A method for assisting a driver in controlling a vehicle, the vehicle comprising a road wheel and at least one vehicle sensor configured to provide vehicle condition data, the road wheel comprising a tyre sensor configured to output tyre operation data, the method comprising: receiving tyre operation data from the tyre sensor during the vehicle being controlled along at least one lap of a track; receiving vehicle condition data from at least one vehicle sensor during the vehicle being controlled along at least one lap of the track; determining, based on the tyre operation data and vehicle condition data, an intervention the driver should make during a future lap of the track; and communicating the intervention to the driver.

A system vectors torque between two wheels of a rear axle of an electric motor vehicle that are disposed on either side of the vehicle and are each driven by an electric motor in order to distribute a torque between the two wheels. The system includes a first torque setpoint generator, a second slip correction torque generator, a detector for detecting oversteer or understeer of the vehicle during the acceleration phase when turning, a third skid correction torque generator, a corrected-torque set point generator, and a controller for controlling the first electric motor based on the first corrected-torque set point and for controlling the second electric motor based on the second corrected-torque setpoint.

A vehicle behavior control method is suitable for a vehicle behavior control device. The vehicle behavior control device includes: a lateral acceleration sensor, detecting lateral acceleration occurring in a vehicle body; a wheel speed sensor, detecting a wheel speed of a wheel; a steering angle sensor, detecting a steering angle of the wheel; a steering angle lateral acceleration calculation unit, calculating steering angle lateral acceleration from the wheel speed and the steering angle; and a yaw moment control unit, applying yaw moment to the vehicle body. In the vehicle behavior control method, when the lateral acceleration and the steering angle lateral acceleration meet a predetermined condition, a yaw moment directed inward in a turning direction of the vehicle body is applied by the yaw moment control unit.

A vehicle control system includes a skill level module that determines a skill level of a driver of the vehicle based on both (i) a lateral acceleration of the vehicle and (ii) a longitudinal acceleration of the vehicle. A handling module determines a handling type based on a rate of change of a steering wheel angle. An actuator control module, based on the skill level of the driver and the handling type, selectively actuates a dynamics actuator of the vehicle.

A vehicle electronic stability control system which allows a vehicle to have improved movement performance and limit performance without causing a driver to feel uncomfortable, by actuating electronic stability control from a state where a lateral slip is relatively less likely to occur. The system prevents a skid of a vehicle. The system is provided with a stability determination module that obtains information indicating vehicle behavior from a sensor, and determines whether the vehicle is in an unstable or less stable state, on the basis of the information. The system is further provided with a braking/driving force control module which, when the stability determination module determines that the vehicle is in the unstable or less stable state, applies a braking force to one of the drive wheels, and simultaneously applies a driving force to the motor for the other drive wheel.

A method for controlling in real time the path of a motor vehicle travelling in a traffic lane includes detecting a corner in the traffic lane, then, when the vehicle enters the corner, determining first and second quantities for a plurality of successive sampling increments, based on state variables characteristic of the movement of the vehicle, determining a first stored value dependent on the first quantity determined in the current sampling increment and one of the preceding sampling increments, determining a second stored value dependent on the second quantity determined in the current sampling increment and one of the preceding sampling increments, saving the first and second stored values determined for each sampling increment, then, when the vehicle exits the corner determining a value of the understeer gradient depending on the saved first and second stored values, and determining a command for the vehicle based on the understeer gradient.

An object is to provide an attitude control system that can suppress an understeering characteristic when a vehicle such as an automobile travels in a medium-speed or low-speed range. A vehicle drives front wheels, and controls steering angles of the front wheels and steering angles of rear wheels. In an attitude control system to be mounted on the vehicle, a control amount detecting unit detects an operation amount of an accelerator pedal operated by a driver of the vehicle. A driving force estimating unit estimates a driving force generated on the front wheels based on the operation amount of the accelerator pedal. A rear-wheel steering angle determining unit determines a rear-wheel steering angle instruction value for controlling steering angles of the rear wheels based on an estimated front-wheel driving force that is the driving force estimated by the driving force estimating unit.

A vehicle control system includes a skill level module that determines a skill level of a driver of the vehicle based on both (i) a lateral acceleration of the vehicle and (ii) a longitudinal acceleration of the vehicle. A handling module determines a handling type based on a rate of change of a steering wheel angle. An actuator control module, based on the skill level of the driver and the handling type, selectively actuates a dynamics actuator of the vehicle.

The present invention consists in determining at least one dangerous driving indicator (IND) by means of a physical model (MOD) based on the dynamics of the vehicle. According to the invention, the dynamic model (MOD) of the vehicle makes it possible to determine a slip parameter (, SR) of the vehicle, which is used to deduce a representative dangerous driving indicator (IND).

A method and a system for an automated parking determines, using the geometry of the vehicle and the map of the parking space, a collision free geometric path connecting an initial state of the vehicle with a target state of parked vehicle through a set of waypoints and determines, using a kinematic model of the vehicle, a set of kinematic subgraphs forming a kinematic graph having multiple nodes connected with kinematic edges. Each waypoint defines a position and orientation of the vehicle, each kinematic subgraph connects a pair of neighboring waypoints of the geometric path, each node defines a state of the vehicle, and each kinematic edge connecting two nodes defines a collision free kinematic path connecting the two nodes according to kinematics of the vehicle. A kinematic path is selected form the kinematic graph and a reference trajectory tracking the kinematic path as a function of time is determined using a dynamic model of the vehicle. The motion of the vehicle is according to the reference trajectory.