A method for operating a brake system of a motor vehicle includes actuating a first actuating device of the brake system, exerting an electromechanical braking force to decelerate the motor vehicle in an event of a fault in the hydraulic braking device and when the first actuating device is actuated, and generating the electromechanical braking force after a start of the actuation of the first actuating device for a minimum generation period and/or generating the electromechanical braking force after an end of the actuation of the first actuating device for an additional continued generation period. The brake system includes a hydraulic braking device, an electromechanical braking device, and a first actuating device, in particular a brake pedal.

A method for operating a brake system of a motor vehicle includes actuating a first actuating device of the brake system, exerting an electromechanical braking force to decelerate the motor vehicle in an event of a fault in the hydraulic braking device and when the first actuating device is actuated, and generating the electromechanical braking force after a start of the actuation of the first actuating device for a minimum generation period and/or generating the electromechanical braking force after an end of the actuation of the first actuating device for an additional continued generation period. The brake system includes a hydraulic braking device, an electromechanical braking device, and a first actuating device, in particular a brake pedal.

A control device may be configured for responding to failure for ensuring the stability of a vehicle by switching from a two-wheel-drive mode to a four-wheel-drive mode when detecting failure of the brake system in a two-wheel-drive mode.

A control device may be configured for responding to failure for ensuring the stability of a vehicle by switching from a two-wheel-drive mode to a four-wheel-drive mode when detecting failure of the brake system in a two-wheel-drive mode.

System for suctioning braking particles from a friction braking system of a vehicle, the suction system including a negative-pressure source, a suction mouth, a filter, a conduit connecting the suction mouth to the negative-pressure source, a control unit configured to control the negative-pressure source, the suction system further including a stream of information originating from a computer that controls a motor-generator of a driving/braking system of the vehicle, the control unit being configured to control the negative-pressure source preemptively before the actual activation of the friction braking, the control unit controlling the negative-pressure source as a function of the activation of electromagnetic braking or other parameters, and associated method.

A method for operating a motor vehicle including an actuating element which is, in particular steplessly, displaceable between a first end position and a second end position. An instantaneous position of the actuating element is monitored. A deceleration torque being predefined for the motor vehicle when the instantaneous position is in a deceleration range situated between the first end position and a predefinable change position, and an acceleration torque being predefined for the motor vehicle when the instantaneous position is in an acceleration range situated between the second end position and the change position. A monitoring is carried out for the occurrence of at least one disturbance variable which influences an actual deceleration of the motor vehicle effectuated by the deceleration torque, the deceleration torque being changed as a function of a detected disturbance variable.

A method for operating a motor vehicle including an actuating element which is, in particular steplessly, displaceable between a first end position and a second end position. An instantaneous position of the actuating element is monitored. A deceleration torque being predefined for the motor vehicle when the instantaneous position is in a deceleration range situated between the first end position and a predefinable change position, and an acceleration torque being predefined for the motor vehicle when the instantaneous position is in an acceleration range situated between the second end position and the change position. A monitoring is carried out for the occurrence of at least one disturbance variable which influences an actual deceleration of the motor vehicle effectuated by the deceleration torque, the deceleration torque being changed as a function of a detected disturbance variable.

A braking device is mounted on a vehicle having two or more rows of right and left wheels, electric brakes, and at least one steering actuator. The steering actuator is capable of turning at least one row of the right and left wheels regardless of a steering wheel operation. The braking device includes a braking control unit configured to control a braking force of the electric brake for each of the wheels and operation of the steering actuator. When an abnormality detector detects an abnormality in the electric brakes, the braking control unit switches to an abnormal-time braking control different from a normal state control, at least controlling the steering actuator so as to suppress an influence on the vehicle due to the abnormality.

A braking device is mounted on a vehicle having two or more rows of right and left wheels, electric brakes, and at least one steering actuator. The steering actuator is capable of turning at least one row of the right and left wheels regardless of a steering wheel operation. The braking device includes a braking control unit configured to control a braking force of the electric brake for each of the wheels and operation of the steering actuator. When an abnormality detector detects an abnormality in the electric brakes, the braking control unit switches to an abnormal-time braking control different from a normal state control, at least controlling the steering actuator so as to suppress an influence on the vehicle due to the abnormality.

A vehicle motor control apparatus includes: a processor configured to determine whether a state of a vehicle is an over-steer state or an under-steer state, to determine a driving control mode or a braking control mode of a motor based on a determination result of the state of the vehicle, to calculate a target yaw moment of based on a tire force by using the over-steer state or the under-steer state, and to determine a motor control amount that follows the target yaw moment; and a storage configured to store data and algorithms driven by the processor.