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Rule-Based Safety-Critical Control Design using Control Barrier Functions with Application to Autonomous Lane Change

Suiyi He, Jun Zeng, Bike Zhang, Koushil Sreenath

202162 citationsDOI

Abstract

This paper develops a new control design for guaranteeing a vehicle's safety during lane change maneuvers in a complex traffic environment. The proposed method uses a finite state machine (FSM), where a quadratic program based optimization problem using control Lyapunov functions and control barrier functions (CLF-CBF-QP) is used to calculate the system's optimal inputs via rule-based control strategies. The FSM can make switches between different states automatically according to the command of driver and traffic environment, which makes the ego vehicle find a safe opportunity to do a collision-free lane change maneuver. By using a convex quadratic program, the controller can guarantee the system's safety at a high update frequency. A set of pre-designed typical lane change scenarios as well as randomly generated driving scenarios are simulated to show the performance of our controller.

Topics & Concepts

Computer scienceControl theory (sociology)Controller (irrigation)CollisionLyapunov functionQuadratic programmingControl (management)Set (abstract data type)Quadratic equationState (computer science)Vehicle dynamicsConvex optimizationCollision avoidanceActive safetyControl engineeringRegular polygonMathematical optimizationEngineeringAlgorithmAutomotive engineeringMathematicsArtificial intelligenceAgronomyComputer securityPhysicsQuantum mechanicsBiologyGeometryNonlinear systemProgramming languageVehicle Dynamics and Control SystemsAutonomous Vehicle Technology and SafetyFormal Methods in Verification
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