On Optimization-Based Coordination of Automated Vehicles in Confined Sites
Doctoral thesis, 2024
Optimization-based control methods are useful for planning AV operations, considering key operational constraints. However, these methods can be slow for real-time applications due to the complexity of solving the optimization problems involved, especially for coordinating multiple vehicles. This thesis introduces a method using optimization-based heuristics to simplify and approximate these problems.
The method involves a two-stage optimization approach for AV coordination in confined sites. Specifically, the combinatorial part of the coordination problem that is related to the occupancy orders of the conflict zones is formulated as a Mixed Integer Quadratic Program (MIQP). In the second stage, the optimal control commands for each vehicle are found under a fixed crossing order by solving a Nonlinear Program (NLP). To additionally improve the computational demand of the approach we propose a decomposition strategy based on a graph theory, where the centralized NLP is decomposed into multiple, parallelly solvable NLPs. Utilizing the Lagrange dual variables we propose a method that can further decompose the NLP and can be used to find a trade-off between improved computation time and optimality.
Finally, we adapted the optimization-based method to be able to handle the scenarios when human-driven vehicles (HDVs) are present in the confined site. Specifically, the heuristic predicts HDV behavior using a model that accounts for various human reactions. In cases where an HDV follows another vehicle, a car-following model is used, where the HDV's movement depends on the lead vehicle. This allows for partial control over the HDV movement, especially if the lead vehicle is an AV. In particular, the lead AV could slow down or speed up the HDV such that a desired occupancy order is achieved, resulting in a more efficient motion of the AV fleet. The MIQP is adapted to include HDV motion estimates and to determine if the HDV can use a car-following model. The NLP is modified to capture HDV movements and establish safety constraints between AVs and HDVs. Through closed-loop receding horizon control, we demonstrate how the occupancy order for the zones can be dynamically adapted to current conditions and HDV motion predictions.
optimal scheduling
multi-agent systems
Automated vehicles
motion control
optimization.
cooperative systems
optimal control
graph theory
Author
Stefan Kojchev
Chalmers, Electrical Engineering, Systems and control
A Two-Stage MIQP-Based Optimization Approach for Coordinating Automated Electric Vehicles in Confined Sites
IEEE Transactions on Intelligent Transportation Systems,;Vol. 25(2024)p. 2061-2075
Journal article
Stefan Kojchev, Robert Hult, Maximilian Kneissl, Jonas Fredriksson. A Computation Decomposition Strategy for Optimization-Based Coordination of Automated Vehicles in Confined Sites
Stefan Kojchev, Robert Hult, Maximilian Kneissl, Jonas Fredriksson. Optimization-based coordination of automated and human-driven vehicles in confined sites
In these settings, a key issue is determining how vehicles should operate to achieve their objectives, increase productivity, and avoid collisions. Optimal control, which involves deriving vehicle control commands by solving optimization problems, is a promising approach for planning vehicle motion.
This thesis proposes an optimization-based framework for planning the motion of vehicles operating in a confined site such that collisions between vehicles are avoided. The framework is scalable and adaptable to a variety of confined sites and vehicle types and promises improvements in operational efficiency.
Areas of Advance
Transport
Production
Energy
Subject Categories
Control Engineering
ISBN
978-91-8103-040-2
Doktorsavhandlingar vid Chalmers tekniska högskola. Ny serie: 5498
Publisher
Chalmers