The Reactive Paradigm

1. The Reactive Paradigm • Describe the Reactive Paradigm in terms of the 3 robot primitives and its organization of sensing • List the characteristics of a reactive robotic system, and discuss the connotations of surrounding the reactive paradigm • Describe the two dominant methods for combining behaviors in a reactive architecture: subsumption and potential field summation • Be able to program a behavior using pfields • Be able to construct a new potential field from primitive pfields and sum pfields to generate an emergent behavior Review Organization -SA -beh. specific Subsumption -Philosophy -Level 0 -Level 1 -Level 2 Summary Chapter 4: The Reactive Paradigm

2. Review: Lessons from Biology • Programs should decompose complex actions into behaviors. Complexity emerges from concurrent behaviors acting independently • Agents should rely on straightforward activation mechanisms such as IRM • Perception filters sensing and considers only what is relevant to the task (action-oriented perception) • Behaviors are independent but the output may be used in many ways including: combined with others to produce a resultant output or to inhibit others Review Organization -SA -beh. specific Subsumption -Philosophy -Level 0 -Level 1 -Level 2 Summary Chapter 4: The Reactive Paradigm

3. Hierarchical Organization is“Horizontal” Review Organization -SA -beh. specific Subsumption -Philosophy -Level 0 -Level 1 -Level 2 Summary Chapter 4: The Reactive Paradigm

4. More Biological is “Vertical” Review Organization -SA -beh. specific Subsumption -Philosophy -Level 0 -Level 1 -Level 2 Summary Chapter 4: The Reactive Paradigm

5. Behaviors can “share” perception without knowing it This is behavioral sensor fusion Sensing is Behavior-Specific or Local Review Organization -SA -beh. specific Subsumption -Philosophy -Level 0 -Level 1 -Level 2 Summary Chapter 4: The Reactive Paradigm

6. Reactive Robots • Most apps are programmed with this paradigm • Biologically based: • Behaviors (independent processes), released by perceptual or internal events (state) • No world models or long term memory • Highly modular, generic • Overall behavior emerges RELEASER behavior SENSE ACT Overview History Reactive USAR Summary Chapter 4: The Reactive Paradigm

7. www.friendlymachines.com Example 1: Robomow • Behaviors? • Random • Avoid • Avoid(bump=obstacle) • Avoid(wire=boundary) • Stop • Stop(tilt=ON) • All active Overview History Reactive USAR Summary Chapter 4: The Reactive Paradigm

8. www.irobot.com Example 2: My Real Baby • Behaviors? • Touch-> Awake • Upside down & Awake-> Cry • Awake & Hungry -> Cry • Awake & Lonely -> Cry • Note can get crying from multiple behaviors • Note internal state (countdown timer on Lonely) Overview History Reactive USAR Summary Chapter 4: The Reactive Paradigm

9. Reactive • Historically, there are two main styles of creating a reactive system • Subsumption architecture • Layers of behavioral competence • How to control relationships • Potential fields • Concurrent behaviors • How to navigate • They are equivalent in power • In practice, see a mixture of both layers and concurrency Chapter 4: The Reactive Paradigm

10. Subsumption:Rodney Brooks Review Organization -SA -beh. specific Subsumption -Philosophy -Level 0 -Level 1 -Level 2 Summary From http://www.spe.sony.com/classics/fastcheap/index.html Chapter 4: The Reactive Paradigm

11. Subsumption Philosophy • Modules should be grouped into layers of competence • Modules in a higher lever can override or subsume behaviors in the next lower level • Suppression: substitute input going to a module • Inhibit: turn off output from a module • No internal state in the sense of a local, persistent representation similar to a world model. • Architecture should be taskable: accomplished by a higher level turning on/off lower layers Review Organization -SA -beh. specific Subsumption -Philosophy -Level 0 -Level 1 -Level 2 Summary Chapter 4: The Reactive Paradigm

12. follow-corridor 2 wander 1 runaway 0 RUN AWAY PS MS PS MS HALT COLLIDE Level 0: Runaway Review Organization -SA -beh. specific Subsumption -Philosophy -Level 0 -Level 1 -Level 2 Summary Chapter 4: The Reactive Paradigm

13. Example Perception: Polar Plot • Plot is ego-centric • Plot is distributed (available to whatever wants to use it) • Although it is a representation in the sense of being a data structure, there is no memory (contains latest information) and no reasoning (2-3 means a “wall”) Review Organization -SA -beh. specific Subsumption -Philosophy -Level 0 -Level 1 -Level 2 Summary if sensing is ego-centric, can often eliminate need for memory, representation Chapter 4: The Reactive Paradigm

14. follow-corridor 2 wander 1 runaway 0 WANDER AVOID PS MS MS encoders What would Inhibition do? PS Note sharing of Perception, fusion Level 1: Wander Review Organization -SA -beh. specific Subsumption -Philosophy -Level 0 -Level 1 -Level 2 Summary Chapter 4: The Reactive Paradigm

15. move2light 2 wander 1 runaway 0 LIGHT PHOTO- TROPHISM S Class Exercise Review Organization -SA -beh. specific Subsumption -Philosophy -Level 0 -Level 1 -Level 2 Summary Chapter 4: The Reactive Paradigm

16. follow-corridor 2 wander 1 runaway 0 STAY-IN-MIDDLE PS MS Level 2: Follow-Corridors Review Organization -SA -beh. specific Subsumption -Philosophy -Level 0 -Level 1 -Level 2 Summary Chapter 4: The Reactive Paradigm

