English

Graph Meta-Reinforcement Learning for Transferable Autonomous Mobility-on-Demand

Systems and Control 2022-02-16 v1 Systems and Control

Abstract

Autonomous Mobility-on-Demand (AMoD) systems represent an attractive alternative to existing transportation paradigms, currently challenged by urbanization and increasing travel needs. By centrally controlling a fleet of self-driving vehicles, these systems provide mobility service to customers and are currently starting to be deployed in a number of cities around the world. Current learning-based approaches for controlling AMoD systems are limited to the single-city scenario, whereby the service operator is allowed to take an unlimited amount of operational decisions within the same transportation system. However, real-world system operators can hardly afford to fully re-train AMoD controllers for every city they operate in, as this could result in a high number of poor-quality decisions during training, making the single-city strategy a potentially impractical solution. To address these limitations, we propose to formalize the multi-city AMoD problem through the lens of meta-reinforcement learning (meta-RL) and devise an actor-critic algorithm based on recurrent graph neural networks. In our approach, AMoD controllers are explicitly trained such that a small amount of experience within a new city will produce good system performance. Empirically, we show how control policies learned through meta-RL are able to achieve near-optimal performance on unseen cities by learning rapidly adaptable policies, thus making them more robust not only to novel environments, but also to distribution shifts common in real-world operations, such as special events, unexpected congestion, and dynamic pricing schemes.

Keywords

Cite

@article{arxiv.2202.07147,
  title  = {Graph Meta-Reinforcement Learning for Transferable Autonomous Mobility-on-Demand},
  author = {Daniele Gammelli and Kaidi Yang and James Harrison and Filipe Rodrigues and Francisco C. Pereira and Marco Pavone},
  journal= {arXiv preprint arXiv:2202.07147},
  year   = {2022}
}

Comments

11 pages, 4 figures

R2 v1 2026-06-24T09:36:49.124Z