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A Comparison of Trajectory Planning and Control Frameworks for Cooperative Autonomous Driving

Ícaro Bezerra Viana, Husain Kanchwala, Kenan Ahıska, Nabil Aouf

2021Journal of Dynamic Systems Measurement and Control34 citationsDOIOpen Access PDF

Abstract

Abstract This work considers the cooperative trajectory-planning problem along a double lane change scenario for autonomous driving. In this paper, we develop two frameworks to solve this problem based on distributed model predictive control (MPC). The first approach solves a single nonlinear MPC problem. The general idea is to introduce a collision cost function in the optimization problem at the planning task to achieve a smooth and bounded collision function, and thus to prevent the need to implement tight hard constraints. The second method uses a hierarchical scheme with two main units: a trajectory-planning layer based on mixed-integer quadratic program (MIQP) computes an on-line collision-free trajectory using simplified motion dynamics, and a tracking controller unit to follow the trajectory from the higher level using the nonlinear vehicle model. Connected and automated vehicles (CAVs) sharing their planned trajectories lay the foundation of the cooperative behavior. In the tests and evaluation of the proposed methodologies, matlab-carsim cosimulation is utilized. carsim provides the high-fidelity model for the multibody vehicle dynamics. matlab-carsim conjoint simulation experiments compare both approaches for a cooperative double lane change maneuver of two vehicles moving along a one-way three-lane road with obstacles.

Topics & Concepts

CarSimTrajectoryComputer scienceController (irrigation)Control theory (sociology)Collision avoidanceMotion planningVehicle dynamicsFunction (biology)Model predictive controlNonlinear systemTrajectory optimizationMathematical optimizationMATLABCollisionControl engineeringSimulationOptimal controlControl (management)EngineeringArtificial intelligenceMathematicsRobotAutomotive engineeringBiologyEvolutionary biologyAstronomyPhysicsQuantum mechanicsAgronomyOperating systemComputer securityVehicle Dynamics and Control SystemsTraffic control and managementReal-time simulation and control systems
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