Research continuum2004

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* Load can be re-distributed among the backbones without shape variation. This assumption is introduced in (Simaan 2005) by presenting a general resolution for actuation redundancy. Results from the analytic modeling using elliptic integrals show that the tip position variation is less than 0.05% of the segment’s length (while the tip orientation is kept the same) when loads redistrubited.
* Load can be re-distributed among the backbones without shape variation. This assumption is introduced in (Simaan 2005) by presenting a general resolution for actuation redundancy. Results from the analytic modeling using elliptic integrals show that the tip position variation is less than 0.05% of the segment’s length (while the tip orientation is kept the same) when loads redistrubited.
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In the following video clips, an one-segment continuum robot is simulated in MATLAB. By changing the lengths of corresponding backbones, the robot will bend to the side. On the right, a three-segment continuum robot with force sensing capability is palpating a prostate model for tumor detection. For details, please refer to papers listed under the publication session.
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|align="center"|'''An one-segment continuum robot simulatied in MATLAB'''
|align="center"|'''An one-segment continuum robot simulatied in MATLAB'''

Revision as of 05:28, 3 October 2010


A Continuum Structure as Medical Robotic End Effector

January 2005 to August 2009

Note bulb.png This work was done when Dr. Kai Xu was with the Advanced Robotics & Mechanism Applications Lab, Department of Mechanical Engineering, Columbia University.

Continuum robots involved in this research: (A) a Ø7.5mm one; (B) a Ø4.2mm one; (C) a two-segment continuum robot with a detachable gripper; (D) a three-segment continuum robot with intrinsic force sensing capability

This continuum structures in this research were introduced by Simaan et al. (Simaan, Taylor et al. 2004; Simaan, Taylor et al. 2004). They consist of one or more flexible segments. Each segment consists of multiple superelastic NiTi components (tubes or beams) called backbones and several rigid disks. The figure to the right shows several examples: insets (A) and (B) show a one-segment continuum robot, inset (C) shows a two-segment continuum robot with a detachable gripper and inset (D) shows a three-segment robot with intrinsic force sensing capability.

In these examples, each segment includes one primary backbone, three secondary backbones and a few disks. As the figure below shows, the primary backbone is centrally located and three identical secondary backbones are equidistant from each other and from the primary backbone. The primary backbone is attached to the base disk and the end disk, while the secondary backbones are only attached to the end disk and can slide in appropriately toleranced holes in the base disk and in the spacer disks. Two adjacent disks and the backbones form a subsegment. Each segment possesses two degrees of freedom (DoF) via simultaneous actuation of the three secondary backbones in a push-pull mode. Since three secondary backbones are independently actuated to carry out a 2-DoF motion, these continuum robots feature actuation redundancy.

Structure of one continuum segment

Multiple segments can be serially stacked through the use of concentric NiTi backbones to form a continuum robot with more DoFs. Three segments of the snake-like continuum robot can be stacked and numbered from the proximal end to the distal end. The end disk of the first segment also acts as the base disk of the second segment, while the end disk of the second segment also serves as the base disk of the third segment. Backbones of the first and second segment are concentric superelastic NiTi tubes, while the third segment’s backbones are superelastic NiTi beams passing through the second segment’s tubes.

According to the modeling framework presented by Simaan (Simaan, Taylor et al. 2004; Simaan, Taylor et al. 2004; Simaan 2005), shape of the continuum segment shown in Figure 2.1 assumes a constant twist distribution. Following the equivalent simplifications below, simplified models for kinematics and statics will be presented.

  • Shape of the primary backbone is circular. This approximation have been experimentally verified. Analytic modeling using elliptic integrals shows that in one actuation mode, shape of the primary backbone is strictly circular. In the other actuation mode, shape of the primary backbone is very close to circular.
  • Shape of the secondary backbones is circular. This approximation will introduce some experiment-based corrections.
  • Load can be re-distributed among the backbones without shape variation. This assumption is introduced in (Simaan 2005) by presenting a general resolution for actuation redundancy. Results from the analytic modeling using elliptic integrals show that the tip position variation is less than 0.05% of the segment’s length (while the tip orientation is kept the same) when loads redistrubited.

In the following video clips, an one-segment continuum robot is simulated in MATLAB. By changing the lengths of corresponding backbones, the robot will bend to the side. On the right, a three-segment continuum robot with force sensing capability is palpating a prostate model for tumor detection. For details, please refer to papers listed under the publication session.

An one-segment continuum robot simulatied in MATLAB A three-segment continuum robot in palpation
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