17. Class Exercise • Design the roomba with subsumption Chapter 4: The Reactive Paradigm

18. Subsumption Review • What is the Reactive Paradigm in terms of primitives? • What is the Reactive Paradigm in terms of sensing? • Does the Reactive Paradigm solve the Open World problem? • How does the Reactive Paradigm eliminate the frame problem? • What is the difference between a behavior and a level of competence? • What is the difference between suppression and inhibition in subsumption? Review Organization -SA -beh. specific Subsumption -Philosophy -Level 0 -Level 1 -Level 2 Summary Chapter 4: The Reactive Paradigm

19. Potential Fields:Ron Arkin From http://www.cc.gatech.edu/aimosaic/faculty/arkin From http://www.cc.gatech.edu/aimosaic/robot-lab/MRLhome.html Chapter 4: The Reactive Paradigm

20. Potential Fields Philosophy • The motor schema component of a behavior can be expressed with a potential fields methodology • A potential field can be a “primitive” or constructed from primitives which are summed together • The output of behaviors are combined using vector summation • From each behavior, the robot “feels” a vector or force • Magnitude = force, strength of stimulus, or velocity • Direction • But we visualize the “force” as a field, where every point in space represents the vector that it would feel if it were at that point Chapter 4: The Reactive Paradigm

21. Example: Run Away via Repulsion Chapter 4: The Reactive Paradigm

22. 5 Primitive Potential Fields Chapter 4: The Reactive Paradigm

23. Draw These Now!Common fields in behaviors • Uniform • Move in a particular direction, corridor following • Repulsion • Runaway (obstacle avoidance) • Attraction • Move to goal • Perpendicular • Corridor following • Tangential • Move through door, docking (in combination with other fields) • random • do you think this is a potential field? what would it look like? Chapter 4: The Reactive Paradigm

24. Attractive Repulsive Class Exercise • Name the field you’d use for • Moving towards a light • Avoiding obstacles Chapter 4: The Reactive Paradigm

25. goal goal obstacle obstacle Combining Fields forEmergent Behavior obstacle If robot were dropped anywhere on this grid, it would want to move to goal and avoid obstacle: Behavior 1: MOVE2GOAL Behavior 2: RUNAWAY The output of each independent behavior is a vector, the 2 vectors is summed to produce emergent behavior Chapter 4: The Reactive Paradigm

26. Note: in this example, robot can sense the goal from 10 meters away Note: In this example, repulsive field only extends for 2 meters; the robot runs away only if obstacle within 2 meters Fields and Their Combination Chapter 4: The Reactive Paradigm

27. Path Taken Robot only feels vectors for this point when it (if) reaches that point • If robot started at this location, it would take the following path • It would only “feel”the vector for the location, then move accordingly, “feel” the next vector, move, etc. • Pfield visualization allows us to see the vectors at all points, but robot never computes the “field of vectors” just the local vector Chapter 4: The Reactive Paradigm

28. Discussion • Could you represent the Arctic Tern feeding behavior with potential fields? • what happens with multiple red dots? • can you inhibit with potential fields? Chapter 4: The Reactive Paradigm

29. Example: follow-corridor or follow-sidewalk Perpendicular Uniform Note use of Magnitude profiles: Perpendicular decreases Combined Chapter 4: The Reactive Paradigm

30. Just half of a follow-corridor, but… Class Exercise:Draw Fields for Wall-Following(assume that robot stands still if no wall) Chapter 4: The Reactive Paradigm

31. But how does the robot see a wall without reasoning or intermediate representations? • Perceptual schema “connects the dots”, returns relative orientation MS: Perp. orientation PS: Find-wall S MS: Uniform Sonars Chapter 4: The Reactive Paradigm

32. OK, But why isn’t that a representation of a wall? • It’s not really reasoning that it’s a wall, rather it is reacting to the stimulus which happens to be smoothed (common in neighboring neurons) Chapter 4: The Reactive Paradigm

33. Note: multiple instances of a behavior vs. 1: Could just have 1 Instance of RUN AWAY, Which picks nearest reading; Doesn’t matter, but this Allows addition of another Sonar without changing the RUN AWAY behavior Level 0: Runaway Chapter 4: The Reactive Paradigm

34. Level 1: Wander Wander is Uniform, but Changes direction aperiodically Chapter 4: The Reactive Paradigm

35. Level 2: Follow Corridor Follow-corridor Should we Leave Run Away In? Do we Need it? Chapter 4: The Reactive Paradigm

36. Pfields • Advantages • Easy to visualize • Easy to build up software libraries • Fields can be parameterized • Combination mechanism is fixed, tweaked with gains • Disadvantages • Local minima problem (sum to magnitude=0) • Box canyon problem • Jerky motion Chapter 4: The Reactive Paradigm

37. Orientation, ratio of pixel countstangent vector Total countattraction vector • Arkin and Murphy, 1990, Questa, Grossmann, Sandini, 1995, Tse and Luo, 1998, Vandorpe, Xu, Van Brussel, 1995. Roth, Schilling, 1998, Santos-Victor, Sandini, 1997 Example: Docking Behavior Chapter 4: The Reactive Paradigm

38. Docking Behavior Video Chapter 4: The Reactive Paradigm

39. Class Discussion:When Does a Field End? • Imagine the case of a “SodaPup” robot (MIT) • task: find and pick up a Coca-Cola can • environment: red cans are only red object in world • behavior: ?? Chapter 4: The Reactive Paradigm

40. Pfields Summary • Reactive Paradigm: SA, sensing is local • Solves the Open World problem by emulating biology • Eliminates the frame problem by not using any global or persistent representation • Perception is direct, ego-centric, and distributed • Two architectural styles are: subsumption and pfields • Behaviors in pfield methodologies are a tight coupling of sensing to acting; modules are mapped to schemas conceptually • Potential fields and subsumption are logically equivalent but different implementations • Pfield problems include • local minima (ways around this) • jerky motion • bit of an art Chapter 4: The Reactive Paradigm