Institutional Repository [SANDBOX]
Technical University of Crete
EN  |  EL

Search

Browse

My Space

A lateral positioning strategy for connected and automated vehicles in lane-free traffic

Faros Ioannis, Yanumula Venkata-Karteek, Typaldos Panagiotis, Papamichail Ioannis, Papageorgiou Markos

Full record


URI: http://purl.tuc.gr/dl/dias/2008C788-DB75-4047-9762-3AD11545051F
Year 2022
Type of Item Conference Short Paper
License
Details
Bibliographic Citation I. Faros, V. K. Yanumula, P. Typaldos, I. Papamichail and M. Papageorgiou, “A lateral positioning strategy for connected and automated vehicles in lane-free traffic,” in 4th Symposium on Management of Future Motorway and Urban Traffic Systems (MFTS 2022), Dresden, Germany, November 30 - December 2, 2022, pp. 9-17, doi: 10.25368/2023.93. https://doi.org/10.25368/2023.93
Appears in Collections

Summary

An optimal-control based path planning algorithm has been developed recently for Connected and Automated Vehicles (CAVs) driving on a lane-free highway, including vehiclenudging. That vehicle movement strategy considers, in the lateral direction, a lateral desired speed that had been set to zero in previous works; in other words, vehicles avoid lateral movement if this is not helpful in achieving some of their goals, e.g. achieving a longitudinal desired speed by overtaking slower vehicles. In this work, a lateral positioning strategy for the vehicles is proposed, aiming to improve the vehicles’ longitudinal speeds and the traffic flow, mainly at intermediate densities, by distributing laterally the vehicles based on their longitudinal desired speeds. The intention is to leverage the existing optimal control formulation to move the CAVs to appropriate lateral positions, while respecting other, higher-priority sub-objectives, such as avoiding crashes. First, the longitudinal desired speed of each vehicle is mapped to a lateral desired position under the premise “faster vehicles drive farther left”. Then, the value of the desired lateral speed is updated in real-time in dependence on the vehicle’s current versus the desired lateral position, letting the optimal control problem, with the given sub-objective priorities, decide on the actual vehicle path. The proposed strategy is demonstrated via traffic simulations, involving various traffic densities, on a ring-road. Several quantities, such as the reached average flows and statistical measures of the error in the lateral position are computed for evaluation and comparison purposes.

Available Files

Services

Statistics