Driving support ECU transmits a communication connection request to a help net center HNC when a driver of a vehicle has been determined to be in an abnormal state where the driver loses an ability to drive the vehicle, and when the communication connection to the help net center HNC has been established, the driving support ECU transmits the help signal (the positional information of the vehicle) and decelerates the vehicle at a constant deceleration to make the vehicle stop. On the other hand, when the communication connection to the help net center HNC has not been established, the driving support ECU makes the vehicle travel at a constant speed. Accordingly, it is possible to make the vehicle stop under a situation where the help net center HNC recognizes the vehicle position inside which the driver who has been determined to be in the abnormal state is.

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 steering apparatus for a two-track vehicle may include a steering handle, in the case of whose rotary actuation the steerable vehicle wheels can be turned by a wheel steering angle, and a control device to electrically actuate a steering actuator for setting the wheel steering angle was a function of driving operational parameters and independently of the steering handle and a clutch that provides a releasable mechanical steering connection between the steering handle and the steerable vehicle wheels. An automatic avoidance manoeuvre may be carried out in the case of a risk of collision, in which the control device fully releases the clutch, and the control device actuates the steering actuator such that the vehicle briefly leaves its driving lane and is then brought back into the driving lane. The control device also actuates a braking of the steering handle during the collision avoidance manoeuvre.

A method for operating a lane-keeping assistance system of a vehicle includes: detecting at least two lane markings in a traffic space ahead of the vehicle using a sensor system; recognizing the separation of a primary lane into a first secondary lane and a second secondary lane based on the at least two detected lane markings; selecting one of the secondary lanes, including detecting and analyzing a signal representing an instantaneous driver intention; calculating a target trajectory of the selected secondary lane; activating a steering device of the vehicle for guiding the vehicle along the calculated target trajectory of the selected secondary lane.

An autonomous vehicle control system is provided. The control system may include a plurality of cameras to acquire a plurality of images of an area in a vicinity of a vehicle; and at least one processing device configured to: recognize a curve to be navigated based on map data and vehicle position information; determine an initial target velocity for the vehicle based on at least one characteristic of the curve as reflected in the map data; adjust a velocity of the vehicle to the initial target velocity; determine, based on the plurality of images, observed characteristics of the curve; determine an updated target velocity based on the observed characteristics of the curve; and adjust the velocity of the vehicle to the updated target velocity.

A system for a vehicle is provided. The system may include a memory and at least one processor configured to: access a plurality of images of a forward-facing view from the vehicle, the plurality of images corresponding to image data obtained by a camera; determine from the images a first lane marking on a first side of a lane, the lane through which the vehicle can navigate, and a second lane marking on a second side of the lane opposite of the first side; navigate the vehicle autonomously relatively centered between the first and second lane markings; determine from the plurality of images that an object is on the first side or the second side of the lane, and the object beyond the first or second lane marking; and navigate the vehicle autonomously to travel over a driving path that is offset from a center of the lane.

A vehicle control system includes a lane line recognizer that recognizes lane lines of a road on which a vehicle is traveling, a virtual line setter that sets, when there is a section in which the lane lines are not recognizable by the lane line recognizer after passing through a gate installed on the road, a virtual line with a terminating end portion of a lane line extending from the gate or an object present near the gate as one end and a beginning end portion of the lane line in a future travel area of the vehicle which is present ahead of the section in which the lane lines are not recognizable as another end, and an automated driving controller that performs automated driving in the section in which the lane lines are not recognizable on the basis of the virtual line set by the virtual line setter.

A lane departure prevention device includes: a travelling state recognition unit; a lane line recognition unit; a departure determination unit; a yaw moment calculation unit configured to calculate a target trajectory and a target yaw moment; a direction determination unit configured to determine the departure avoidance direction; a direction alignment determination unit configured to determine the turning direction of the vehicle by the target yaw moment coincides with the departure avoidance direction; and a braking force control unit configured to control the braking forces of the vehicle. In a case where the direction alignment determination unit determines that the results of determinations coincide with each other, the braking force control unit perform a braking force control, and in a case where the direction alignment determination unit doesn't determine that the results of determinations coincide with each other, the braking force control unit doesn't perform the braking force control.

Systems and methods are provided for determining a road profile along a predicted path. In one implementation, a system includes at least one image capture device configured to acquire a plurality of images of an area in a vicinity of a user vehicle; a data interface; and at least one processing device configured to receive the plurality of images captured by the image capture device through the data interface; and compute a profile of a road along one or more predicted paths of the user vehicle. At least one of the one or more predicted paths is predicted based on image data.

Provided is a vehicle travel control device which simultaneously achieves the behavioral stability of a vehicle and the continuity of travel assistance during vehicle travel assistance. The setting range of controlled variable to an actuator in travel assistance control is limited on the basis of the information having higher priority among road type information and road shape information. Thus, compared to when the setting range of the control variable is determined on the basis of only the road type information or the road shape information, it is possible to suppress excessive limitations on the applicable range/duration time of travel assistance.