A method for controlling a motor vehicle including the steps of transitioning the vehicle from a brake holding mode to an engine driving mode and then accelerating the vehicle in a forward direction until a set vehicle target speed has been reached. The method including maintaining the vehicle at the set target speed until a driver of the vehicle intervenes.

Method and apparatus are disclosed for traction control based on friction coefficient estimation. An example vehicle includes a plurality of sensors to measure qualities of a surface of a road and an anti-lock brake system module. The anti-lock brake system module (a) estimates confidence values for different road surface types based on the qualities of the surface of the road, (b) estimates a coefficient of friction between the road and tires of the vehicle based on the confidence values, and (c) adapt a traction control system by altering a target slip based on the coefficient of friction.

Method and apparatus are disclosed for traction control based on friction coefficient estimation. An example vehicle includes a plurality of sensors to measure qualities of a surface of a road and an anti-lock brake system module. The anti-lock brake system module (a) estimates confidence values for different road surface types based on the qualities of the surface of the road, (b) estimates a coefficient of friction between the road and tires of the vehicle based on the confidence values, and (c) adapt a traction control system by altering a target slip based on the coefficient of friction.

A stability index is determined based on the estimated position, the estimating heading, and the estimated yaw rate. A surface roughness estimator is adapted to estimate a variance or standard deviation of the roll of roll angle change based on the measured roll angle. A wheel-slip estimator estimates the wheel slip indicator based on numerator of drivetrain-derived wheel speed minus estimated velocity, which numerator is collectively divided by the drivetrain-derived wheel speed. A performance evaluation module determines a performance rating based on the determined stability index, the estimated surface roughness index and the estimated wheel slip.

A control method for a motor-driven vehicle is provided. The method includes calculating a correction torque of a drive motor through a difference between speeds of wheels or a variance rate of the difference between speeds of the wheels and comparing a calculated correction torque with a current required torque of the drive motor. When the calculated correction torque is greater than the current required torque, the drive motor is operated based on the current required torque. When the calculated correction torque is less than or equal to the current required torque, the drive motor is operated based on the calculated correction torque, or the required torque of the drive motor is corrected to correspond to the calculated correction torque and the drive motor is operated based on a corrected required torque of the drive motor.

A device for wheel slip control on a motor vehicle having at least one front axle and at least one rear axle is specified, wherein the front axle is assigned at least one front actuator for influencing at least one linear front wheel speed, and the rear axle is assigned at least one rear actuator for influencing at least one linear rear wheel speed. The device comprises at least one interface, which is designed to receive the following parameters: at least one first parameter indicating the at least one linear front wheel speed; at least one second parameter indicating the at least one linear rear wheel speed; and at least one third parameter indicating a vehicle speed, wherein the at least one third parameter is different from the at least one first parameter and the at least one second parameter.

A control system that controls a driveline of a motor vehicle to operate in a selected one of a plurality of configurations is configured to receive a brake signal responsive to the application of a braking system. The control system causes the driveline to operate in a second configuration and not a first configuration in dependence at least in part on the brake signal. In the first configuration a first group of one or more wheels and in addition a second group of one or more wheels are arranged to be driven by the driveline, and in the second configuration the first group of one or more wheels and not the second group are arranged to be driven by the driveline.

A method for controlling a motor vehicle take-off from rest including the steps of transitioning the vehicle from a brake holding mode to an engine driving mode and then accelerating the vehicle in a forward direction until a set vehicle target speed has been reached. The method including maintaining the vehicle at the set target speed until a driver of the vehicle intervenes.

The present invention provides a vehicle control apparatus, a vehicle control method, and a vehicle control system capable of optimizing balance between a target tire lateral force and a target tire longitudinal force. A vehicle control apparatus outputs an instruction for achieving an optimal slip ratio corresponding to a minimum value of a sum of a first difference and a second difference to an actuator regarding braking/driving of a vehicle. The first difference is a difference between a tire lateral force and a target tire lateral force with respect to an arbitrary slip ratio in a correlative relationship between a slip ratio and the tire lateral force of a tire of a wheel portion. The second difference is a difference between a tire longitudinal force and a target tire longitudinal force with respect to the arbitrary slip ratio in a correlative relationship between the slip ratio and the tire longitudinal force.

Described herein is a system and method for preemptive chassis control intervention for an autonomous vehicle having a mechanical system and a chassis controller. The chassis controller is configured to output a consumption signal that represents a percentage of an activation threshold consumed by an operation monitored by the chassis controller, wherein the chassis controller is activated to manipulate the mechanical system when the activation threshold is reached. A computing system of the autonomous vehicle receives the consumption signal output by the chassis controller to determine a path plan for the autonomous vehicle based upon the percentage of the activation threshold consumed by the operation monitored by the chassis controller. The computing system further controls the mechanical system to execute the path plan to preempt activation of the chassis controller.