The present invention provides a sensing apparatus for a vehicle, the apparatus including: a sensing unit that is configured to sense at least one of vehicle speed information, yaw rate information, and steering angle information, and to sense a forward object existing within a sensing distance set in advance; a calculator that is configured to calculate at least one of a driving curvature radius, which is calculated based on the vehicle speed information and the yaw rate information, and a steering angular speed, which is calculated based on the steering angle information; and an adjusting unit that is configured to adjust the sensing distance to be decreased when the driving curvature radius is less than, or equal to, a predetermined curvature radius or when the steering angular speed is less than, or equal to, a predetermined angular speed.

A target acceleration/deceleration setting unit (28) of a vehicle acceleration/deceleration controller (16) sets a target acceleration or deceleration at a location at which a curve starts to be a predetermined maximum deceleration, sets a target acceleration or deceleration at a location at which the curve ends to be a predetermined maximum acceleration, sets a target acceleration or deceleration at a predetermined intermediate location between the location at which the curve starts and the location at which the curve ends to be zero, and sets a target deceleration D (Ld) at a location to which the travelling distance from the location at which the curve starts is Ld and a target acceleration A (La) at a location to which the travelling distance from the predetermined intermediate location is La to satisfy respective predetermined relations.

A vehicle control system includes: a non-inertial sensor arrangement configured to detect a parameter indicative of a radius of turn for the vehicle that is desired by a driver of the vehicle; a speed detection arrangement operable to detect the forward speed of the vehicle; a friction estimation arrangement, configured to provide an estimated value for the coefficient of friction between at least one tire of the vehicle and a surface over which the vehicle is driven; and a processor connected to receive signals from the non-inertial sensor arrangement, the speed detection arrangement and the friction estimation arrangement.

Methods and systems for controlling driving of a vehicle are disclosed, where line system includes one or more processors configured to identify objects, including another vehicle, around a host vehicle and collect object information about the objects, to collect road states information of road states in a traveling direction of the host vehicle, to 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 to 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 method for controlling a vehicle train, having a towing vehicle and at least one trailer vehicle. The towing vehicle includes a continuous deceleration device for performing a continuous deceleration. The method includes the steps: determining a trailer mass of the trailer vehicle in the prevailing vehicle configuration of the vehicle train; determining a towing vehicle trailer mass of the towing vehicle in the prevailing vehicle configuration; determining a mass ratio of the prevailing vehicle configuration based on the trailer mass and the towing vehicle mass; and limiting a maximum permissible continuous deceleration power of the continuous deceleration device based on the mass ratio. A driver assistance system is configured to perform the method. A commercial vehicle includes the driver assistance system. A computer program product is configured to perform the method.

A vehicle control apparatus comprises a sensor that obtains object information on an object that is present in front of a vehicle; a regenerative brake device that applies a regenerative brake force to a wheel; a friction brake device that applies a friction brake force to the wheel; and a control unit that performs a deceleration control to control at least one of the regenerative brake device and the friction brake device, when an execution condition is satisfied, in such a manner that a total of the regenerative brake force and the friction brake force becomes equal to a target brake force. The control unit is configured to make a maximum regenerative brake force smaller when a friction condition is satisfied than when the friction condition is not satisfied. The friction condition is satisfied when it is predicted that the target brake force will become greater than a predetermined force.

A computer system has processing circuitry to handle wheel slip of at least one wheel of a vehicle. The processing circuitry obtains road properties for one or more road segments of a road travelled or to be travelled by the vehicle. The road properties are indicative of a curvature of the one or more road segments. For each of the one or more road segments, a longitudinal slip limit is determined based on the road properties for the respective road segment. The longitudinal slip limit indicates a maximum allowed longitudinal slip for the at least one wheel in the respective road segment.