A vehicular lane change system includes a forward-viewing camera that has a field of view through the vehicle windshield that encompasses a road being traveled along by the vehicle. Responsive at least in part to processing of image data captured by the camera, a control determines the lane traveled by the vehicle. The control is operable to detect a lane change maneuver of the vehicle to a lane immediately adjacent to the lane traveled by the vehicle. Detection of the lane change maneuver is based at least in part on vehicle steering data and/or image processing of captured image data. Responsive to the control detecting the lane change maneuver of the vehicle when the driver of the vehicle has neglected to turn on an appropriate turn signal indicator of the vehicle, the control automatically turns on the turn signal indicator at the appropriate side of the vehicle.

A vehicle control apparatus mounted to an own vehicle to control the own vehicle according to a position of other vehicle ahead of the own vehicle is provided. The device includes a setting means setting a parameter indicating a position of the other vehicle relative to the own vehicle in a lateral direction perpendicular to the path of the own vehicle, a determination means determining whether the other vehicle is in the path of the own vehicle based on the parameter, a detection means detecting whether a relative movement has been made in the lateral direction by at least one of the own vehicle and the other vehicle, and a correction means correcting the parameter when a relative movement has been made in the lateral direction.

An overtaking lane control system in a vehicle comprises a lane determination unit to recognize road configuration; an obstacle monitoring unit to detect approaching vehicles in adjacent lanes; and an overtaking lane control unit to issue a first alert to a driver to warn the driver to return to a normal lane when the overtaking lane control unit determines that the vehicle has traveled in an overtaking lane for a first predetermined time and it is safe to change to the normal lane.

Systems and methods use cameras to provide autonomous navigation features. In one implementation, a method for navigating a user vehicle may include acquiring, using at least one image capture device, a plurality of images of an area in a vicinity of the user vehicle; determining from the plurality of images a first lane constraint on a first side of the user vehicle and a second lane constraint on a second side of the user vehicle opposite to the first side of the user vehicle; enabling the user vehicle to pass a target vehicle if the target vehicle is determined to be in a lane different from the lane in which the user vehicle is traveling; and causing the user vehicle to abort the pass before completion of the pass, if the target vehicle is determined to be entering the lane in which the user vehicle is traveling.

A vehicular control system includes a plurality of cameras, at least one radar sensor, and a control having at least one processor. Captured image data and sensed radar data are provided to and processed at the control to detect objects present exteriorly of the vehicle. The control receives data relevant to a geographic location of the vehicle. The vehicular control system wirelessly communicates information that is relevant to the geographic location of the vehicle to a remote receiver. The information wirelessly communicated to the remote receiver is derived, at least in part, from image data captured by at least a forward-viewing camera. The vehicular control system, based at least in part on processing at the control of at least one selected from the group consisting of (i) captured image data and (ii) captured radar data, detects another vehicle that is present exterior of the equipped vehicle.

Driving support ECU sets a driver's state to temporarily abnormal and decelerates a vehicle when a driver of the vehicle has been first determined to be in an abnormal state where the driver loses an ability to drive the vehicle. Driving support ECU changes the driver's state to regularly abnormal in a case when the abnormal state of the driver remains unchanged when a vehicle speed decreases to a set vehicle speed, and at this point, reports to a help net center HNC. With this configuration, a report to the help net center HNC can be made at an appropriate timing.

A method for open-loop or closed-loop control of a driver assistance system of a vehicle, including: a) using a first sensor device to detect from a roadway at least one lane and a roadway marking that separates the lane from an edge of the roadway; b) using a second sensor device to detect operation of at least one operating device of the vehicle that influences the driving dynamics of the vehicle by virtue of the driver; c) using steering actuators and/or brake actuators to influence the driving dynamics of the vehicle; and d) outputting, if there is a threat of the vehicle leaving the lane, as detected by the first sensor device, a first warning signal. A related driver assistance system is also described.

An apparatus for controlling a lane change in a vehicle is provided. The apparatus includes: a turn signal module to receive an input for a turn signal, a navigation module to obtain map information, a display to output a user interface, and a processor electrically connected with the turn signal lever, the navigation module, and the display. The processor recognizes a diverging section located on a road where the vehicle is traveling, based on the map information obtained by the navigation module when a lane change command is received via the turn signal module, determines whether the vehicle is able to change a driving lane of the vehicle to a diverging lane in the diverging section based on a speed of the vehicle, and controls the vehicle to enter the diverging lane when the vehicle is able to change the driving lane.

A multi-lane scenario driving support is provided for an ego vehicle in a traffic situation. Traffic surroundings are measured by an environment sensor system. The traffic surroundings include data about traffic and free space within an ego lane of the ego vehicle and an adjacent lane, and data about front proximity area and rear proximity area of the ego vehicle. A decision device evaluates the measured traffic surroundings and decides a driving operation to be executed by the ego vehicle based on at least one strategy. In the decision device, a cost function is used for choosing one of at least six strategies. The cost function is based on at least a core priority to avoid collision of the ego vehicle and not cause collision of the ego vehicle with a third party vehicle.

Aspects of the present disclosure relate generally to identifying and displaying traffic lanes that are available for autonomous driving. This information may be displayed to a driver of a vehicle having an autonomous driving mode, in order to inform the driver of where he or she can use the autonomous driving mode. In one example, the display may visually distinguishing between lanes that are available for auto-drive from those that are not. The display may also include an indicator of the position of a lane (autodrive or not) currently occupied by the vehicle. In addition, if that lane is an autodrive lane the display may include information indicating how much further the vehicle may continue in the autonomous driving mode in that particular lane. The display may also display information indicating the remaining autodrive distance in other lanes as well as the lane with the greatest remaining autodrive distance.