A vehicle travel control device includes a surrounding environment recognition device that acquires surrounding environment information on a surrounding environment of a vehicle; a vehicle state recognition device that acquires state information on a state of the vehicle; and a travel control unit that performs travel control of the vehicle, based on the surrounding environment information or the state information. When the vehicle state recognition device detects a slip of at least one drive wheel of the vehicle, the vehicle travel control device executes brake LSD control for braking the at least one drive wheel. When the surrounding environment recognition device recognizes snow on a traveling road of the vehicle and a snow melting area and a snow non-melting area ahead, the travel control unit switches an operation mode of the brake LSD control from a first mode to a second mode.

Provided is a vehicle control apparatus and vehicle control method. The vehicle control apparatus and vehicle control method includes a sensing unit configured to sense at least one of a vehicle speed value and a wheel speed value, a transmission information output device configured to output transmission information, and a control unit configured to determine whether a vehicle having been in a stationary state is moving using the sensed at least one of the vehicle speed value and the wheel speed value, determine whether the output transmission information corresponds to a neutral state when the vehicle having been in a stationary state is moving, and transmit an electrical parking brake (EPB) engagement command to an EPB device such that EPB automatic engagement is performed by the EPB device when the transmission information corresponds to a neutral state.

A system for use in a vehicle, the system comprising sensors located on the front and back fascia of the vehicle; processors coupled to the sensors; and a memory including instructions, which when executed by the processors, cause the processors to perform a method. The method comprising detecting a change in first acoustic impedance at a first sensor while detecting a change in second acoustic impedance at a second sensor. In accordance with a determination that the change in first acoustic impedance and the second acoustic impedance are between a threshold range for at least a threshold period of time, the method executing a precautionary measure. In accordance with a determination that the change in first acoustic impedance and the change in second acoustic impedance are not between the threshold range for at least the threshold period of time, the method forgoing executing the precautionary measure.

Disclosed herein is an electric brake system including: a hydraulic feeder configured to move a piston forward or backward according to a pedal effort from a brake pedal to discharge oil; a motor position sensor configured to measure a position of the piston; and a controller configured to control, when an Anti-lock Brake System (ABS) control starts, a change in direction of the piston based on predicted displacement information of the piston while the ABS control is performed such that the piston is at a target position at target vehicle speed.

Managing a brake system of a vehicle includes collecting sensor data from one or more sensors in or around the vehicle, calculating brake effectiveness values based on the sensor data, calibrating the brake effectiveness values based on environmental context data associated with the vehicle, accumulating the calibrated brake effectiveness values as a dataset, generating a prediction curve or formula based the dataset, and scheduling a maintenance alarm for the brake system based on the brake effectiveness values.

This emergency evacuation device includes: an emergency stop requesting unit which detects abnormality from obstacle information acquired from an obstacle information acquisition unit and a roadside information acquisition unit and an occupant physiological state acquired from an occupant state information acquisition unit, and outputs an emergency stop request; a movement permission determination unit which determines movement permission for a mobile object, using the emergency stop request; a movement permission cancellation unit which determines whether or not to cancel movement permission for the mobile object, using a control state of the mobile object acquired from a mobile object state information acquisition unit; and a mobile object control unit which controls movement of the mobile object, using information about movement permission and cancellation of the movement permission. When movement is permitted and the movement permission is not cancelled, the mobile object is allowed to be moved within a certain limited range.

Brake force distribution during an anti-lock braking (ABS) event in a vehicle using an electronic parking brake (EPB) force to supplement a primary brake pressure is described. In an example, an vehicle control system of the vehicle can detect when an ABS event is going to occur and a primary brake pressure can be applied to a rotor at a wheel of the vehicle using a primary brake system. An EPB brake pressure can be applied to the rotor using an EPB brake system to reduce the pressure required to be applied by the primary brake pressure. As a result, the primary brake system may be sized to accommodate normal braking and to accommodate ABS braking when supplemented by the EPB system.

In a method for determining conditions of a road and a tire, a measurement of a sound signal produced by the tire running on the road during a timeframe is recorded, and a spectral density of a power of the sound signal over a frequency interval is determined. The frequency interval is segmented into frequency bands, and each frequency band is associated with a representative data element representing a mean acoustic power measured in the frequency band. The representative data elements obtained from the measurement form variables of a vector associated with the measurement. A road condition and a tire condition are determined via a discriminant analysis of the representative data elements using a learning base. Each representative data element is obtained by finding a ratio between a mean acoustic power measured in a corresponding frequency band and a total acoustic power measured over an entirety of the frequency interval.

An emergency braking control method for a vehicle may include: controlling, by a controller, an ambient information detector to take an image of surroundings of the road on which a vehicle is traveling; controlling, by the controller, a camera recognition fail state detector to analyze the image taken by the ambient information detector, and to determine a severity level of a temporary camera recognition fail state; and controlling, by the controller, an operation of an emergency braking apparatus or setting a control strategy according to the severity level of the temporary camera recognition fail state.

Methods and systems for evaluating underground road conditions using accelerometers. One system includes an electronic processor that receives sensor data from an accelerometer and location data of a mining machine operating within a mining environment. The electronic processor determines, based on the sensor data, a first data point when acceleration in a first direction exceeds a predetermined first threshold based on the sensor data, and determines a second data point when acceleration in a second direction opposite the first direction exceeds a predetermined second threshold. The electronic processor also determines a location of a road condition associated with the first data point and the second data point based on the location data and takes at least one automatic action to correct the road condition.