continuum robots, tendon-driven, follow-the-leader, model-based control, tendon elongation modeling

ASJC Scopus subject areas

Cite this

Tendon-driven continuum robots with extensible sections-A model-based evaluation of path-following motions. / Amanov, Ernar; Thien-Dang Nguyen; Burgner-Kahrs, Jessica.
In: International Journal of Robotics Research, Vol. 40, No. 1, 01.01.2021, p. 7-23.

Research output: Contribution to journalArticleResearchpeer review

Amanov, E, Thien-Dang Nguyen & Burgner-Kahrs, J 2021, 'Tendon-driven continuum robots with extensible sections-A model-based evaluation of path-following motions', International Journal of Robotics Research, vol. 40, no. 1, pp. 7-23. https://doi.org/10.1177/0278364919886047
Amanov, E., Thien-Dang Nguyen, & Burgner-Kahrs, J. (2021). Tendon-driven continuum robots with extensible sections-A model-based evaluation of path-following motions. International Journal of Robotics Research, 40(1), 7-23. https://doi.org/10.1177/0278364919886047
Amanov E, Thien-Dang Nguyen, Burgner-Kahrs J. Tendon-driven continuum robots with extensible sections-A model-based evaluation of path-following motions. International Journal of Robotics Research. 2021 Jan 1;40(1):7-23. Epub 2019 Nov 17. doi: 10.1177/0278364919886047
Amanov, Ernar ; Thien-Dang Nguyen ; Burgner-Kahrs, Jessica. / Tendon-driven continuum robots with extensible sections-A model-based evaluation of path-following motions. In: International Journal of Robotics Research. 2021 ; Vol. 40, No. 1. pp. 7-23.
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title = "Tendon-driven continuum robots with extensible sections-A model-based evaluation of path-following motions",
abstract = "Continuum robots are highly miniaturizable, exhibit non-linear shapes with several curves, and are flexible and compliant. In particular, concentric-tube and tendon-driven continuum robots can be designed on a small scale with diameters of below 10 mm. A small diameter-to-length ratio enables insertion of these robots through small entry points in order to reach hardly accessible regions by avoiding obstacles. This scenario can often be found in minimally invasive surgery and technical inspections. However, to reach the target region, a deployment along a narrow tortuous path is often required. Common tendon-driven continuum robots are intrinsically incapable of such deployment and concentric-tube continuum robots require special path conditions and intensive parameter optimization. Other proposed robot types, such as hyper-redundant and pneumatically actuated robots, exhibit less favorable diameter-to-length ratios and are thus not suitable for those tasks. Since the limiting factors are found in the design of continuum robots, we propose a novel tendon-driven continuum robot design, which features an additional degree of freedom in each robot section. The backbone is composed of straight, concentrically arranged tubes, each of which composes a section and is used to adapt its length. We present a three-section continuum robot prototype with a diameter of 7 mm, determine its follow-the-leader capabilities theoretically, and validate the results experimentally using model-based control. For our 165 mm long robot prototype, the repeatability is below 2.38 mm. The model accuracy reaches a median of 3.16% over 25 configurations with respect to robot length. The path-following error over five curvilinear paths results in median errors of 2.59% with respect to robot length.",
keywords = "Continuum robots, tendon-driven, follow-the-leader, model-based control, tendon elongation modeling",
author = "Ernar Amanov and {Thien-Dang Nguyen} and Jessica Burgner-Kahrs",
note = "Funding Information: https://orcid.org/0000-0002-2866-0487 Amanov Ernar 1 Nguyen Thien-Dang 1 https://orcid.org/0000-0001-9185-3970 Burgner-Kahrs Jessica 1 2 1 Laboratory of Continuum Robotics, Leibniz Universit{\"a}t Hannover, Germany 2 Continuum Robotics Laboratory, University of Toronto Mississauga, Canada Jessica Burgner-Kahrs, Continuum Robotics Laboratory, University of Toronto Mississauga, 3359 Mississauga Rd, Toronto, ON, Canada. Email: jessica.burgnerkahrs@utoronto.ca 11 2019 0278364919886047 {\textcopyright} The Author(s) 2019 2019 SAGE Publications Continuum robots are highly miniaturizable, exhibit non-linear shapes with several curves, and are flexible and compliant. In particular, concentric-tube and tendon-driven continuum robots can be designed on a small scale with diameters of below 10 mm. A small diameter-to-length ratio enables insertion of these robots through small entry points in order to reach hardly accessible regions by avoiding obstacles. This scenario can often be found in minimally invasive surgery and technical inspections. However, to reach the target region, a deployment along a narrow tortuous path is often required. Common tendon-driven continuum robots are intrinsically incapable of such deployment and concentric-tube continuum robots require special path conditions and intensive parameter optimization. Other proposed robot types, such as hyper-redundant and pneumatically actuated robots, exhibit less favorable diameter-to-length ratios and are thus not suitable for those tasks. Since the limiting factors are found in the design of continuum robots, we propose a novel tendon-driven continuum robot design, which features an additional degree of freedom in each robot section. The backbone is composed of straight, concentrically arranged tubes, each of which composes a section and is used to adapt its length. We present a three-section continuum robot prototype with a diameter of 7 mm, determine its follow-the-leader capabilities theoretically, and validate the results experimentally using model-based control. For our 165 mm long robot prototype, the repeatability is below 2.38 mm. The model accuracy reaches a median of 3.16% over 25 configurations with respect to robot length. The path-following error over five curvilinear paths results in median errors of 2.59% with respect to robot length. Continuum robots tendon-driven follow-the-leader model-based control tendon elongation modeling Deutsche Forschungsgemeinschaft https://doi.org/10.13039/501100001659 BU 2935/1-1 edited-state corrected-proof Funding This work was supported by the German Research Foundation (DFG) (grant number BU 2935/1-1). ORCID iDs Ernar Amanov https://orcid.org/0000-0002-2866-0487 Jessica Burgner-Kahrs https://orcid.org/0000-0001-9185-3970",
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T1 - Tendon-driven continuum robots with extensible sections-A model-based evaluation of path-following motions

