In a braking force control system for a vehicle having a braking system capable of controlling braking force of each of right and left front wheels and right and left rear wheels independently of one another, when anti-skid control starts being performed on one of the front wheels while the vehicle is running on a road having different coefficients of friction on the left side and right side thereof, increase of the braking force of the other front wheel laterally opposite to the above-indicated one front wheel is suppressed, and increase of the braking force of at least one of the right and left rear wheels is suppressed.

In a braking force control system for a vehicle having a braking system capable of controlling braking force of each of right and left front wheels and right and left rear wheels independently of one another, when anti-skid control starts being performed on one of the front wheels while the vehicle is running on a road having different coefficients of friction on the left side and right side thereof, increase of the braking force of the other front wheel laterally opposite to the above-indicated one front wheel is suppressed, and increase of the braking force of at least one of the right and left rear wheels is suppressed.

The hydraulic pressure controlling unit is capable of execute a first control, a second control, and a third control. The third control is configured to be started under condition that during the second control, an anti-lock brake control on the wheel brake on the high-μ road side is started, the acceptable differential pressure is equal to or larger than a first threshold, or a steering angle of a steering is equal to or larger than a second threshold. During the third control, the hydraulic pressure controlling unit is configured to decrease the hydraulic pressure of the wheel brake on the high-μ road side if the vehicle state deciding unit decides that the vehicle is in an unstable state.

The hydraulic pressure controlling unit is capable of execute a first control, a second control, and a third control. The third control is configured to be started under condition that during the second control, an anti-lock brake control on the wheel brake on the high-μ road side is started, the acceptable differential pressure is equal to or larger than a first threshold, or a steering angle of a steering is equal to or larger than a second threshold. During the third control, the hydraulic pressure controlling unit is configured to decrease the hydraulic pressure of the wheel brake on the high-μ road side if the vehicle state deciding unit decides that the vehicle is in an unstable state.

A method controls lateral pulling of a moving motor vehicle during braking. The method includes a) calculating a value representative of a difference between angular accelerations of left and right wheels of a wheelset of the motor vehicle, b) calculating a correction value as a function of at least the value representative of the difference between the angular accelerations; and c) controlling for the left wheel and the right wheel an associated brake so as to modify a drag force applied by the associated brake as a function of the correction value calculated in step b), such that the drag force applied to a first wheel of the left and right wheels is increased, and the drag force applied to a second wheel different from the first wheel is reduced, to reduce the value representative of the difference between the angular accelerations of the left and right wheels.

A method determines a roadway condition using steering actuators, wherein at least two steering actuators are arranged on each vehicle wheel. Measurement variables of the first and second steering actuators are sensed. The sensed measurement variables of the two steering actuators are compared with one another and, an inhomogeneity signal is determined from the deviation between the sensed measurement variables of the two steering actuators. If the inhomogeneity signal lies within a tolerance range, a homogeneous roadway condition exists. If the inhomogeneity signal lies outside the tolerance range, an inhomogeneous roadway condition exists.

A braking control device includes: a control unit that is configured to control front-wheel braking power and rear-wheel braking power based on braking power distribution and requested braking power; a distribution setting unit that is configured to set the braking power distribution; and a slip judgment unit that is configured to judge whether or not the vehicle is in a rear-wheel-led slip state. If it is judged that the vehicle is in the rear-wheel-led slip state when the braking power distribution is first braking power distribution, the distribution setting unit executes a distribution shifting process of shifting the braking power distribution to second braking power distribution within a predetermined period. The second braking power distribution is such distribution that the rear-wheel braking power is reduced relative to that observed when the first braking power distribution is set as the braking power distribution.

A braking control device includes: a control unit that is configured to control front-wheel braking power and rear-wheel braking power based on braking power distribution and requested braking power; a distribution setting unit that is configured to set the braking power distribution; and a slip judgment unit that is configured to judge whether or not the vehicle is in a rear-wheel-led slip state. If it is judged that the vehicle is in the rear-wheel-led slip state when the braking power distribution is first braking power distribution, the distribution setting unit executes a distribution shifting process of shifting the braking power distribution to second braking power distribution within a predetermined period. The second braking power distribution is such distribution that the rear-wheel braking power is reduced relative to that observed when the first braking power distribution is set as the braking power distribution.

A vehicle control system for a vehicle having a braking system and active suspension system is provided. The vehicle control system may be configured to adjust a normal component of a wheel force at one or more wheels of the vehicle to increase an average traction force at the one or more wheels during a braking event. The vehicle control system may adjust a normal component of a wheel force at one or more wheels based on reference road information, forward-looking road information, and/or vehicle sensor data.

A method is disclosed for controlling a vehicle in the event of unexpected braking with braking forces acting differently on respective sides on a steerable vehicle axle. The method includes determining whether there is unintentional braking with the braking forces causing the vehicle to yaw at a braking yaw rate in a yaw direction because of the braking forces. The yaw direction is determined in which the vehicle will yaw as a result of the braking forces. A steering angle requirement is specified and set immediately upon detection of unintentional braking with the different braking forces acting on the respective sides on the steerable vehicle axle with the steering angle requirement being specified in dependence upon the yaw direction so as to cause the braking yaw rate to be compensated on the steerable vehicle axle after setting the steering angle requirement.