Flatland Competition 2020: MAPF and MARL for Efficient Train Coordination on a Grid World - Robotics Institute Carnegie Mellon University

Flatland Competition 2020: MAPF and MARL for Efficient Train Coordination on a Grid World

Florian Laurent, Manuel Schneider, Christian Scheller, Jeremy Watson, Jiaoyang Li, Zhe Chen, Yi Zheng, Shao-Hung Chan, Konstantin Makhnev, Oleg Svidchenko, Vladimir Egorov, Dmitry Ivanov, Aleksei Shpilman, Evgenija Spirovska, Oliver Tanevski, Aleksandar Nikov, Ramon Grunder, David Galevski, Jakov Mitrovski, Guillaume Sartoretti, Zhiyao Luo, Mehul Damani, Nilabha Bhattacharya, Shivam Agarwal, Adrian Egli, Erik Nygren, and Sharada Mohanty
Conference Paper, Proceedings of (NeurIPS) Neural Information Processing Systems, Vol. 133, pp. 275 - 301, December, 2020

Abstract

The Flatland competition aimed at finding novel approaches to solve the vehicle re-scheduling problem (VRSP). The VRSP is concerned with scheduling trips in traffic networks and the re-scheduling of vehicles when disruptions occur, for example the breakdown of a vehicle. While solving the VRSP in various settings has been an active area in operations research (OR) for decades, the ever-growing complexity of modern railway networks makes dynamic real-time scheduling of traffic virtually impossible. Recently, multi-agent reinforcement learning (MARL) has successfully tackled challenging tasks where many agents need to be coordinated, such as multiplayer video games. However, the coordination of hundreds of agents in a real-life setting like a railway network remains challenging and the Flatland environment used for the competition models these real-world properties in a simplified manner. Submissions had to bring as many trains (agents) to their target stations in as little time as possible. While the best submissions were in the OR category, participants found many promising MARL approaches. Using both centralized and decentralized learning based approaches, top submissions used graph representations of the environment to construct tree-based observations. Further, different coordination mechanisms were implemented, such as communication and prioritization between agents. This paper presents the competition setup, four outstanding solutions to the competition, and a cross-comparison between them.

Notes
Competition and Demonstration Track

BibTeX

@conference{Laurent-2020-131402,
author = {Florian Laurent and Manuel Schneider and Christian Scheller and Jeremy Watson and Jiaoyang Li and Zhe Chen and Yi Zheng and Shao-Hung Chan and Konstantin Makhnev and Oleg Svidchenko and Vladimir Egorov and Dmitry Ivanov and Aleksei Shpilman and Evgenija Spirovska and Oliver Tanevski and Aleksandar Nikov and Ramon Grunder and David Galevski and Jakov Mitrovski and Guillaume Sartoretti and Zhiyao Luo and Mehul Damani and Nilabha Bhattacharya and Shivam Agarwal and Adrian Egli and Erik Nygren and Sharada Mohanty},
title = {Flatland Competition 2020: MAPF and MARL for Efficient Train Coordination on a Grid World},
booktitle = {Proceedings of (NeurIPS) Neural Information Processing Systems},
year = {2020},
month = {December},
volume = {133},
pages = {275 - 301},
}