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Human-Like Obstacle Avoidance Trajectory Planning and Tracking Model for Autonomous Vehicles That Considers the Driver’s Operation Characteristics

Qinyu Sun, Yingshi Guo, Rui Fu, Chang Wang, Wei Yuan

2020Sensors11 citationsDOIOpen Access PDF

Abstract

Developing a human-like autonomous driving system has gained increasing amounts of attention from both technology companies and academic institutions, as it can improve the interpretability and acceptance of the autonomous system. Planning a safe and human-like obstacle avoidance trajectory is one of the critical issues for the development of autonomous vehicles (AVs). However, when designing automatic obstacle avoidance systems, few studies have focused on the obstacle avoidance characteristics of human drivers. This paper aims to develop an obstacle avoidance trajectory planning and trajectory tracking model for AVs that is consistent with the characteristics of human drivers' obstacle avoidance trajectory. Therefore, a modified artificial potential field (APF) model was established by adding a road boundary repulsive potential field and ameliorating the obstacle repulsive potential field based on the traditional APF model. The model predictive control (MPC) algorithm was combined with the APF model to make the planning model satisfy the kinematic constraints of the vehicle. In addition, a human driver's obstacle avoidance experiment was implemented based on a six-degree-of-freedom driving simulator equipped with multiple sensors to obtain the drivers' operation characteristics and provide a basis for parameter confirmation of the planning model. Then, a linear time-varying MPC algorithm was employed to construct the trajectory tracking model. Finally, a co-simulation model based on CarSim/Simulink was established for off-line simulation testing, and the results indicated that the proposed trajectory planning controller and the trajectory tracking controller were more human-like under the premise of ensuring the safety and comfort of the obstacle avoidance operation, providing a foundation for the development of AVs.

Topics & Concepts

Obstacle avoidanceTrajectoryObstacleCarSimController (irrigation)Control theory (sociology)Computer scienceField (mathematics)Control engineeringKinematicsModel predictive controlCollision avoidancePotential fieldSimulationEngineeringArtificial intelligenceMobile robotControl (management)RobotMathematicsPhysicsLawClassical mechanicsGeophysicsBiologyCollisionPolitical sciencePure mathematicsAgronomyAstronomyComputer securityGeologyAutonomous Vehicle Technology and SafetyVehicle Dynamics and Control SystemsRobotic Path Planning Algorithms