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Robotics

Robotics. R&N: ch 25. based on material from Jean-Claude Latombe, Daphne Koller, Stuart Russell. sensors. environment. ?. agent. effectors. Agent. Robots  Physical sensors and effectors. Sensors. Sensors that tell the robot position/change of joints: odometers, speedometers, etc.

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Robotics

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  1. Robotics R&N: ch 25 based on material from Jean-Claude Latombe, Daphne Koller, Stuart Russell

  2. sensors environment ? agent effectors Agent Robots  Physical sensors and effectors

  3. Sensors • Sensors that tell the robot position/change of joints: odometers, speedometers, etc. • Force sensing. Enables compliant motion--robot just maintains contact with object (video: compliant) • Sonar. Send out sound waves and measure how long it takes for it to be reflected back. Good for obstacle avoidance. • Vision systems

  4. Effectors • Converts software commands into physical motion • Typically electrical motors or hydraulic/pneumatic cylinders • Two main types of effectors: • locomotion • manipulation

  5. Locomotion • Legs! • traditional (video: honda human) • Other types • Statically stable locomotion: can pause at any stage during its gate without falling • Dynamically stable locomotion: stable only as long as it keeps moving (video: hopper) • Still, wheeled or tread locomotion like Shakey is still most practical for typical environments • Other methods: reconfigurable robots, fish robots, snake-like robots. (video: mod-robot)

  6. Manipulation • Manipulation of objects • Typical manipulators allow for: • Prismatic motion (linear movement) • Rotary motion (around a fixed hub) • Robot hands go from complex anthromorphic models to simpler ones that are just graspers • (video: manipulation) • (video: heart surgery)

  7. Problems in Robotics • Localization and Mapping • Motion planning

  8. Localization: Where Am I? • Use probabilistic inference: compute current location and orientation (pose) given observations At-1 At-1 At-1 Xt-1 Xt-1 Xt-1 Zt-1 Zt-1 Zt-1

  9. Motion Planning • Simplest task that a robot needs to accomplish • Two aspects: • Finding a path robot should follow • Adjusting motors to follow that path • Goal: move robot from one configuration to another

  10. Configuration space • Describe robot’s configuration using a set of real numbers • Flatland -- robot in 2D -- how to describe? • Degrees of freedom: a robot has k degrees of freedom if it can be described fully by a set of k real numbers • e.g. robot arm (slide) • Want minimum-dimension parameterization • Set of all possible configurations of the robot in the k-dimensional space is called the configuration space of the robot.

  11. Example • workspace for 2-D robot that can only translate, not rotate • configuration space describes legal configurations • free-space • obstacles • Configuration space depends on how big robot is—need reference point

  12. Path planning • Goal: move the robot from an initial configuration to a goal position • path must be contained entirely in free space • assumptions: • robot can follow any path (as long as avoids obstacles) • dynamics are completely reliable • obstacles known in advance • obstacles don’t move

  13. Assumption #1 • robot can follow any path • what about a car? • degrees of freedom vs. controllable degrees of freedom • holonomic (same) • nonholonomic • (video: holonomic)

  14. Motion planning • reduces to problem of finding a path from an initial state to a goal in robot’s configuration space • why is this hard?

  15. Reformulate as discrete search • finely discretized grid • cell decomposition: decompose the space into large cells where each cell is simple, motion planning in each cell is trivial • roadmap (skeletonization) methods: come up with a set of major “landmarks” in the space and a set of roads between them

  16. Issues in Search • Complete • Optimality • Computational Complexity

  17. Motion planning algorithms • grid • cell decomposition • exact • approximate • roadmap (skeletonization) methods: • visibility graphs • randomized path planning

  18. Robotics: Summary • We’ve just seen a brief introduction… • Issues: • sensors, effectors • Locomotion, manipulation • Some problems: • Localization • Motion Planning • Lots more!!

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