| 研究実績の概要 |
The implementation of this research is related to the creation of two systems, one placed in the remote site composed by a robot manipulator and a visual based sensing mechanism, and another placed on the clinical room in which an operator can control and replan the motion of the robot while visualizing real-time stiffness information of the explored anatomical area.
A light weight six degree of freedom manipulator, the UFactory Lite6 collaborative robot, has been purchased and interfaced with the Robot Operating System (ROS), a powerful framework which allow implementation of algorithms-simulations for robotics and easy interface with real hardware.
A semi-autonomous navigation algorithm, in which the operator can control the motion of the robot remotely and replan the its path, has been implemented using Moveit, a motion planning navigation framework, in ROS.
Although the operator can replan the motion of the robot and control it remotely, virtual fixture will be implemented using the visual-stiffness information to control the force and integrate safety futures during the contact.
The control and planning algorithm have been initially tested in simulations and are now interfaced with the real robot.
A novel 3D machine learning algorithm, that shatters the constraints of conventional methodologies, is implemented to find the optimal design of the sensing mechanism. The method is still in a development phase.
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| 今後の研究の推進方策 |
In this year the PI will work on the finalization of the optimization algorithm, manufacturing of the sensor and realization of the interface that will be implemented in the clinical room.
Once the optimal design is completed, the sensor will be integrated with the control and planning algorithm of the robot. A real-time stiffness map will be feedback to the remote operator which will be also able to control and replan the motion of the remote-manipulator.
The stiffness information will be used to create and store a colored-code stiffness map.
The integrated system will be tested with phantoms which mimicking the mechanical properties of the humans' anatomical areas.
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