A system for controlling driving of a vehicle, includes one or more processors configured to: identify objects, including another vehicle, around a host vehicle and collect object information about the objects; collect road states information of road states in a traveling direction of the host vehicle; check the object information around the host vehicle and the road states information to identify a safety zone to which the host vehicle is able to travel; and control the host vehicle to travel to the safety zone when the other vehicle is detected in the traveling direction of the host vehicle in a state in which the host vehicle has entered a curved road.

A system for controlling driving of a vehicle, includes one or more processors configured to collect information about another vehicle identified in a traveling direction of a host vehicle, check whether a road in the traveling direction of the host vehicle is a straight road or a curved road, and control, in response to the check, the host vehicle to travel in a direction in which the host vehicle avoids the other vehicle when the host vehicle enters a curved section of the road and the other vehicle is detected in the traveling direction of the host vehicle, and perform braking of the host vehicle such that a traveling speed of the host vehicle is reduced.

An eco-friendly vehicle and a hill descent control method therefor are provided to enable stable driving on a downhill road. The method includes detecting a downhill road inclination based on a request for hill descent control and determining an average inclination and an inclination variation width based on the recognized downhill road inclination. First braking force of a main braking source from a motor and a hydraulic pressure brake system based on the average inclination and the inclination variation width, and second braking force of an auxiliary braking source from the motor and the hydraulic pressure brake system for each driving wheel based on a target speed set with respect to the hill descent control and a speed of each driving wheel are determined. The first and second braking force are output by a corresponding braking source from the motor and the hydraulic pressure brake system.

A forward collision avoidance system of a vehicle includes a detector configured to detect an obstacle positioned ahead in a traveling direction of the vehicle; a processor; a memory coupled to the processor and storing an algorithm that, when executed by the processor, causes the processor to: estimate a gradient of a road on which the vehicle is traveling, and determine a braking strategy of the vehicle based on the estimated gradient, a position of the detected obstacle and a velocity of the vehicle; and a controller configured to control braking of the vehicle based on the braking strategy of the vehicle determined by the processor.

An apparatus comprising an interface, a memory and a processor. The interface may be configured to receive sensor data samples during operation of a vehicle. The memory may be configured to store the sensor data samples over a number of points in time. The processor may be configured to analyze the sensor data samples stored in the memory to detect a pattern. The processor may be configured to manage an application of brakes of the vehicle in response to the pattern.

A system and method for classifying an actuation of an electric parking brake of a vehicle. In one example, the system includes a sensor configured to sense a vehicle parameter, an output device, a data store including an electric parking brake usage profile, and an electronic controller configured to receive the electric parking brake usage profile, receive the vehicle parameter from the sensor, detect an actuation of the electric parking brake, and in response to detecting an actuation of the electric parking brake: determine a reason for the actuation of the electric parking brake, determine an attribute of the vehicle based on the vehicle parameter, classify the actuation of the electric parking brake based on at least one selected from the group consisting of a numerical value of the attribute and the reason for the actuation of the electric parking brake, update the electric parking brake usage profile based on the classification of the actuation of the electric parking brake, and output the updated parking brake usage profile to the output device.

A device and a method for controlling collision avoidance of a trailer vehicle in platooning include a jackknife induction determination module or operation that determines whether to execute jackknife induction control in a leading vehicle when an emergency braking situation occurs during platooning of the trailer vehicle. The device and method also include a jackknife induction control module or operation that provides an additional braking distance of a following vehicle at the rear of a tractor by inducing pivoting of a trailer while controlling the tractor and trailer of the leading vehicle, respectively, to allow a jackknife phenomenon to occur. Stability of the platooning is improved by reducing a possibility of the occurrence of a collision accident by the following vehicle even during emergency braking.

A system, method, and apparatus includes management of coasting during operation of a vehicle. Speed of a vehicle is monitored during a coasting event and is compared against a threshold to determine whether to remain coasting or re-engage an engine to a driveline. If instantaneous speed exceeds the threshold, predicted speed can be used to determine whether to permit short duration excursions, or to re-engage the engine to the driveline. These techniques can be used whether the vehicle is slowing down below a threshold or speeding up above a threshold.

An apparatus comprising an interface, a memory and a processor. The interface may be configured to receive sensor data samples during operation of a vehicle. The memory may be configured to store the sensor data samples over a number of points in time. The processor may be configured to analyze the sensor data samples stored in the memory to detect a pattern. The processor may be configured to manage an application of brakes of the vehicle in response to the pattern.

A brake system for a combination vehicle in which a plurality of vehicles are coupled in a line, including: a plurality of brake devices respectively provided for the plurality of vehicles; and a controller configured to control the plurality of brake devices, wherein the controller is configured to control a braking force applied to each of the plurality of vehicles based on a loaded weight or a weight of each of the plurality of vehicles.