In the not-so-distant future, city streets could be flooded with autonomous vehicles. Self-driving cars can move faster and travel closer together, allowing more of them to fit on the road – potentially leading to congestion and gridlock on city streets.
A new study by Cornell researchers developed a first-of-its-kind model to control traffic and intersections in order to increase car capacity on urban streets, reduce congestion and minimize accidents.
“For the future of mobility, so much attention has been paid to autonomous cars,” said Oliver Gao, professor of civil and environmental engineering and senior author of the study published in Transportation Research Part B.
“If you have all these autonomous cars on the road, you’ll see that our roads and our intersections could become the limiting factor,” Gao said.
The study looks at the interaction between autonomous cars and the infrastructure on the ground, with the aim of unlocking the real capacity of autonomous transportation.
The researchers determined that the arrival and departure of groups of autonomous cars — known as platoons— in crossing directions need to be synchronized. Their model allows platoons to pass through one-way intersections without waiting.
The results of a microsimulation showed the model increased the capacity of vehicles on city streets up to 138% over a conventional traffic signal system.
The model assumes only autonomous cars are on the road; Gao’s team is addressing situations with a combination of autonomous and human-driven cars in future research.
Car manufacturers and researchers around the world are developing prototypes of self-driving cars that could be introduced by 2025. This Cornell research focuses on the infrastructure that will support these driverless cars.
Autonomous vehicles will be able to communicate with each other, offering opportunities for coordination and efficiency. The researchers’ model takes advantage of this capability, as well as smart infrastructure, in order to optimize traffic so cars can pass quickly and safely through intersections.
“Instead of having a fixed green or red light at the intersection, these cycles can be adjusted dynamically,” Gao said. “And this control can be adjusted to allow for platoons of cars to pass.”
The paper’s first author is postdoctoral associate Mahyar Amirgholy; Mehdi Nourninejad of the University of Toronto also contributed. The research was supported by the U.S. Department of Transportation; the Center for Transportation, Environment and Community Health; the National Science Foundation; and the Lloyd’s Register Foundation.