A collision warning method in relation to vulnerable road users (VRUs), applied in a host vehicle when being driven, obtains a relative lateral distance between a vehicle and a VRU and obtains speed of movement of the VRU in addition to speed and direction of the host vehicle. A warning scenario is determined according to the relative lateral distance and the VRU speed. A warning distance according to the warning scenario and the relative speed is calculated, a relative distance between the host vehicle and the VRU is obtained, and the issue of a corresponding level of a collision warning is determined according to a comparison between the warning distance and the relative distance.

Determining an instantaneous vehicle characteristic (e.g., at least one yaw rate) of an additional vehicle that is in addition to a vehicle being autonomously controlled, and adapting autonomous control of the vehicle based on the determined instantaneous vehicle characteristic of the additional vehicle. For example, autonomous steering, acceleration, and/or deceleration of the vehicle can be adapted based on a determined instantaneous vehicle characteristic of the additional vehicle. In many implementations, the instantaneous vehicle characteristics of the additional vehicle are determined based on data from a phase coherent Light Detection and Ranging (LIDAR) component of the vehicle, such as a phase coherent LIDAR monopulse component and/or a frequency-modulated continuous wave (FMCW) LIDAR component.

A system for autonomously assisting the operation of a host vehicle traveling on a first lane of a roadway includes at least one camera assembly for detecting the presence and speed of a vehicle merging into the first lane. A proximity sensor monitors the distance between the host vehicle and the merging vehicle. A controller electrically is connected to the at least one camera assembly and the proximity sensor and, in response to receiving signals from the at least one camera assembly and the proximity sensor, actuates a steering gear to laterally move the host vehicle from the first lane to a second lane of the roadway to allow the merging vehicle to enter the first lane.

The invention provides a vehicle control system including a vehicle detector that detects a nearby vehicle with respect to an own-vehicle and an automated driving controller that automatically controls at least acceleration/deceleration of the own-vehicle such that the own-vehicle can travel along a route to a destination, wherein the automated driving controller acquires information indicating a position of a specific region in which the number of lanes decreases from map information and sets, if a relative relationship between the own-vehicle and a nearby vehicle detected by the vehicle detector satisfies a predetermined condition when the own-vehicle passes through the acquired specific region, a target speed of the own-vehicle to less than a speed of the nearby vehicle for which the relative relationship satisfies the predetermined condition.

A controller for an adaptive cruise control system having a speed based mode includes an input for receiving a signal indicative of a detected target object, an input for receiving the speed of the host vehicle and control logic. The control logic is capable of transmitting messages to maintain the vehicle at a preset time gap from the target object upon receiving the signal indicative of a target object and transmitting messages to set the vehicle at a predetermined following distance from the target object in response to the speed of the host vehicle being less than or equal to a minimum speed.

A vehicle collision avoidance assist system, including: a forward obstacle detecting device; and a controller including an automatic braking control executing portion to execute an automatic braking control for permitting a brake apparatus to automatically operate and an avoidance control executing portion to execute, in addition to the automatic braking control, an avoidance control for pen fitting a steering apparatus to automatically operate, wherein the avoidance control executing portion is configured such that, when the forward obstacle detecting device detects, as a forward obstacle, a continuous obstacle that continuously extends diagonally forward so as to be inclined with respect to a forwardly extending centerline that forwardly extends from a center of the own vehicle, the avoidance control executing portion executes the avoidance control to enable the own vehicle to avoid the continuous obstacle such that the own vehicle travels along the continuous obstacle.

A driving support ECU includes: a lateral width acquisition unit that acquires from an image a dimension of an object in a lateral direction with respect to an imaging direction of an imaging means as a lateral width; a determination unit that compares the current lateral width with a past lateral width to determine whether the current width is smaller than the past lateral width; and a correction unit that, when the current lateral width is smaller than the past lateral width, corrects right and left end positions of the lateral width based on whichever is smaller, the deviation amount of the right end position of the object or the deviation amount of the left and position of the object.

A roundabout detecting arrangement is disclosed configured to detect presence of a roundabout ahead of a vehicle hosting the arrangement. The arrangement includes a preceding vehicle monitoring unit configured to monitor at least one of a lateral movement and a heading direction of a vehicle preceding the host vehicle, and further configured to generate a first signal representative thereof. The arrangement also includes a processing unit configured to detect presence of the roundabout by processing the first signal. The present disclosure also relates to an adaptive cruise control arrangement and a method of detecting the presence of a roundabout.

A control system has at least one sensor configured to track an orientation of a front wheel of a nearby vehicle and provide data indicative of the orientation. The control system also has a computing device including a processor and a memory. The computing device is configured to receive the data from the at least one sensor, determine a wheel angle parameter of the front wheel of the nearby vehicle based on the data, and generate a control command to change at least one of a direction or an acceleration of the vehicle based on the determined wheel angle parameter.

A vehicle traveling control apparatus of the invention stops a vehicle by causing a braking force applying device to apply a braking force to the vehicle after determining that a driver is under an abnormal state. When a stop of a control for maintaining a vehicle at a stopped state is requested while a shift lever is set at a range other than parking and neutral ranges, the apparatus limits a driving force requested for a driving force supplying device to supply to drive wheels, to a value smaller than a driver's requesting driving force.