A system and method are provided for efficiently estimating vehicle tire wear. Vehicle kinetics (first) data are provided via one or more sensors associated with the vehicle and/or at least one associated tire. The vehicle kinetics data are locally processed to compress or otherwise generate second data as a reduced subset thereof, said second data representative of the first data and comprising any one or more predetermined wear-specific features extracted therefrom. The second data are selectively transmitted via a communications network to a remote computing system, which processes the second data to estimate a wear characteristic for the at least one tire. Alternatively, the second data processed to generate third data as a reconstruction of the first data, and the third data and the any one or more extracted features are processed to estimate a wear characteristic for the at least one tire.

An electric brake system for a vehicle is provided, wherein the vehicle has a brake value encoder, at least one first axle having at least two wheels and a second axle having at least two wheels. A first axle modulator is associated with the first axle. A second axle modulator is associated with the second axle. A single central control unit is further provided, which generates and outputs a first brake signal for the first axle modulator and a second brake signal for the second axle modulator as a function of a brake signal from the brake value encoder or as a function of a further brake request. The first and second axle modulator are each configured to decelerate the wheels of the first and second axle as a function of the first and second brake signal from the central control unit.

An in-vehicle device, an in-vehicle system, and a method for hands-free driving assistance are disclosed. The in-vehicle device includes: an obtaining module configured to obtain a hands-free assistance status signal from a hands-free driving assistance system of a vehicle and a steering assistance status signal from a steering system of the vehicle; an ascertainment module configured to ascertain, based on the hands-free assistance status signal, whether a hands-free driving assistance function of the vehicle is activated, and ascertain, based on the steering assistance status signal, whether a fault occurs in the steering system; a trigger module configured to trigger a brake jerk in a braking system of the vehicle if it is ascertained that the hands-free driving assistance function has been activated and that the fault occurs in the steering system; and a determination module configured to calculate, in real time and based on a mass of the vehicle, a duration that the brake jerk has lasted, and a rate of change in a longitudinal deceleration of the vehicle, a braking force for the brake jerk, for use in dynamic pressure build-up in the braking system during the brake jerk.

Methods of assessing driver behavior include monitoring vehicle systems and driver monitoring systems to accommodate for a driver's slow reaction time, attention lapse and/or alertness. When it is determined that a driver is drowsy, for example, the response system may modify the operation of one or more vehicle systems. The systems that may be modified include: visual devices, audio devices, tactile devices, antilock brake systems, automatic brake prefill systems, brake assist systems, auto cruise control systems, electronic stability control systems, collision warning systems, lane keep assist systems, blind spot indicator systems, electronic pretensioning systems and climate control systems.

A vehicle is provided. The vehicle includes a plurality of controllers and a driver. Each controller is configured to receive one or more braking signals. Each controller is also configured to generate one or more braking commands in correspondence to the one or more braking signals. The driver is configured to perform a voting operation on the one or more braking commands to determine whether to generate a driving signal to at least one brake.

A method for controlling braking force of brake may include step of controlling braking force for each vehicle speed period to make braking force different in accordance with vehicle speed period by increasing an early hydraulic pressure of brake system for obtaining braking force in low-speed period to be lower than in middle-speed period, by increasing hydraulic pressure in middle-speed period to be higher than in low-speed period but to be lower than in high-speed period, and by increasing hydraulic pressure in high-speed period to be higher than in middle-speed period, and step of controlling braking force for each vehicle speed which sets correction coefficient that is function of vehicle speed while braking to make braking force different for each vehicle speed, and brakes vehicle with braking force according to current vehicle speed determined using set correction coefficient , wherein braking force is controlled by one of steps.

The invention relates to a method for carrying out one or more collision-avoiding measures of a vehicle, in particular a motor vehicle. In the method, the positions of static and dynamic objects 11 are detected in a step 10, and one or more trajectories 21 which avoid collisions with the detected objects 11 are determined for the vehicle in a step 20. According to the invention, a danger value 23 for the determined trajectory 21 or for each of the determined trajectories 21, is determined continuously or periodically in a further step 22. This danger value 23 constitutes a measure for the forces which act on the vehicle when the respective trajectory 21 is passed through. The collision-avoiding measures are then carried out in a step 27 if the determined danger value 23, or the determined danger values 23, is/are above a selected or predefined threshold value 26. In addition, the invention relates to a device for carrying out the method.

Described herein is a vehicle system configured to identify and mitigate inappropriate driving behavior. In some embodiments, the vehicle system may receive input information from one or more input sensors. The vehicle system may identify driving behaviors related to a vehicle from the received input. The vehicle system may determine whether the driving behaviors are inappropriate in light of one or more conditions affecting the vehicle. Upon identifying inappropriate behavior, the vehicle system may generate a set of corrective actions capable of being executed to mitigate the inappropriate driving behavior.

A parking assist device includes an electronic control unit. The electronic control unit is configured to: perform parking assist of a vehicle to automatically park the vehicle at a target position while restricting a vehicle speed to an upper limit or lower in accordance with an instruction of a user who is outside the vehicle; determine whether or not the vehicle moves on a road surface having a downhill grade along a travelling direction of the vehicle by the parking assist; and set the upper limit in the case where the vehicle is determined to move on the road surface having a downhill grade to be smaller than the upper limit in the case where the vehicle is not determined to move on the road surface having a downhill grade.

A control unit of an assist controller for a vehicle estimates the visibility of a driver, calculates a visibility degradation ratio as a temporal change amount of the visibility, compares the visibility degradation ratio with a warning threshold that has been set in advance according to a vehicle speed, determines whether to warn the driver with a warning device, compares the visibility degradation ratio with a control characteristic change threshold that has been set in advance according to a vehicle speed, determines changes in control characteristics of the ABS function, skid preventing control function, and brake assist control function, compares the visibility degradation ratio with a deceleration control actuation threshold that has been set in advance according to a vehicle speed, and determines whether to execute automatic braking.