Abstract: Disclosed is a brake control apparatus which starts ABS control on the basis of slip ratio speed and which reduces a variation in the slip ratio at the time of start of the ABS control. A brake ECU computes a braking stiffness BS** in a linearly increasing region of a ?-S characteristic, and computes a slip ratio speed reference value dSref**/dt by dividing a changing speed dFxc**/dt of braking force of a wheel by the braking stiffness BS**. The brake ECU computes, as a slip ratio speed threshold, a value ((dSref**/dt)+dSn) by adding a slip ratio speed noise offset value dSn to the slip ratio speed reference value dSref**/dt and starts ABS control when the slip ratio speed dSc**/dt of the wheel exceeds the slip ratio speed threshold.

Abstract: A signal indicating an estimated body deceleration and a deceleration indicated by a detection signal from a G sensor are pass through first and second filters having different filter constants. Based on a resulting difference in response speeds thereof, it is determined whether sudden braking, i.e., quick depression, is being performed. If quick depression is determined, then even if an upper limit of a W/C pressure to rear wheels is set in order to prevent rear wheel locking precedent to front wheel locking, the W/C pressure is increased so as to exceed such an upper limit. Thus, a greater deceleration can be achieved than when the W/C pressure at the set upper limit is generated.

Abstract: A method and apparatus in a vehicular telemetry system and a remote data analysis system for detecting an event and switching a data acquisition mode. Checking a state of a data acquisition mode. If the state is in a filtered data state and if an indicator value is at or above a threshold value, then switch the data acquisition mode to an unfiltered data state and acquire unfiltered data. If the data acquisition mode is in an unfiltered data state and if the indicator value is below the threshold value, switch the data acquisition mode to a filtered data state and acquire filtered data.

Abstract: In deceleration control apparatus and method for an automotive vehicle, a deceleration control is performed on the basis of a turning of the vehicle; and a controlled variable of the deceleration control is decreased when the vehicle is traveling on an outlet of a curved road.

Abstract: A brake system control method for use in a vehicle in which wheel speed normalization factors are iteratively updated, comprising the steps of: monitoring a plurality of wheel speed signals from a plurality of wheel speed sensors; determining for each wheel a wheel acceleration responsive to the wheel speed signal; determining an acceleration dead band for each wheel, wherein the acceleration dead band is proportional to a measure of vehicle acceleration; comparing the wheel acceleration to the dead band; and if the magnitude of the wheel acceleration is greater than the magnitude of the dead band, inhibiting update of the normalization factors.

Abstract: As illustrated in FIG. 1, the wheel accelerations of the respective wheels are calculated from the detected wheel speeds, variations in the wheel accelerations are calculated from these wheel accelerations, the cumulative sums of the variations in the wheel accelerations are calculated from these variations, and the presumptive vehicle deceleration is calculated from the cumulative sums, whereby the vehicle deceleration can be accurately presumed without employing an acceleration sensor or the like. Further, the presumptive vehicle speed is calculated accurately using the presumptive vehicle deceleration. Still further, the slip factors of the respective wheels are calculated from the differences between the presumptive vehicle speed and the wheel speeds so as to perform an antiskid brake control at low cost and at a high precision.

Abstract: A method and system for damping wheel speed oscillation during an anti-lock braking event. The method includes the initial step of sensing the wheel speed and determining a wheel slip based on the sensed wheel speed and a vehicle speed reference. Next, the method continues with the step of determining whether the wheel slip has exceeded a predetermined slip threshold. If the wheel slip has not exceeded a predetermined slip threshold, the method performs normal or unmodified anti-lock brake control. If the wheel slip has exceeded the predetermined slip threshold, the method continues with the step of determining whether an acceleration feedback condition representative of a high mu surface has been satisfied. If an acceleration feedback condition has been satisfied, the method continues with the step of increasing brake pressure applied to the wheel from a steady-state level in a step-wise function during acceleration of the wheel before the wheel speed reaches the vehicle speed reference.

Abstract: An anti-skid control for use in an automotive vehicle is comprised of a brake control device for adjusting braking force of each road-wheel of a vehicle, the brake control device being set to be initiated upon receipt of a condition, a detecting device being set to be initiated upon receipt of a condition, a detecting device for measuring a load applied to the vehicle, and a changing device for less sensitivity of the initiation of the brake control device as the load decreases. Even if an instantaneous decrease of the load occurs due to the vehicle's jumping motion or turning motion, an expected initiation of the brake operation can be prevented.