Download presentation
Presentation is loading. Please wait.
1
Finding Optimal Solutions to Cooperative Pathfinding Problems Trevor Standley and Rich Korf Computer Science Department University of California, Los Angeles
2
Introduction Pathfinding Problems A single agent must find a path from a start state to a goal state Cooperative Pathfinding Problems Multiple agents interact Want to minimize the total cost
3
Motivation
5
My Formulation Gridworld pathfinding
6
Related Work Centralized Approaches Strengths: Typically complete, can be optimal Weaknesses: Takes forever! Decoupled Approaches Strengths: Fast Weaknesses: Incomplete and suboptimal
7
Related Work Centralized Approaches Strengths: Typically complete, can be optimal Weaknesses: Takes forever! Decoupled Approaches Strengths: Fast Weaknesses: Incomplete and suboptimal
8
Related Work Centralized Approaches Strengths: Typically complete, can be optimal Weaknesses: Takes forever! Decoupled Approaches Strengths: Fast Weaknesses: Incomplete and suboptimal
9
Related Work Centralized Approaches Strengths: Typically complete, can be optimal Weaknesses: Takes forever! Decoupled Approaches Strengths: Fast Weaknesses: Incomplete and suboptimal
10
Related Work Centralized Approaches Strengths: Typically complete, can be optimal Weaknesses: Takes forever! Decoupled Approaches Strengths: Fast Weaknesses: Incomplete and suboptimal
11
Related Work Centralized Approaches Strengths: Typically complete, can be optimal Weaknesses: Takes forever! Decoupled Approaches Strengths: Fast Weaknesses: Incomplete and suboptimal
12
Related Work Centralized Approaches Strengths: Typically complete, can be optimal Weaknesses: Takes forever! Decoupled Approaches Strengths: Fast Weaknesses: Incomplete and suboptimal
13
Related Work Centralized Approaches Strengths: Typically complete, can be optimal Weaknesses: Takes forever! Decoupled Approaches Strengths: Fast Weaknesses: Incomplete and suboptimal
14
Related Work Centralized Approaches Strengths: Typically complete, can be optimal Weaknesses: Takes forever! Decoupled Approaches Strengths: Fast Weaknesses: Incomplete and suboptimal
15
Related Work Centralized Approaches Strengths: Typically complete, can be optimal Weaknesses: Takes forever! Decoupled Approaches Strengths: Fast Weaknesses: Incomplete and suboptimal
16
Related Work Centralized Approaches Strengths: Typically complete, can be optimal Weaknesses: Takes forever! Decoupled Approaches Strengths: Fast Weaknesses: Incomplete and suboptimal
17
Related Work Centralized Approaches Strengths: Typically complete, can be optimal Weaknesses: Takes forever! Decoupled Approaches Strengths: Fast Weaknesses: Incomplete and suboptimal
18
Related Work Centralized Approaches Strengths: Typically complete, can be optimal Weaknesses: Takes forever! Decoupled Approaches Strengths: Fast Weaknesses: Incomplete and suboptimal
19
Related Work Centralized Approaches Strengths: Typically complete, can be optimal Weaknesses: Takes forever! Decoupled Approaches Strengths: Fast Weaknesses: Incomplete and suboptimal
20
Related Work Centralized Approaches Strengths: Typically complete, can be optimal Weaknesses: Takes forever! Decoupled Approaches Strengths: Fast Weaknesses: Incomplete and suboptimal
21
Related Work Centralized Approaches Strengths: Typically complete, can be optimal Weaknesses: Takes forever! Decoupled Approaches Strengths: Fast Weaknesses: Incomplete and suboptimal
22
Our Prior Work (Standley AAAI-10) Independence Detection Empowers centralized algorithms. Combines the strength of centralized and decentralized approaches. Maintains optimality and completeness.
23
Simple Independence Detection From (Standley AAAI-10)
24
Simple Independence Detection 1.Put each agent into its own group. 2.Plan paths for each group independently 3.Check for conflicts in new paths 4.Combine groups with conflicting paths 5.Repeat 2-4 until no conflicts From (Standley AAAI-10)
25
Simple Independence Detection From (Standley AAAI-10)
26
Simple Independence Detection Problem Are these agents independent? From (Standley AAAI-10)
27
Simple Independence Detection Problem Are these agents independent? From (Standley AAAI-10)
28
Better Independence Detection When a conflict is detected between two groups, try to find an alternative path for one of the groups If that fails try to find an alternate path for the other group Only as a last resort do we combine the groups From (Standley AAAI-10)
29
Best Independence Detection How can we make agent 2 take this path initially? From (Standley AAAI-10)
30
Best Independence Detection Try to avoid future conflicts avoid the current paths of other agents. From (Standley AAAI-10)
31
Reservation Tables Illegal move table Contains all the ways alternative paths could result in a conflict with the currently conflicting group. Consider such moves illegal. Conflict avoidance table Contains all the ways alternative paths could result in a conflict with any other group Keep track of conflict avoidance table violations and
32
Reservation Tables Illegal move table. From (Standley AAAI-10)
33
Reservation Tables Illegal move table. From (Standley AAAI-10)
34
Reservation Tables Illegal move table. From (Standley AAAI-10)
35
Reservation Tables Illegal move table Contains all the ways alternative paths could result in a conflict with the currently conflicting group. Consider such moves illegal. Conflict avoidance table Contains all the ways alternative paths could result in a conflict with any other group Keep track of conflict avoidance table violations
36
Reservation Tables Conflict avoidance table. From (Standley AAAI-10)
37
Reservation Tables Conflict avoidance table. From (Standley AAAI-10)
38
Reservation Tables Conflict avoidance table. From (Standley AAAI-10)
39
Complete Approximation Algorithms Our previous work maintained optimality by: Only accepting alternate paths if they have the same cost as original paths. Coupling independence detection with an optimal centralized algorithm. We recognize in our current work that we can drop these two constraints.
40
Complete Approximation Algorithms Modifications to the centralized algorithm Expand nodes with fewest violations first Use cost to break ties
41
When to drop these constraints Always Leads to a fast and complete algorithm When doing so avoids the creation of groups containing more than x agents Leads to a slower but still fast algorithm Produces higher quality paths
42
Parameterized Approximation Maximum group size parameter x Drop constraints to avoid creating groups larger than x. x =1 : always drop the constraints. x = ∞ : never drop the constraints (optimal) The algorithm is complete for any choice of x
43
Simple Optimal Anytime Algorithm Run the parameterized approximation with x = 1. Then run the parameterized approximation with x = 2. … When we run out of time, we return the best solution found by any run.
44
Simple Optimal Anytime Algorithm Problem The simple anytime algorithm suffers the cost of unused and incomplete iterations.
45
Optimal Anytime Algorithm Problem Keep paths and groupings from previous iterations when possible. Keep track of groups that might not have optimal paths. Fix these paths one at a time starting with the easiest.
46
Optimal Anytime Algorithm Keep a lower bound for each group. When merging a group, add lower bounds
47
Optimal Anytime Algorithm Update best path many times within an iteration. Whenever the solution is conflict free we update the best solution found. When lower bound equals cost, we’re done
48
Results Our coarsest approximation is complete, has competitive running time, and produces superior solutions. As an optimal algorithm, our anytime algorithm is competitive with our previous state-of-the-art. If our anytime algorithm is terminated early, it often returns an optimal path.
Similar presentations
