A master manipulator with a remote-center-of-motion kinematic structure for a minimally invasive robotic surgical system

Cited 13 time in webofscience Cited 0 time in scopus
  • Hit : 765
  • Download : 0
BackgroundIn robotic surgical systems, commercial master devices have limitations owing to insufficient workspace and lack of intuitiveness. To overcome these limitations, a remote-center-of-motion (RCM) master manipulator was proposed. MethodsThe feasibility of the proposed RCM structure was evaluated through kinematic analysis using a conventional serial structure. Two performance comparison experiments (peg transfer task and objective transfer task) were conducted for the developed master and Phantom Omni. ResultsThe kinematic analysis results showed that compared with the serial structure, the proposed RCM structure has better performance in terms of design efficiency (19%) and workspace quality (59.08%). Further, in comparison with Phantom Omni, the developed master significantly increased task efficiency and significantly decreased workload in both experiments. ConclusionsThe comparatively better performance in terms of intuitiveness, design efficiency, and operability of the proposed master for a robotic system for minimally invasive surgery was confirmed through kinematic and experimental analysis.
Publisher
WILEY
Issue Date
2018-02
Language
English
Article Type
Article
Keywords

SINGLE-PORT SURGERY; PERFORMANCE; OPTIMIZATION; MECHANISM; DESIGN; CONSTRUCT; SIMULATOR; VALIDITY; FEEDBACK; SKILLS

Citation

INTERNATIONAL JOURNAL OF MEDICAL ROBOTICS AND COMPUTER ASSISTED SURGERY, v.14, no.1

ISSN
1478-5951
DOI
10.1002/rcs.1865
URI
http://hdl.handle.net/10203/239901
Appears in Collection
ME-Journal Papers(저널논문)
Files in This Item
There are no files associated with this item.
This item is cited by other documents in WoS
⊙ Detail Information in WoSⓡ Click to see webofscience_button
⊙ Cited 13 items in WoS Click to see citing articles in records_button

qr_code

  • mendeley

    citeulike


rss_1.0 rss_2.0 atom_1.0