2015
DOI: 10.1177/0278364914558006
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Five-degree-of-freedom manipulation of an untethered magnetic device in fluid using a single permanent magnet with application in stomach capsule endoscopy

Abstract: This paper demonstrates magnetic three-degree-of-freedom (3-DOF) closed-loop position and 2-DOF open-loop orientation control of a mockup magnetic capsule endoscope in fluid with a single permanent magnet positioned by a commercial 6-DOF robotic manipulator, using feedback of only the 3-DOF capsule position measured by a localization system, with application in capsule endoscopy of a fluid-distended stomach. We analyze the kinematics of magnetic manipulation using a single permanent magnet as the end-effector … Show more

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Cited by 213 publications
(132 citation statements)
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“…86,87,88 Their 6-DOF robot arm had a motor-rotatable permanent magnet as an end-effector [ Fig. 4(b)].…”
Section: B1 Magnetically Guided Capsule Gastroscopymentioning
confidence: 99%
“…86,87,88 Their 6-DOF robot arm had a motor-rotatable permanent magnet as an end-effector [ Fig. 4(b)].…”
Section: B1 Magnetically Guided Capsule Gastroscopymentioning
confidence: 99%
“…The permanent magnetic systems are suitable for in vivo tasks, for which the applied organisms are too big for an electromagnetic system. For example, Mahoney et al used a rotating permanent magnet mounted on a robotic arm to actuate an untethered magnetic device for the application in stomach capsule endoscopy [71]. The magnetic magnitude of a permanent magnet is stronger than electromagnets, but attenuates quickly with the distance.…”
Section: Rotating Permanent Magnetic Systemsmentioning
confidence: 99%
“…By following the above procedure, we find: Brmax=51. 9 [mT], and xoptimal =[37.9,100 0 ,27]. Therefore, r 2opt =37.9 mm, ∆θ opt =100 0 , r1 *∆θopt=52.4 mm, and ∆z opt =27 mm.…”
Section: Optimization Of the Arc-shaped Permanent Magnetsmentioning
confidence: 99%
“…For example, a ring-shaped IPM to control the trajectory of a CE was used in [8,9], ring-shaped IPMs to deploy legs as a locomotion system for a CE were used in [10,11], cylindrical IPMs for biopsy purposes were used in [2,6] and two spherical IPMs to achieve wireless insufflation were employed in [7]. Furthermore, two cylindrical IPMs to release drug from a chamber in a prototype of CE were reported in [12,13].…”
Section: Introductionmentioning
confidence: 99%