Abstract: A brake fluid pressure control device for vehicles is provided capable of adjusting with a simple control a brake fluid pressure applied to a wheel brake. The control device includes for each system of an X-pipe arrangement: a cut valve as a linear solenoid valve provided to a first fluid pressure path; a pump capable of pressurizing brake fluid on a side toward the wheel brakes than the cut valve on the first fluid pressure path; and a control valve provided on the second fluid pressure path. The control device further includes: a target fluid pressure setting portion for setting a target fluid pressure for each of the wheel brake; and a valve actuating portion for drive-controlling the cut valve and the control valve, based on the target fluid pressure.

Abstract: A brake control apparatus includes a braking force generating section and a control unit. The braking force generating section generates braking forces at wheels of a vehicle.

Abstract: In order to achieve a good brake feeling, a brake control system includes a master cylinder which discharges pressurized operating fluid according to an operating amount of a brake operating member by a driver, a stroke simulator which is connected to the master cylinder and creates a reaction force with respect to that operation according to the operating amount of the brake operating member, and a control portion which calculates a target deceleration using hydraulic pressure in the stroke simulator. The brake control system is also provided with a master cylinder pressure sensor that measures the hydraulic pressure in the master cylinder. The control portion may also calculate the target deceleration using an estimated value of the hydraulic pressure in the stroke simulator calculated based on the measured value from the master cylinder pressure sensor.

Abstract: A brake control apparatus includes a master cylinder, wheel cylinders provided for each vehicle wheel, first and second hydraulic actuators provided separately from the master cylinder and adjusting a hydraulic pressure of the wheel cylinder. The first and second hydraulic actuators respectively have first and second hydraulic pressure sources and each have a wheel cylinder system. The first hydraulic actuator adjusts the hydraulic pressure of the wheel cylinder belonging to the one wheel cylinder system between the wheel cylinders by the first hydraulic pressure source. The second hydraulic actuator adjusts the hydraulic pressure of the wheel cylinder belonging to the other wheel cylinder system than the above wheel cylinder system by the second hydraulic pressure source.

Abstract: A vehicle stabilizing device for setting or modifying brake pressures in the wheel brakes of a braking system with diagonally divided braking circuits. To improve a stabilization of the vehicle in the case of understeering by an additional delay, a device for determining a understeering drive condition, a controller for calculating a desired speed or deceleration, and derived therefrom a deceleration braking force in accordance with the understeering drive condition, a braking force control which in the wheel brakes of the front axle sets a differential braking force between the wheel brakes, which corrects the understeering drive condition, in accordance with the deceleration control braking force are provided.

Abstract: A brake control system includes an ECU having an estimate part which is so constructed as to: totalize an influent amount of fluid in a brake actuator in accordance with an output time of a valve opening drive signal of a control signal and a supply amount per unit time of fluid in a pressure control valve; estimate an amount of fluid in the brake actuator in accordance with the influent amount as totalized; estimate a value of the fluid pressure within the brake actuator in accordance with the amount of fluid as estimated; and carry out correction for obtaining a supply amount of fluid in the brake actuator when a time of retaining operation performed by the control signal is smaller than a predetermined value, correction being performed by adding a correction value corresponding to the time to the output time of the valve opening drive signal of the control signal.

Abstract: A method and an apparatus for controlling a drive unit, in which, when drivetrain oscillations are present, a reduction of the torque takes place until they have decayed. In addition, the torque value at which the oscillations occurred is stored. If the torque exceeds that value, a limitation of the rise in the torque is accomplished.

Abstract: A sensor system is provided in which a digital absolute value of the particular position of a stationary part (stator) with respect to a part moving relative to it (rotor) is created, which is transferred in serial transmission to an evaluation circuitry, whereby transfer of the serial absolute value is induced each time by an external signal. In order to increase the resolution of the encoder, the change in absolute value is recorded each time in the sensor and finest interpolation is undertaken beginning each time from the time of the change. Finally, the absolute value is amended by the accumulated result of finest interpolation when interrogated by the external signal.

Abstract: The parking brakes on a truck or other vehicle having plural axles are applied such that at least one wheel at a first end of a first axle receives a parking brake force without applying a parking brake force to any wheel at the opposite end of the first axle. In addition, at least one wheel at a second end of a second axle, the second end of the second axle being opposite to the first end of the first axle, receives a parking brake force. Desirably, any wheels at the opposite end of the second axle from the second end of the second axle are not the recipient of a parking brake force such that diagonally disposed parking brake forces are applied upon activation of the vehicle parking brakes. The first axle in one example is forwardly of the second axle and the first end of the first axle may be at the longitudinal side of the vehicle which is the heaviest.

Abstract: A braking apparatus for vehicles BU, in which plurality systems of individually separated brake fluid pressure passages BC(A), BC(B) are arranged, and each passage is provided with at least one brake fluid pressure retaining means RU(A), RU(B) for continuously retaining brake fluid pressure within a wheel cylinder WC(A), WC(B) arranged in the brake fluid pressure passage after a depression of a brake pedal BP is released and for releasing the retained brake fluid pressure in response to an increase of a starting driving force of the vehicle, wherein the release of the retained brake fluid pressure is carried out in a time differential manner at each brake fluid pressure retaining means.

