A vehicle-electrical-apparatus, including: a service-brake-valve-device (SBVD) having an electropneumatic service-brake-device (ESBVD), which is an electronically-brake-pressure-regulated-brake-system (EBPRBS), having an ESBVD, a first-electronic-brake-control-device (EBCD), electropneumatic-modulators (EM) and pneumatic-wheel-brake actuators (PWBA); a sensor-device; the first-EBCD controls the EMs generating pneumatic brake-control-pressures (PBCP) for the PWBAs, and the ESBVD has a service-brake-actuation-member (SBAM) and an electrical-channel containing an electrical-brake-value-transmitter, actuate-able by the SBAM, and a second-EBCD couples brake-request signals into the first-EBCD depending on the AS, and, within a pneumatic-service-brake-circuit, a pneumatic-channel in which a control-piston of the SBVD is loaded with a first-actuation-force (AF) by actuating the service-brake-actuation-member based on a driver brake-request, and the control-piston controls a double-seat valve of the SBVD to generate PBCPs for the PWBAs; generating a second AF that acts on the control-piston; brake slip/driving-dynamics-regulation are in the second-EBCD, the second-EBCD receives sensor-signals, and for braking requested, generating the second AF to perform a brake-slip and/or driving-dynamics-regulation.

The invention relates to an electric brake system (1) for a vehicle. The electric brake system (1) comprises electric brake devices (2). The electric brake devices (2) are powered and controlled by redundant capacitor-based power sources (9A, 9B) and redundant control circuits (16A, 16B). The capacitor-based power source (9A, 9B) can be integrated into axle modules (39A, 39B) located close to a vehicle axle (61A, 61B). The capacitor-based power sources (9A, 9B) are recharged by a hub generator, a regeneration power source (32).

A method for checking functionality of a motor vehicle braking system. The braking system has a main module, including: hydraulically actuatable wheel brakes, pairs being assigned to respective brake circuits; at least one electrically actuatable wheel valve per wheel brake sets wheel-specific brake pressures; a pressure provision device actively builds up pressure in the wheel brakes; a pressure-medium reservoir at atmospheric pressure, and an auxiliary module, which has for each of two wheel brakes: a pressure sensor for measuring pressure in a wheel brake line; an open when deenergized isolating valve in the wheel brake line; a pump. At least one variable is measured to assess functionality of the braking system. Using least one acceptance criterion, and checked whether the variable satisfies the acceptance criterion. Determining at least one variable representing the viscosity of the brake fluid, and the at least one acceptance criterion depends on a variable representing viscosity.

The present disclosure relates to a device for operating an automated parking brake with an actuator for a motor vehicle, wherein the device comprises at least: a central control unit and an application-specific integrated circuit, which application-specific integrated circuit represents an interface between the control unit and the actuator. According to the disclosure, the device is characterized in that the application-specific integrated circuit has a functionally not changeable part and a part that can be functionally changed by means of program code, wherein the functionally changeable part is designed to carry out a specified error check. The disclosure further relates to a method for operating such a device.

The present invention relates to a braking technology of a vehicle, and in particular to a high fault tolerance brake system for a vehicle, a control method for the brake system, and a computer readable medium. The brake system comprises two control modules (211, 212) and an electric brake device (131; 132) provided on each wheel of the vehicle. Each of the electric brake devices (131; 132) may receive brake requests from the two control modules (211, 212) generated in response to a brake demand to brake or release a corresponding wheel. The brake system may further comprise a raw signal acquisition module (311) for acquiring a raw signal indicating the brake demand and directly transmitting the raw signal to at least one of the electric brake devices (131; 132) for verifying the brake requests. The present invention may improve fault tolerance of the vehicle brake system.

A vehicle control device that controls a vehicle electric brake system includes: a shutdown determination part that determines whether the vehicle control device itself has been previously shut down normally or abnormally; a cranking determination part that determines whether an instruction to perform a cranking at a start-up of the vehicle is based on a manual operation of a driver of the vehicle or automatically; a diagnosis part that performs a plurality of initial diagnoses of the vehicle control device at the start-up of the vehicle; and a diagnosis skip control part configured to provide control such that the diagnosis part skips at least one of the initial diagnoses when the shutdown determination part determines that the vehicle control device has been previously shut down abnormally, and at the same time, when the cranking determination part determines that the cranking has been conducted based on the driver's manual operation.

A braking system in an at least partially autonomous vehicle, having one vehicle wheel brake per vehicle wheel, which is assigned to both the primary brake regulation system and a redundant secondary brake regulation system, wherein the primary brake regulation system has a primary control unit and one electromechanical primary actuator per vehicle wheel for actuating the vehicle wheel brake, and wherein the primary control unit generates primary positioning signals for activating the respective electromechanical primary actuator on the basis of a setpoint deceleration specification generated in a pilot system and/or a setpoint deceleration specification generated on the part of the driver by a brake pedal. The secondary brake regulation system has a secondary control unit independent of the primary control unit and one electromechanical secondary actuator, independent of the primary actuator, per vehicle wheel.

A braking system in an at least partially autonomous vehicle, having one vehicle wheel brake per vehicle wheel and having a primary brake regulation system and a redundant secondary brake regulation system. One hydraulic actuator for actuating the vehicle brake is provided per vehicle wheel in a first vehicle axle which actuator is assigned to both the primary brake regulation system and also the secondary brake regulation system. One electromechanical primary actuator per vehicle wheel is assigned to the primary brake regulation system in the second vehicle axle and one electromechanical secondary actuator is assigned to the secondary brake regulation system.

A brake pad state estimation device estimates a brake pad state including at least one of a wear volume and a temperature of a brake pad of a vehicle. The brake pad state estimation device acquires sensor detection information including a vehicle speed and a brake pressure, and calculates the brake pad state based on the sensor detection information during braking of the vehicle. The brake pad state estimation device variably sets a sampling period for acquiring the sensor detection information from a sensor according to a driving environment for the vehicle. The sampling period in a case where the wear volume or the temperature of the brake pad is expected to be lower is set to be longer than the sampling period in a case where the wear volume or the temperature of the brake pad is expected to be higher.

A sensor assembly includes control devices with evaluation and control units, and multiple sensor elements which are each assigned to a brakeable vehicle wheel and one of the evaluation and control units designed to detect a physical variable of the associated wheel and to output same as an output signal directly to the associated evaluation and control unit, wherein the control devices are each designed to carry out a braking function of the vehicle based on the detected movement-dependent physical variables of the vehicle wheels, wherein the individual evaluation and control units are designed to output the received output signal to a respective evaluation and control unit of another control device, such that the individual evaluation and control units each receive the output signals from at least two sensor elements, which are assigned to evaluation and control units of different control devices, and prepare same for evaluation.