Information Sharing for Distributed Planning

1. Information Sharing forDistributed Planning Prasanna Velagapudi AAMAS 2010 - Doctoral Symposium

2. Large Heterogeneous Teams • 100s to 1000s of robots, agents, people • Complex, collaborative tasks • Dynamic, uncertain environment • Joint planning intractable AAMAS 2010 - Doctoral Symposium

3. Scaling Team Planning • Independent planners: can’t account for teammates • Existing work: needs specific structure or doesn’t scale to these sizes • DPC, Prioritized Planning • JESP, Factored MDP, ND-POMDP AAMAS 2010 - Doctoral Symposium

4. Iterated Distributed Planning • Factor the problem, enumerate interactions • Compute independent plans & potential interactions • Exchange messages about interactions • Use exchanged information, improve local model AAMAS 2010 - Doctoral Symposium

5. Iterated Distributed Planning • Factor the problem, enumerate interactions • Compute independent plans & potential interactions • Exchange messages about interactions • Use exchanged information, improve local model ? AAMAS 2010 - Doctoral Symposium

6. Iterated Distributed Planning • Factor the problem, enumerate interactions • Compute independent plans & potential interactions • Exchange messages about interactions • Use exchanged information, improve local model ? AAMAS 2010 - Doctoral Symposium

7. Iterated Distributed Planning • Factor the problem, enumerate interactions • Compute independent plans & potential interactions • Exchange messages about interactions • Use exchanged information, improve local model AAMAS 2010 - Doctoral Symposium

8. A Tale of Two Distributed Planners Distributed Prioritized Planning (DPP) L-TREMOR AAMAS 2010 - Doctoral Symposium

9. Distributed Prioritized Planning AAMAS 2010 - Doctoral Symposium

10. Multiagent Path Planning Start Goal AAMAS 2010 - Doctoral Symposium

11. Multiagent Path Planning AAMAS 2010 - Doctoral Symposium

12. Prioritized Planning • Assign priorities to agents based on path length [van den Berg, et al 2005] AAMAS 2010 - Doctoral Symposium

13. Prioritized Planning • Plan from highest priority to lowest priority • Use previous agents as dynamic obstacles [van den Berg, et al 2005] AAMAS 2010 - Doctoral Symposium

14. Distributed Prioritized Planning Parallelizable & Equivalent AAMAS 2010 - Doctoral Symposium

15. Large-Scale Path Solutions AAMAS 2010 - Doctoral Symposium

16. Large-Scale Path Solutions AAMAS 2010 - Doctoral Symposium

17. DPP Results Fewer Sequential Plans AAMAS 2010 - Doctoral Symposium

18. DPP Results Fewer Sequential Plans Longer Planning Time AAMAS 2010 - Doctoral Symposium

19. Why does this happen? • Prioritized Planning • DPP Longest planning agents might replan multiple times A A B B C C Individual agent planning times varied by >2 orders of magnitude D D Solution 1: Prioritize by plan time? Solution 2: Incremental Planning AAMAS 2010 - Doctoral Symposium

20. Summary of DPP • Observable, certain world • Only one type of interaction: collision • Far fewer sequential planning iterations • Incremental planning may reduce execution time AAMAS 2010 - Doctoral Symposium

21. L-TREMOR AAMAS 2010 - Doctoral Symposium

22. A Simple Rescue Domain Unsafe Cell Rescue Agent Clearable Debris Narrow Corridor Victim Cleaner Agent AAMAS 2010 - Doctoral Symposium

23. A Simple (Large) Rescue Domain AAMAS 2010 - Doctoral Symposium

24. Distributed POMDP with Coordination Locales (DPCL) • Often, interactions between agents are sparse Only fits one agent Passable if cleaned [Varakantham, et al 2009] AAMAS 2010 - Doctoral Symposium

25. Distributed POMDP with Coordination Locales (DPCL) • Define coordination locales (CLs) where POMDP model functions are not independent: <S, A, Ω, P, R, O> (states) (actions) (obs.) (transition)(reward)(obs. fn) [Varakantham, et al 2009] AAMAS 2010 - Doctoral Symposium

26. Distributed POMDP with Coordination Locales (DPCL) • Define coordination locales (CLs) where POMDP model functions are not independent: Outside CL: (typical) Sglobal R1, P1, O1 R2, P2, O2 S1, A1 S2, A2 [Varakantham, et al 2009] AAMAS 2010 - Doctoral Symposium

27. Distributed POMDP with Coordination Locales (DPCL) • Define coordination locales (CLs) where POMDP model functions are not independent: Inside CL: (interaction) Sglobal R12, P12, O12 S1, A1 S2, A2 [Varakantham, et al 2009] AAMAS 2010 - Doctoral Symposium

28. TREMOR [Varakantham, et al 2009] AAMAS 2010 - Doctoral Symposium

29. L-TREMOR Distributed & Parallelizable AAMAS 2010 - Doctoral Symposium

30. Preliminary Results – Joint Utility N = 100 (structurally similar to N=10) N = 6 N = 10 AAMAS 2010 - Doctoral Symposium

31. Preliminary Results – Timing AAMAS 2010 - Doctoral Symposium

32. Preliminary Results – Model Accuracy R = 0.804 AAMAS 2010 - Doctoral Symposium

33. Current Issues • Oscillations in solutions • Discovery of relevant locales ? AAMAS 2010 - Doctoral Symposium

34. Summary of L-TREMOR • Partially-observable, uncertain world • Multiple types of interactions • Role-allocation of tasks • Improvement over independent planning • Handles large problems • Next steps: improving convergence AAMAS 2010 - Doctoral Symposium

35. Conclusions • Two approaches to distributed planning • DPP: approaching centralized performance • L-TREMOR: exceeding joint tractability • Analogous strategies for distributing planning • Both iterate independent planners • Both exchange messages about states, actions AAMAS 2010 - Doctoral Symposium

36. Future Work • Generalized framework for distributed planning through iterative message exchange • Reduce necessary communication • Better search over task allocations • Scaling to larger team sizes AAMAS 2010 - Doctoral Symposium