A Decentralized Reinforcement Learning Framework for Efficient Passage
of Emergency Vehicles
- URL: http://arxiv.org/abs/2111.00278v1
- Date: Sat, 30 Oct 2021 16:13:48 GMT
- Title: A Decentralized Reinforcement Learning Framework for Efficient Passage
of Emergency Vehicles
- Authors: Haoran Su, Yaofeng Desmond Zhong, Dey Biswadip, Amit Chakraborty
- Abstract summary: Emergency vehicles (EMVs) play a critical role in a city's response to time-critical events.
The existing approaches to reduce EMV travel time employ route optimization and traffic signal pre-emption.
We introduce EMVLight, a framework for simultaneous dynamic routing and traffic signal control.
- Score: 6.748225062396441
- License: http://creativecommons.org/licenses/by/4.0/
- Abstract: Emergency vehicles (EMVs) play a critical role in a city's response to
time-critical events such as medical emergencies and fire outbreaks. The
existing approaches to reduce EMV travel time employ route optimization and
traffic signal pre-emption without accounting for the coupling between route
these two subproblems. As a result, the planned route often becomes suboptimal.
In addition, these approaches also do not focus on minimizing disruption to the
overall traffic flow. To address these issues, we introduce EMVLight in this
paper. This is a decentralized reinforcement learning (RL) framework for
simultaneous dynamic routing and traffic signal control. EMVLight extends
Dijkstra's algorithm to efficiently update the optimal route for an EMV in
real-time as it travels through the traffic network. Consequently, the
decentralized RL agents learn network-level cooperative traffic signal phase
strategies that reduce EMV travel time and the average travel time of non-EMVs
in the network. We have carried out comprehensive experiments with synthetic
and real-world maps to demonstrate this benefit. Our results show that EMVLight
outperforms benchmark transportation engineering techniques as well as existing
RL-based traffic signal control methods.
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