Multimedia  

 

Volume 22 Issue 10/11- Publication Date: 1 October 2003
 
Integrated Vision/Force Robotic Servoing in the Task Fram Formalism
 
J. Baeten Katholieke Hogeschool Limburg, Department of Industrial Sciences and Technology, University Campus Gebouw B, bus 3, B-3590 Diepenbeek, Belgium, H. Bruyninckx and J. De Schutter Katholieke University Leuven, Department of Mechanical Engineering, Celestijnenlaan 300B, B-2001 Heverlee, Belgium
 

In this paper we show how to use the task frame to easily model, implement and execute three-dimensional (3D) robotic tasks, which integrate force control and visual servoing, in an uncalibrated workspace.

In contrast to most hybrid vision/force research, this work uses eye-in-hand vision and force control. Mounting both sensors on the same end-effector gives rise to new constraints, control issues and advantages, which are discussed in this paper.

On the one hand, in this paper we emphasize shared control in which both vision and force simultaneously control a given task frame direction. Our work shows the usefulness and feasibility of a range of tasks which use shared control. Moreover, it offers a framework based on the task frame formalism (TFF) to distinguish between different basic forms of shared control. Each basic form is illustrated by a robotic task with shared control in only one direction. In addition, an extension to classify multi-dimensional shared control tasks is presented.

On the other hand, a new classification is presented which distinguishes between four meaningful tool/camera configurations, being parallel or non-parallel endpoint closed-loop and fixed or variable endpoint open-loop. Corresponding control strategies are discussed, resulting in either collocated or non-collocated vision/force control. Several task examples (in 3D space), specified in the TFF, illustrate the use of these four configurations.

As shown by the presented experimental results, the tasks at hand benefit from the integrated control approach.

 
Multimedia Key
= Video = Data = Code = Image
 
Extension
Type
Description
1
Example One: Global view of contour following. (3.9MB)
2
Example Two: Processed image in contour following. (0.8MB)
3
Example Three: Approach with shared control. (1.7MB)
 
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