Searching with Consistent Prioritization for Multi-Agent Path Finding
About
We study prioritized planning for Multi-Agent Path Finding (MAPF). Existing prioritized MAPF algorithms depend on rule-of-thumb heuristics and random assignment to determine a fixed total priority ordering of all agents a priori. We instead explore the space of all possible partial priority orderings as part of a novel systematic and conflict-driven combinatorial search framework. In a variety of empirical comparisons, we demonstrate state-of-the-art solution qualities and success rates, often with similar runtimes to existing algorithms. We also develop new theoretical results that explore the limitations of prioritized planning, in terms of completeness and optimality, for the first time.
Hang Ma, Daniel Harabor, Peter J. Stuckey, Jiaoyang Li, Sven Koenig• 2018
Related benchmarks
| Task | Dataset | Result | Rank | |
|---|---|---|---|---|
| Multi-robot path planning | Commercial farm topological map 5 robots | Throughput vs Naive Planner51.08 | 6 | |
| Multi-robot path planning | Commercial farm topological map 6 robots | Throughput (%)37.95 | 6 | |
| Multi-robot path planning | Commercial farm topological map 7 robots | Throughput vs Naive Planner37.65 | 6 | |
| Multi-robot path planning | Commercial farm topological map 8 robots | Throughput (%)39.13 | 6 | |
| Multi-robot path planning | Commercial farm topological map 9 robots | Throughput (% of Naive Planner)21 | 6 | |
| Multi-robot path planning | Commercial farm topological map 10 robots | Throughput vs Naive Planner (%)31.63 | 6 |
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