🤖 AI Summary
This work addresses the decoupling between decision-making and trajectory planning for autonomous vehicles at unsignalized intersections by proposing an end-to-end integrated framework. By formulating a finite-horizon optimal control problem, the method uniquely combines time-varying artificial potential fields, short-term motion prediction, and conflict-zone occupancy coefficients to dynamically mitigate collision risks and generate safe, feasible reference trajectories. Evaluated in multi-vehicle simulation scenarios involving complex unsignalized intersections, the approach demonstrates effective navigation with high efficiency and safety, significantly enhancing overall system coordination and real-time performance.
📝 Abstract
This paper presents a novel framework for integrated Decision-Making (DM) and Trajectory Planning (TP) for automated vehicles at unsignalized intersections. The approach leverages a Finite Horizon Optimal Control Problem (FHOCP) that employs Time-Varying Artificial Potential Fields (TV-APF). By utilizing short-horizon motion prediction and a dedicated conflict-zone occupancy coefficient, the framework suitably accounts for potential collisions within the FHOCP. The proposed method effectively unifies DM and TP, ensuring the generation of a feasible and safe reference trajectory. Simulation results in multi-vehicle traffic scenarios demonstrate the effectiveness of the approach.