Abstract: A target wheel cylinder pressure for each wheel is calculated according to an amount of braking operation performed by a vehicle operator. When anti-skid control is required, the wheel cylinder pressure is controlled to be equal to the target wheel cylinder pressure for reducing the brake slip of the wheel. When one of the rear-left and the rear-right wheels is anti-skid controlled, the target wheel cylinder pressure for the other wheel for which the anti-skid control is not performed is set to the same value as the target wheel cylinder pressure for the wheel for which the anti-skid control is performed. Linear valves are controlled based on the target wheel cylinder pressure, controlling the wheel cylinder pressures for the rear-left and the rear-right wheels to have substantially the same value.

Abstract: A brake fluid pressure retaining unit for a vehicle comprises a solenoid valve SV arranged in a brake fluid passage FP between a master cylinder MC and a wheel cylinder WC so as to shut off or communicate the brake fluid passage FP. In the case that a transmission of the vehicle is shifted to a driving position, the solenoid valve SV is switched to a shut-off position when the vehicle stops with a brake pedal BP depressed. The solenoid valve SV is switched to a communicating position when driving force is exerted on the vehicle. Brake fluid pressure is retained within the wheel cylinder WC when the solenoid valve SV is in the shut-off position. The brake fluid pressure within the wheel cylinder is retained after releasing the brake pedal so that braking force continues to act on the vehicle.

Abstract: A braking-force control system and method is provided for a road vehicle having an electrically controllable four-circuit brake system. The braking forces generated by the individual wheel brakes can be adjusted in a wheel-specific way. Adjustment devices on a chassis vary the normal forces acting on the vehicle wheels, with at least one normal-force adjustment device being provided per vehicle wheel. The adjustment devices are configured so that, for the most part, the weight of the vehicle can be supported on one of the front wheels and on the rear wheel of the vehicle which is arranged diagonally opposite the latter. The braking force generated by a front-wheel brake and the rear-wheel brake which lies opposite the latter viewed along the diagonal of the vehicle, corresponds overall to the vehicle weight multiplied by a maximum coefficient of friction which is effective between the carriageway and the braked wheels.

Abstract: A braking system for braking a motor vehicle by the front and rear brakes of the vehicle's front and rear wheels, respectively, including a distribution control device for controlling a distribution of front and rear wheel braking force produced by the respective front and rear brakes, according to a selected one of a first and a second distribution pattern, each of which represents the front and rear wheel braking forces in relation to each other wherein the rear wheel braking force defined by the second distribution pattern is larger than that defined by the first distribution pattern at least when the front and rear wheel braking forces are smaller than respective predetermined values. The selection of the two distribution patterns may be dependent on vehicle load.

Abstract: A method of monitoring a brake system which is equipped with anti-lock control (ABS) and a system for electronic control of brake force distribution (EBV). The system includes two brake circuits in a black/white brake circuit split-up, the EBV function or control is principally released only when the vehicle deceleration exceeds a predetermined limit value (GWN). To identify a front-axle brake circuit failure, acceleration criteria, i.e., criteria responsive to the acceleration behavior of the vehicle wheels, are predetermined and monitored. Further, slip range monitoring in conjunction with acceleration range monitoring is performed.

Abstract: Anti-lock brake system including a controller for controlling at least one solenoid-operated valve device for controlling braking pressures in a rear right and a rear left brake cylinder such that if two different control modes which would be selected for the rear brake cylinders independently of each other include pressure decrease mode, this pressure decrease mode is determined as effective control mode for one of the rear brake cylinders, while one of control modes which is not selected for the other rear brake cylinder and which causes lower braking pressure in the other rear brake cylinder than when the normally selected mode is determined as the effective control mode is determined as the effective control mode for that other rear brake cylinder, and wherein the normally selected different control modes are determined as the effective control modes for the rear brake cylinders if the normally selected control modes consist of pressure hold mode selected for one of the rear brake cylinders and pressure i

Abstract: A turn control apparatus for a vehicle is applied to a four-wheeled automobile. When the vehicle turns while being braked, the outside front and inside rear wheels viewed in the vehicle turn direction are selected from the vehicle wheels as two target wheels to be controlled. The braking force on one target wheel to be controlled is increased in accordance with the turning condition of vehicle, while that of the other target wheel to be controlled is decreased.

Abstract: A method is provided to correct the wheel speed for a vehicle equipped with a mini tire as the spare tire plus a nonvolatile memory device. The presence or absence of a mounted mini tire is detected while the vehicle is moving, and if a mini tire is mounted, the mounting information is stored in the nonvolatile memory. If an antilock control is triggered after the vehicle is restarted and in motion, a correction is made for the mini tire using the mounting information stored in the nonvolatile memory.

