A control system for a motor vehicle automatically activates or deactivates a parking lock or an automatic roll-away prevention facility. The control system has at least one electronic control unit which is designed such that limited maneuvering operation is possible within set boundary conditions in accordance with predefined embarking conditions and in accordance with predefined disembarking conditions, an identified intentional maneuvering demand of the driver after prior automatic roll-away prevention of the vehicle being defined as a predefined embarking condition. The limited maneuvering operation may be activatable both in the case of an activated motor and in the case of a deactivated motor proceeding from a secured state. Depending on the differently defined disembarking conditions that are satisfied, a transition can be made from the limited maneuvering operation either into the secured state, or driving operation can be permitted if the defined conditions for the automatically secured state are no longer present.

Disclosed herein is an electronic brake system and a method for controlling the same are disclosed. The electronic brake system includes a master cylinder for discharging oil according to displacement of a brake pedal, a pedal displacement sensor sensing brake pedal displacement, a simulation apparatus providing pedal pressure responsive to the sensed pedal displacement, a hydraulic pressure supply unit for generating hydraulic pressure using a motor that operates based on the sensed pedal displacement, a hydraulic circuit for supplying the hydraulic pressure generated from the hydraulic pressure supply unit to the caliper, a cut valve positioned between the master cylinder and the hydraulic circuit for transmitting or blocking the hydraulic pressure discharged from the master cylinder, and a controller for blocking at least one of the cut valve and braking control with a target pressure according to a pressure in the simulation apparatus when the simulation apparatus fails.

Disclosed is an electronic brake system that includes a master cylinder unit including a master cylinder to which a master cylinder reservoir coupled to generate a hydraulic pressure, a hydraulic block provided with a hydraulic pressure supply device to generate the hydraulic pressure by an electrical signal outputted in response to a displacement of a brake pedal and a hydraulic control unit to transmit the hydraulic pressure discharged from the hydraulic pressure supply device to wheel cylinders provided in each wheel, and disposed to be separated from the master cylinder unit, a hydraulic block reservoir coupled to the hydraulic block, and a connection hose to connect the master cylinder reservoir and the hydraulic block reservoir.

A method for operating a hill hold controller of a motor vehicle including at least one parking brake. The parking brake is disengaged according to an actuation of a gas pedal of the motor vehicle. The disengagement of the parking brake is released according to a variable representing a road gradient. The release to disengage the parking brake is granted, independently of the variable and/or the availability of the variable, when the gas pedal of the motor vehicle reaches or exceeds a predefinable release position by way of the actuation thereof.

A fluid control system that has a fluid assembly with a piston defined within a chamber, an electrical system having a motor configured to selectively reposition the piston, a controller in communication with the electrical system, and a sensor in communication with the controller to identify a fluid pressure value. Wherein, the controller identifies a desired fluid pressure range and selectively repositions the piston with the motor until the fluid pressure value is within the desired fluid pressure range.

A method avoids a collision of a motor vehicle initially moving backwards or forwards, in particular leaving a parking place, with cross-traffic. The method detects whether there is a risk of collision with cross-traffic; determines a last possible braking intervention for ensuring avoidance of collision when there is a risk of collision with cross-traffic; and performs an automatic last possible initiation of a braking intervention for preventing the collision in the event of an identified risk of collision, if avoidance of the collision is ensured thereby.

A method for operating a brake of a motor vehicle with at least one electronic brake signal generator and with at least one brake control device for actuating the brake based on a brake signal of the brake signal generator includes transmitting the brake signal to the brake control device. The method additionally includes transmitting an actuation of the brake signal generator as a brake signal to the brake control device in addition to a brake pressure value.

A driving support apparatus includes a surrounding sensor capable of acquiring surrounding information on a three-dimensional object around a vehicle and a road marking ahead of the vehicle, and a vehicle state sensor capable of acquiring vehicle state information on multiple types of vehicle states in response to driving operation by a driver, including an AP operation amount in response to the driver's AP operation as one of the vehicle states. The apparatus further includes a control unit configured to execute deceleration assist control to assist deceleration when a predetermined start condition is satisfied, and to cancel the deceleration assist control when a cancel condition which is satisfied when the AP operation is performed during execution of the deceleration assist control is satisfied. When the cancel condition is satisfied, the control unit reduces the braking force based on the surrounding information and the vehicle state information.

The electric brake device includes an electric motor, a friction member operator, a friction member, a brake rotor, and a control device. A braking force estimator provided in the control device includes: a direct estimator configured to convert output of a braking force sensor which detects a load or displacement corresponding amount, to a braking force; and an indirect estimator configured to estimate the braking force on the basis of information other than output of the braking force sensor. A range in which the braking force is estimated by the direct estimator is a specified low-braking-force range, and in a range beyond this range, estimation of the braking force is performed by the indirect estimator.

A vehicle braking system includes a wheel cylinder, a brake pedal, a master cylinder, a master cylinder circuit, a primary braking unit operable to generate a braking force at the wheel cylinder in a primary mode, decoupled from the master cylinder circuit, a secondary braking unit including a second electrically-actuated pressure generating unit and operable to generate a braking force at the wheel cylinder in a secondary mode of operation, a plurality of valves configured to provide anti-lock braking at the wheel cylinder upon loss of traction during braking in the primary mode of operation, and a controller programmed to actuate the plurality of valves and further programmed to actuate the second electrically-actuated pressure generating unit upon loss of traction in the primary mode of operation to generate pulsations within the master cylinder circuit to provide a feedback force at the brake pedal indicative of the anti-lock braking.