Shao-Hung Chan scite author profile

Multi-Agent Path Finding (MAPF) is the combinatorial problem of finding collision-free paths for multiple agents on a graph. This paper describes MAPF-based software for solving train planning and replanning problems on large-scale rail networks under uncertainty. The software recently won the 2020 Flatland Challenge, a NeurIPS competition trying to determine how to efficiently manage dense traffic on rail networks. The software incorporates many state-of-the-art MAPF or, in general, optimization technologies, such as prioritized planning, large neighborhood search, safe interval path planning, minimum communication policies, parallel computing, and simulated annealing. It can plan collision-free paths for thousands of trains within a few minutes and deliver deadlock-free actions in real-time during execution.

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Distributed Deep Reinforcement Learning based Indoor Visual Navigation

Hsu

Chan

et al. 2018

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Multi-Layer Environmental Affordance Map for Robust Indoor Localization, Event Detection and Social Friendly Navigation

Chan

et al. 2019

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Shao-Hung Chan

Robust 2D Indoor Localization Through Laser SLAM and Visual SLAM Fusion

Scalable Rail Planning and Replanning: Winning the 2020 Flatland Challenge

Distributed Deep Reinforcement Learning based Indoor Visual Navigation

Multi-Layer Environmental Affordance Map for Robust Indoor Localization, Event Detection and Social Friendly Navigation

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