Traditional Model Predictive Control (MPC) with fixed horizon cannot balance computational burden and tracking performance under complex conditions. To improve autonomous vehicle path-tracking performance, this study introduces a dual-horizon adaptive MPC strategy, optimizing both control and prediction horizons. This helps to reduce trajectory tracking errors while optimizing computing resources dynamically. First, we establish a vehicle dynamics model and a path-tracking model. Subsequently, the variations in the control and prediction horizons are determined via fuzzy control. The used integration scheme comprehensively considers three key parameters: vehicle speed, lateral deviation, and yaw rate, where the yaw rate measurement is used Kalman filter-based observation. The MPC controller first adjusts the control and prediction horizons. Next, it calculates the desired front-wheel steering angles and direct yaw moment. High-speed condition simulations are performed using MATLAB/Simulink and CarSim co-simulation platforms. Results demonstrate enhanced trajectory tracking accuracy with the variable-horizon MPC approach. Simultaneously, the method improves the computational efficiency, saving about 15.5% of the computation time on average.
Lin et al. (Thu,) studied this question.
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