AU - Amanov, Ernar

AU - Thien-Dang Nguyen,

AU - Burgner-Kahrs, Jessica

N1 - Funding Information: https://orcid.org/0000-0002-2866-0487 Amanov Ernar 1 Nguyen Thien-Dang 1 https://orcid.org/0000-0001-9185-3970 Burgner-Kahrs Jessica 1 2 1 Laboratory of Continuum Robotics, Leibniz Universität Hannover, Germany 2 Continuum Robotics Laboratory, University of Toronto Mississauga, Canada Jessica Burgner-Kahrs, Continuum Robotics Laboratory, University of Toronto Mississauga, 3359 Mississauga Rd, Toronto, ON, Canada. Email: jessica.burgnerkahrs@utoronto.ca 11 2019 0278364919886047 © The Author(s) 2019 2019 SAGE Publications Continuum robots are highly miniaturizable, exhibit non-linear shapes with several curves, and are flexible and compliant. In particular, concentric-tube and tendon-driven continuum robots can be designed on a small scale with diameters of below 10 mm. A small diameter-to-length ratio enables insertion of these robots through small entry points in order to reach hardly accessible regions by avoiding obstacles. This scenario can often be found in minimally invasive surgery and technical inspections. However, to reach the target region, a deployment along a narrow tortuous path is often required. Common tendon-driven continuum robots are intrinsically incapable of such deployment and concentric-tube continuum robots require special path conditions and intensive parameter optimization. Other proposed robot types, such as hyper-redundant and pneumatically actuated robots, exhibit less favorable diameter-to-length ratios and are thus not suitable for those tasks. Since the limiting factors are found in the design of continuum robots, we propose a novel tendon-driven continuum robot design, which features an additional degree of freedom in each robot section. The backbone is composed of straight, concentrically arranged tubes, each of which composes a section and is used to adapt its length. We present a three-section continuum robot prototype with a diameter of 7 mm, determine its follow-the-leader capabilities theoretically, and validate the results experimentally using model-based control. For our 165 mm long robot prototype, the repeatability is below 2.38 mm. The model accuracy reaches a median of 3.16% over 25 configurations with respect to robot length. The path-following error over five curvilinear paths results in median errors of 2.59% with respect to robot length. Continuum robots tendon-driven follow-the-leader model-based control tendon elongation modeling Deutsche Forschungsgemeinschaft https://doi.org/10.13039/501100001659 BU 2935/1-1 edited-state corrected-proof Funding This work was supported by the German Research Foundation (DFG) (grant number BU 2935/1-1). ORCID iDs Ernar Amanov https://orcid.org/0000-0002-2866-0487 Jessica Burgner-Kahrs https://orcid.org/0000-0001-9185-3970

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