DocumentCode
173800
Title
Improvements in teleoperation of industrial robots without low-level access
Author
Dalvand, Mohsen Moradi ; Nahavandi, S.
Author_Institution
Centre for Intell. Syst. Res. (CISR), Deakin Univ., Waurn Ponds, VIC, Australia
fYear
2014
fDate
5-8 Oct. 2014
Firstpage
2170
Lastpage
2175
Abstract
This paper proposes a method to improve motion smoothness and decrease latency using existing ABB IRC5 robot controllers without access to any low level interface. The proposed control algorithm includes a high-level PID controller used to dynamically generate reference velocities for different travel ranges of the tool centre point (TCP) of the robot. Communication with the ABB IRC5 controller was performed utilising the ABB PC software development kit (SDK). The multitasking feature of the IRC5 controller was used in order to enhance the communication frequency between the controller and the remote application. Trajectory tracking experiments of a predefined 3D trajectory were carried out and the benefits of the proposed algorithm was demonstrated. The robot was intentionally installed on a wobbly table and its vibrations were recorded using a six degrees of freedom (DOF) force/torque sensor fitted to the tool mounting interface of the robot. The robot vibrations were used as a measure of the smoothness of the tracking movements. Experimental results demonstrating the robot tool centre point (TCP), tracking errors, and robot vibrations for different control approaches were provided and analysed. It was demonstrated that the proposed approach results in the smoothest motion with less than 0.2 mm tracking errors.
Keywords
industrial robots; motion control; robot dynamics; telerobotics; three-term control; vibrations; 3D trajectory; ABB IRC5 robot controllers; ABB PC software development kit; PID controller; SDK; dynamic reference velocities generation; force-torque sensor; industrial robots teleoperation; latency reduction; low-level access; motion smoothness improvement; multitasking feature; robot TCP; robot tool centre point; robot vibrations; tool mounting interface; trajectory tracking; Force; Robot sensing systems; Service robots; Tracking; Trajectory; Vibrations;
fLanguage
English
Publisher
ieee
Conference_Titel
Systems, Man and Cybernetics (SMC), 2014 IEEE International Conference on
Conference_Location
San Diego, CA
Type
conf
DOI
10.1109/SMC.2014.6974245
Filename
6974245
Link To Document