Engineering LaCAM^∗: Towards Real-Time, Large-Scale, and Near-Optimal Multi-Agent Pathfinding

08/08/2023

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This paper addresses the challenges of real-time, large-scale, and near-optimal multi-agent pathfinding (MAPF) through enhancements to the recently proposed LaCAM* algorithm. LaCAM* is a scalable search-based algorithm that guarantees the eventual finding of optimal solutions for cumulative transition costs. While it has demonstrated remarkable planning success rates, surpassing various state-of-the-art MAPF methods, its initial solution quality is far from optimal, and its convergence speed to the optimum is slow. To overcome these limitations, this paper introduces several improvement techniques, partly drawing inspiration from other MAPF methods. We provide empirical evidence that the fusion of these techniques significantly improves the solution quality of LaCAM*, thus further pushing the boundaries of MAPF algorithms.

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Engineering LaCAM^∗: Towards Real-Time, Large-Scale, and Near-Optimal Multi-Agent Pathfinding

Improving LaCAM for Scalable Eventually Optimal Multi-Agent Pathfinding

Multi-Agent Path Finding with Prioritized Communication Learning

Loop-box: Multi-Agent Direct SLAM Triggered by Single Loop Closure for Large-Scale Mapping

Scalable Rail Planning and Replanning with Soft Deadlines

Modeling all alternative solutions for highly renewable energy systems

The Holy Grail of Multi-Robot Planning: Learning to Generate Online-Scalable Solutions from Offline-Optimal Experts

Simple and near-optimal algorithms for hidden stratification and multi-group learning

Engineering LaCAM^∗: Towards Real-Time, Large-Scale, and Near-Optimal Multi-Agent Pathfinding

Related Research

Improving LaCAM for Scalable Eventually Optimal Multi-Agent Pathfinding

Multi-Agent Path Finding with Prioritized Communication Learning

Loop-box: Multi-Agent Direct SLAM Triggered by Single Loop Closure for Large-Scale Mapping

Scalable Rail Planning and Replanning with Soft Deadlines

Modeling all alternative solutions for highly renewable energy systems

The Holy Grail of Multi-Robot Planning: Learning to Generate Online-Scalable Solutions from Offline-Optimal Experts

Simple and near-optimal algorithms for hidden stratification and multi-group learning