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Designing visually servoed tracking to augment camera teleoperators
Please use this identifier to cite or link to this item:
http://hdl.handle.net/1860/379
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| Title: | Designing visually servoed tracking to augment camera teleoperators |
| Authors: | Stanciu, Ion Rares |
| Keywords: | Engineering
Robots
Servomechanisms |
| Issue Date: | 6-Jan-2005 |
| Abstract: | Robots have now far more impact in humans life then ten years ago. Vacuum cleaning robots are already well known. Making today’s robots to work unassisted requires appropriate visual servoing architecture. In the past, a lot of efforts were directed towards designing controllers that relies exclusively on image data. Still most robots are servoed kinematically using joint data. Visual servoing architecture has applications not only in robotics. Video cameras are often mounted on platforms that can move like rovers, booms, gantries and aircrafts. People can operate such platforms to capture desired views of a scene or a target. To avoid collisions, with the environment and occlusions, such platforms demands much skill. Visual-servoing some degrees-of-freedom may reduce the operator burden and improve tracking. We call this concept human-in-the-loop visual servoing. Human-in-the-loop systems involve an operator who manipulates a device for desired tasks based on feedback from the device and environment. For example, devices like rovers gantries and aircrafts possess a video camera. The task is to control maneuver the vehicle and position the camera to obtain desired fields of view. To overcome joint limits, avoid collisions and ensure occlusion-free views, these devices are typically equipped with redundant degrees-of-freedom. Tracking moving subjects with such systems is a challenging task and requires a well skilled operator. In this approach, we use computer vision techniques to visually servo the camera. The net effect is that the operator just focuses on safely manipulating the boom and dolly while computer-control automatically servos the camera. |
| URI: | http://hdl.handle.net/1860/379 |
| Appears in Collections: | Drexel Theses and Dissertations
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