A method is described for computing a friction estimate between a road surface and a tire of a vehicle when the vehicle is in motion along a course, the tire being arranged on a steerable wheel of the vehicle, and the vehicle including two front wheels and two rear wheels and an axle rack pivotably attached to a linkage arm connected to the steerable wheel such that a translational motion of the axle rack causes the linkage arm to rotate about a kingpin element such that the linkage arm causes a turning motion of the steerable wheel. A corresponding system and vehicle are also described.

Provided is a vehicle control device that can reduce an uncomfortable feeling imparted to the driver when yaw-moment control is executed. In accordance with the output of a computation unit that instructs a yaw moment, the vehicle control device changes the distribution ratio between the braking force imparted to the front wheels and the braking force imparted to the rear wheels.

A method for controlling a hydraulic brake system for a motor vehicle to carry out a braking operation by means of at least one wheel brake includes, in a first step, a pressure buildup in the wheel brake, wherein hydraulic fluid is passed to a wheel brake via a normally open inlet valve. In a second step, a pressure reduction takes place in the wheel brake, wherein hydraulic fluid is discharged from the wheel brake via an energized normally closed outlet valve. The pressure reduction at the wheel brake is accomplished by means of control of the outlet valve in a predefined manner.

A vehicle disturbance detection apparatus includes an electronic control unit. The electronic control unit determines whether a disturbance occurs in a vehicle based on detection signals from a sensor device. The disturbance is a lateral external force that causes the vehicle to veer in a direction different from a direction expected by a driver. The electronic control unit determines that the disturbance occurs in the vehicle when a disturbance determination condition is established in a relationship between a calculated yaw rate and an actual yaw rate. The disturbance determination condition includes a cant traveling exclusion condition that is not established when the vehicle veers by traveling along a cant road but is established when the vehicle veers by receiving a crosswind.

Described herein is a vehicle system configured to identify and mitigate a risk associated with one or more hazards that may impact a vehicle. The vehicle system may include a service provider computer configured to maintain information related to one or more hazards. In some embodiments, a hazard may be identified based at least in part on its being located within the vicinity of a vehicle. In some embodiments, the service provider computer may generate a mitigation strategy to reduce or eliminate the risk posed by the identified hazard. The mitigation strategy may include one or more actions to be taken by a processor device within the vehicle. Upon being provided with a mitigation strategy, the processor device may execute one or more of the actions in the mitigation strategy without human interaction.

A method for actuating a hydraulic brake system in a motor vehicle, in which a hydraulic brake pressure is generated specific to the wheel, data of a driving environment sensor system being taken into account for detecting the instantaneous lateral distance of the motor vehicle from the desired track.

A braking control method for a vehicle having a motor includes: determining the braking torque required by each wheel; determining the motor braking torque to be provided by the motor based on the braking torque required by each wheel and the maximum torque of the motor; and determining the hydraulic braking torque of each wheel to be provided by a hydraulic anti-lock braking system (ABS) brake based on the braking torque required by each wheel and the motor braking torque.

According to at least one aspect, the present disclosure provides a method of controlling an electro-hydraulic brake including an electronic brake-force distribution (EBD) control function, the method comprising: an emergency braking determination operation of determining whether emergency braking is required for a vehicle; a motor control operation of controlling a current flowing in a motor connected to a main master cylinder to increase hydraulic pressure supplied to wheel brakes when it is determined that the emergency braking is required; a rear wheel inlet valve closing operation of closing an inlet valve connected to a rear wheel brake for a predetermined time so that a pressure of the rear wheel brake is not increased earlier than a pressure of a front wheel brake; a closed time period calculation operation of calculating a time during which the inlet valve is maintained in a closed state; and a rear wheel inlet valve opening operation of determining whether a time during which the inlet valve is closed exceeds a closed time period (t), maintaining the inlet valve in the closed state until the time reaches the closed time period (t), and opening the inlet valve when the time exceeds the closed time period (t).

A method for defining a target deceleration for an ego transportation vehicle including determining at least one motional variable of a transportation vehicle ahead; determining a braking time and a braking distance based on the motional variable which the transportation vehicle ahead respectively needs to come to a standstill; determining for the ego transportation vehicle a braking time that is needed to come to a standstill at the latest at the same position as the transportation vehicle ahead when the transportation vehicle ahead has travelled the braking distance; defining a target deceleration for the ego transportation vehicle based on a relationship of the braking times of the transportation vehicle ahead and the ego transportation vehicle. An apparatus for defining a target deceleration for an ego transportation vehicle and a transportation vehicle having such an apparatus.

A computer includes a processor and a memory storing instructions executable by the processor to determine at least one of a vehicle pitch or a longitudinal center of gravity from data measured while deactivating a first brake for a first axle and applying a second brake for a second axle, and operate the vehicle based on the at least one of vehicle pitch or longitudinal center of gravity. The instructions may further include to determine a vehicle weight from the data, and operate the vehicle based on the vehicle weight.