Abstract: An anti-skid control system for an automotive vehicle, comprises a plurality of actuators each associated with one of front-left, front-right, rear-left and rear-right road wheels, for adjusting braking forces applied to the road wheels independently of each other, sensors for detecting wheel speeds of the road wheels to generate wheel-speed indicative signals, and a controller for controlling the actuators in response to the wheel-speed indicative signals. The controller selects a lower value of the wheel-speed indicative signal values of a controlled rear wheel, subjected to a braking-force control, and its diagonal front wheel located on the vehicle diagonally to the controlled rear wheel, and controls the actuator associated with the controlled rear wheel in accordance with the lower value, during braking-force control for the controlled rear wheel.

Abstract: An antilock brake control device installed across two independent brake circuits in which brake lines connect the master cylinder to the wheel cylinders of wheel brakes of diagonal front and rear wheels, in which for each brake circuit, a first brake line 21 connects the master cylinder to the wheel cylinders 141, 144 of the front wheels, first selector valve 24 is installed in each the first brake line 21, second brake line 22 connects the wheel cylinders 142, 143 of the rear wheels and the first brake line 21, second selector valve 25 is installed in the second brake line, reflux channel 23 connects the first brake line and the second brake line, and a hydraulic pump 26 is installed in the reflux line.

Abstract: A vehicle turn control apparatus has an electronic control unit which controls the operation of hydraulic pressure control valves for adjusting a fluid pressure generated by a pump during the turn control which is carried out in accordance with a required control variable for yaw moment control calculated based on either or both of the operating state and behavior of a vehicle. Adjusted fluid pressures are supplied to the wheel brakes concerned, so that a braking force difference is produced between these wheels to control a yawing motion of the vehicle. When the brake pedal is operated during the turn control, the electronic control unit stops the operation of the pump unless the fluid pressure for turn control is so adjusted as to be increased, to thereby decrease the fluid pressure to suppress the brake pedal push-back action of the fluid pressure.

Abstract: A hydraulic braking system for an automobile vehicle includes a first brake pressure control circuit and a second brake pressure control circuit, each of which includes a front solenoid valve disposed between one of the front wheel brakes and one of pressure chambers of a tandem master cylinder, a rear solenoid valve disposed between one of the rear wheel brakes and the pressure chamber, a hydraulic pump whose outlet communicates with a conduit located between the solenoid valves and the pressure chamber, a change over valve disposed between the solenoid valves and the pressure chamber, the change over valve being positionable in a first position which connects the solenoid valves to the pressure chamber and a second position which connects the inlet of the hydraulic pump to the pressure chamber, a front orifice disposed between the front wheel brake and the inlet of the hydraulic pump, a rear orifice disposed between the rear wheel brake and the inlet of the hydraulic pump, and a check valve disposed between

Abstract: A fluid pressure control method of an anti-skid control apparatus for a vehicle, wherein the anti-skid control apparatus includes a tandem master cylinder, wheel cylinders of wheels, wheel speed sensors associated with the respective wheels, a control unit receiving the outputs of the wheel speed sensors for judging skid conditions of the respective wheels, and fluid pressure control valves arranged between the tandem master cylinder and the respective wheels, which receive instructions from the control unit for controlling brake fluid pressures of the respective wheels. The control unit supplies brake-decreasing instructions and brake-holding instructions independently to the ones of the fluid-pressure control valves for the front wheels, controls the others of the fluid-pressure control valves for the rear wheels by the diagonal "Select Low" between the skid conditions of the respective rear wheels and respective front wheels diagonally connected to the respective rear wheels.

Abstract: An ABS skid detection protection system for a wheeled vehicle detects a predetermined level of deceleration at a wheel; detects, memorizers and holds for a prescribed period the wheel speed value at that predetermined deceleration level; detects whether the angular acceleration of the monitored wheel first falls below and then re-establishes the predetermined deceleration level within the prescribed level; and corrects the memorizsed value of wheel speed by subtracting from it an amount equal to the vehicle deceleration multiplied by either the elapsed time since the wheel speed value was memorized or the elapsed time since the initiation of a short-duration pulse by which the actuating pressure applied to a brake can be temporarily dumped upon detection of the predetermined level of deceleration of the wheel.

Abstract: A brake pressure control apparatus for regulating a brake pressure for braking a wheel of a motor vehicle, including a device for obtaining a rotating speed of the wheel, a pressure regulator for regulating the brake pressure, on the basis of the rotary speed of the wheel, a running speed of the vehicle and an optimum slip amount of the wheel, a device for estimating a future speed of the wheel, on the basis of values of the wheel speed which have been obtained by the wheel speed obtaining device, and a device for reflecting the future speed of the wheel on the determination of a point of time at which the wheel brake pressure is regulated by the pressure regulator.

Abstract: An antiskid control device is disclosed. This device is capable of controlling the braking of a vehicle such as an automobile so as to obtain a reduced stopping distance while simultaneously making it possible to maintain the stability and steerability of the vehicle. The device is comprised of two pressure-mediating circuits provided in two lines leading from a master cylinder. Each circuit is connected first to a front brake, then to the diagonal rear brake and then returns to the reservoir. An inlet valve is interposed in each pressure-mediating circuit between the master cylinder and the front brake. An outlet valve is interposed in the return of each pressure-mediating circuit after the rear brake. The inlet and outlet valves are controlled based on a computation analysis of wheel speed.