Diferencia entre revisiones de «Borja-videos»
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These are some examples of real life experiences on the hose transportation problem. Robot detection and control software is run on a PC. Red dots represent the references (where robots should be) and green dots the posture given by the camera (where they are). Commands are sent to robots using radio transceivers: | These are some examples of real life experiences on the hose transportation problem. Robot detection and control software is run on a PC. Red dots represent the references (where robots "should be") and green dots the posture given by the camera (where "they are"). Commands are sent to robots using radio transceivers: | ||
=A) Non-Linked Robots= | =A) Non-Linked Robots= | ||
| Línea 10: | Línea 10: | ||
*B.2 Max. tangential speed for last robot was limited (50%). References move full-speed. ([[media:2010.5.run5.avi]]) | *B.2 Max. tangential speed for last robot was limited (50%). References move full-speed. ([[media:2010.5.run5.avi]]) | ||
The last robot is forced to move slower than the rest and, because of this, the robots aren't capable of catching the references. Error spreads among the system. | |||
*B.3 Max. tangential speed for last robot was limited (50%). References move at 75% speed.([[media:2010.5.run6.avi]]) | *B.3 Max. tangential speed for last robot was limited (50%). References move at 75% speed.([[media:2010.5.run6.avi]]) | ||
The last robot is forced again to move at half-speed and references move at 75% speed, yet the robots aren't able to follow the path in an acceptable way. | |||
*B.4 Max. tangential speed for last robot was limited (50%). References move at 50% speed.([[media:2010.5.run7.avi]]) | *B.4 Max. tangential speed for last robot was limited (50%). References move at 50% speed.([[media:2010.5.run7.avi]]) | ||
The last robot is running at half-speed and the references move at half-speed too, showing that if all the robots move faster or equally fast as the references, the overall system behavior is better, no matter the maximum speed differences between the robots. Near the end of the path, traction forces between robots are higher than the forces applied by the robots and they are not capable of steering correctly. | |||
*B.5 Last robot is switched off. References move full-speed. ([[media:2010.5.run8.avi]]) | *B.5 Last robot is switched off. References move full-speed. ([[media:2010.5.run8.avi]]) | ||
One interesting application of physically-linked multicomponent robotic systems is the tolerance to fails. In this run, last robot remains switched-off and the robots still follow the path acceptably good. | |||
*B.6 Last robot is switched off. References move at 50% speed. ([[media:2010.5.run9.avi]]) | *B.6 Last robot is switched off. References move at 50% speed. ([[media:2010.5.run9.avi]]) | ||
Revisión del 18:29 11 may 2010
These are some examples of real life experiences on the hose transportation problem. Robot detection and control software is run on a PC. Red dots represent the references (where robots "should be") and green dots the posture given by the camera (where "they are"). Commands are sent to robots using radio transceivers:
A) Non-Linked Robots
- A.1 Tangential speeds for all robots were limited to 0.02 m/s.(media:2010.5.run1.avi)
No physical links are used and robots perform relatively well. Due to communication errors, delays, servo inaccuracies and nature of PI controllers, robots oscillate around the path.
B) Linked Robots
- B.1 Tangential speeds for all robots were limited to 0.02 m/s. (media:2010.5.run3.avi)
Steering behaves worse as the physical link introduces some traction effects on the system. For the same reason, it takes longer for the robots to catch the references.
- B.2 Max. tangential speed for last robot was limited (50%). References move full-speed. (media:2010.5.run5.avi)
The last robot is forced to move slower than the rest and, because of this, the robots aren't capable of catching the references. Error spreads among the system.
- B.3 Max. tangential speed for last robot was limited (50%). References move at 75% speed.(media:2010.5.run6.avi)
The last robot is forced again to move at half-speed and references move at 75% speed, yet the robots aren't able to follow the path in an acceptable way.
- B.4 Max. tangential speed for last robot was limited (50%). References move at 50% speed.(media:2010.5.run7.avi)
The last robot is running at half-speed and the references move at half-speed too, showing that if all the robots move faster or equally fast as the references, the overall system behavior is better, no matter the maximum speed differences between the robots. Near the end of the path, traction forces between robots are higher than the forces applied by the robots and they are not capable of steering correctly.
- B.5 Last robot is switched off. References move full-speed. (media:2010.5.run8.avi)
One interesting application of physically-linked multicomponent robotic systems is the tolerance to fails. In this run, last robot remains switched-off and the robots still follow the path acceptably good.
- B.6 Last robot is switched off. References move at 50% speed. (media:2010.5.run9.avi)
