The disclosure relates to a sensor assembly for a vehicle, comprising a sensor element for detecting a measurement variable and at least two control devices, each having a measuring circuit and a power source. A first connection of the sensor element is connected to the power source of a first control device. A second connection of the sensor element is connected to a ground connection via a measuring circuit of a second control device. The measuring circuit of the first control device evaluates sensor current detected in a high side path of the sensor element. The measuring circuit of the second control device evaluates sensor current detected in a low side path of the sensor element. A first emergency protective circuit provides an alternative low side path for the sensor element and receives the sensor current if the voltage drop reaches a predefined breakover voltage value.

The present disclosure relates to a wheel speed sensor system (1), comprising: one or more first wheel speed sensors (2a, 2b), a first application specific integrated circuit (ASIC) (4) configured to receive one or more first wheel speed signals from the one or more first wheel speed sensors (2a, 2b) and to convert the one or more first wheel speed signals to first wheel speed data, and a first electronic control unit (ECU) (6) configured to receive the first wheel speed data from the first ASIC (4) via a data link (8) between the first ECU (6) and the first ASIC (4); and one or more second wheel speed sensors (3a, 3b), a second ASIC (5) configured to receive one or more second wheel speed signals from the one or more second wheel speed sensors (3a, 3b) and to convert the one or more second wheel speed signals to second wheel speed data, and a second ECU (7) configured to receive the second wheel speed data from the second ASIC (5) via a data link (9) between the second ECU (7) and the second ASIC (5). The first ECU (6) is further configured to receive the second wheel speed data from the second ASIC (5) via a data link (13) between the first ECU (6) and the second ASIC (5), and the second ECU (7) is further configured to receive the first wheel speed data from the first ASIC (4) via a data link (14) between the second ECU (7) and the first ASIC (4). The present disclosure further relates to a vehicle including said wheel speed sensor system and to a method of processing wheel speed signals.

An installation system for an associated housing includes a sensor and a tool. The sensor includes: a barrel portion, a sensing end of the barrel portion, a non-sensing end of the barrel portion, an over-mold portion at the non-sensing end, and a wire extending from the non-sensing end. The tool includes a handle and an applicator secured to the handle. The applicator includes a first applicator portion, a second applicator portion, and a channel. When the over-mold portion of the sensor is proximate to a channel opening and the channel opening is blindly inserted into the associated housing opening, a force applied to the handle along an angle relative to the longitudinal axis of the handle frictionally seats the sensor in the associated housing.

A vehicle control apparatus includes a first ECU electrically connected to a wheel speed sensor and a second ECU electrically connected to the wheel speed sensor.

An apparatus for measuring a speed of a vehicle having an in-wheel motor may include: a transmission gear configured to be rotated by power transmitted from the in-wheel motor, and including a mounting groove formed along a circumferential direction; a measurement target having magnetic force and mounted in the mounting groove; and a speed sensor installed at a position spaced apart from the measurement target and configured to measure rotation of the measurement target part.

A wheel head monitoring unit includes a first sensor unit, a second sensor unit and an evaluation unit, wherein the first sensor unit detects and/or is configured to detect at least a first measured value of a first wheel head, wherein the second sensor unit detects and/or is configured to detect a second measured value of a second wheel head, wherein the evaluation unit is configured to compare the first measured value with the second measured value and/or the first measured value with a predicted first measured value and/or time derivatives or integrations thereof, wherein the evaluation unit is configured in particular to output and/or store a signal if the difference of the first measured value from the second measured value and/or of the first measured value from the predicted first measured value exceeds a threshold value.

A hydraulic motor vehicle brake system is specified with a device for generating a hydraulic fluid pressure. The device comprises an electrically controllable actuator and a piston in a pressure chamber, which is movable by means of the electrically controllable actuator for changing a hydraulic fluid pressure in the pressure chamber. The brake system also comprises a wheel brake pressure control device with a reservoir for the storage of hydraulic fluid discharged from a motor vehicle wheel brake in a pressure reduction phase, wherein the reservoir is fluidically coupled to the pressure chamber. A control system of the brake system is designed to output a control signal for the actuator in the event of a detected loss of function of the control device and in the event of a detected critical filling volume of the reservoir with hydraulic fluid during operation of the control device, which causes the piston to be driven back for pressure reduction in the pressure chamber with suction of hydraulic fluid from the reservoir.

An anti-lock sensor ring may have a flattened exciting portion having a retention mechanism projecting from a ring radial edge. The retention mechanism may have cantilever spring retention clips elastically deformable to snap on a disc brake band retention seat. The mechanism may also have a cantilever support portion disposed side by side to and spaced apart from the cantilever spring retention clips. Each of the cantilever spring retention clips may have a retention surface and the cantilever support portion with a support surface. When the anti-lock sensor ring is dismounted from a disc brake band, the plane defined by the retention surface and the plane defined by the support surface are facing each other in order to create opposing gripping elements.

The present invention relates to a brake control device and a brake control method for a vehicle comprising a plurality of brakes which are respectively installed on wheels, the brake control device comprising an auto leveling sensor which senses a load state of the vehicle according to a change in an angle; a control unit which calculates a correction value according to the load state of the vehicle sensed by the auto leveling sensor; and an electronic brake booster which corrects a predetermined braking power set according to a brake pedal force with the calculated correction value so that the braking operation of each brake is made.

A parking brake fail safety control system and method for a vehicle having an electric-axle, may enable safe parking braking on a level ground, a slope, etc. By controlling the torque from a first motor configured for a rear wheel-first electric-axle and the torque from a second motor configured for a rear wheel-second electric-axle to have the same magnitude in opposite directions and by increasing/decreasing the torque from the first motor and the torque from the second motor, depending on a change of wheel speed when a parking brake fails.