Description:
In tele-operation applications, especially in surgery, haptic devices need to exhibit a high degree of rigidity and accuracy. This paper deals with the development of a spherical parallel manipulator (SPM) that enables the satisfaction of those characteristics. The parallel architecture enables the use of this kind of robot as master in a tele-operation system. Moreover, the SPM has a center of rotation that makes it a natural candidate and more adapted to minimally invasive surgery application. However, the parallel manipulator presents a poor behavior in singular configuration. In this paper we discuss the technique we used to overcome the singularity effects. We also present the methodology of using additional sensor to avoid kinematic structure problem without design changes. The investigation of the developed solution is detailed in this paper. Also, the experimental results of the newly developed haptic device are presented in this paper.
Description:
The current objective of this robotics research study is mainly to develop a cheap and not cumbersome systems for special applications. A PROMIS (Pprime RObot for Minimally Invasive Surgery) system is designed with this philosophy. The developed system is composed of master, slave and control system for collaborative operation between the surgeon and the robot. A parallel robot haptic device is used as master to teleoperate a serial robot with three degrees of freedom (dof). The advantage of this method is the possibility of coupling master and slave with non-matching kinematics through a kinematic transformation. The developed control system architecture is presented in this paper. The control architecture was designed to control the teleoperation system where the master and slave robots do not have homothetic kinematics. Finally, the viability of the developed control is demonstrated by the experimental results.