Abstract
This paper presents a method to design a Model Predictive Control to maximize the passengers’ comfort in assisted and self-driving vehicles by achieving lateral and longitudinal dynamic. The weighting parameters of the MPC are tuned off-line using a Genetic Algorithm to simultaneously maximize the control performance in the tracking of speed profile, lateral deviation and relative yaw angle and to optimize the comfort perceived by the passengers. To this end, two comfort evaluation indexes extracted by ISO 2631 are used to evaluate the amount of vibration transmitted to the passengers and the probability to experience motion sickness. The effectiveness of the method is demonstrated using simulated experiments conducted on a subcompact crossover vehicle. The control tracking performance produces errors lower than 0.1 m for lateral deviation, 0.5° for relative yaw angle and 1.5 km/h for the vehicle speed. The comfort maximization results in a low percentage of people who may experience nausea (below 5%) and in a low value of equivalent acceleration perceived by the passenger (below 0.315 [Formula: see text]“not uncomfortable” by ISO 2631). The robustness at variations of vehicle parameters, namely vehicle mass, front and rear cornering stiffness and mass distribution, is evaluated through a sensitivity analysis.
Highlights
A primary current focus in the automotive industry is the development of advanced solutions exploiting electronic and electromechanical devices for sensing, actuation and control tasks, intending to improve performance, safety and sustainability.[1]Many of these techniques, known as Advanced Driver Assistance Systems (ADAS), are designed to help the driver controlling the vehicle and are entitled to intervene in case of dangerous maneuvers, driver distraction and high-risk situations
An Model Predictive Control (MPC) designed to optimize the tracking of speed profile, lateral deviation and relative yaw angle and maximize the passenger comfort has been proposed
The passenger comfort was maximized through an appropriate choice of the weighting parameters of the controller
Summary
A primary current focus in the automotive industry is the development of advanced solutions exploiting electronic and electromechanical devices for sensing, actuation and control tasks, intending to improve performance, safety and sustainability.[1]. Many of these techniques, known as Advanced Driver Assistance Systems (ADAS), are designed to help the driver controlling the vehicle and are entitled to intervene in case of dangerous maneuvers, driver distraction and high-risk situations.
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