A vehicular adaptive driving beam headlighting system includes a camera disposed at and viewing forwardly through a windshield of a vehicle. A control includes an image processor that processes image data captured by the camera at night to detect headlights present in a field of view of the camera of an oncoming vehicle that is approaching the equipped vehicle along a traffic lane to the left of a traffic lane of a road that the equipped vehicle is travelling along. A left-side headlamp is disposed at a left-side front portion of the equipped vehicle and a right-side headlamp is disposed at a right-side front portion of the equipped vehicle. Responsive to detection of headlights of an oncoming vehicle, the left-side headlamp beam of light is adjusted to reduce glaring a driver of the oncoming vehicle.

Embodiments describing an approach to receiving visual feedback. Generating a recommended visual pattern based on the visual feedback. Tracking a driver's real-time visual pattern. Extracting the driver's real-time visual patterns from the eye-tracking data. Determining the differences between the recommended visual pattern and the driver's real-time visual pattern. Generating enhanced headlamp control configurations based on the determined differences between the recommended visual pattern and the driver's real-time visual pattern; and adjusting the headlamp calibration controls based on the enhanced headlamp control configuration.

Embodiments describing an approach to receiving visual feedback. Generating a recommended visual pattern based on the visual feedback. Tracking a driver's real-time visual pattern. Extracting the driver's real-time visual patterns from the eye-tracking data. Determining the differences between the recommended visual pattern and the driver's real-time visual pattern. Generating enhanced headlamp control configurations based on the determined differences between the recommended visual pattern and the driver's real-time visual pattern; and adjusting the headlamp calibration controls based on the enhanced headlamp control configuration.

The invention is directed to methods and devices to improve light patterns used to inform or assist an observer or a driver. The invention is related to an illuminating device and to a method for projecting a pre-definable light pattern using the illuminating device of the vehicle into an area surrounding the vehicle. According to the invention, a projection surface is determined in the area surrounding the vehicle, a position of a predefined observer has been determined or provided, and a light unit of the illuminating device is controlled pixel-wise according to the determined projection surface and the determined position of the predefined observer in order to produce the pre-definable light pattern.

A driver assistance system for a vehicle includes a camera disposed at and viewing forwardly through a windshield of the equipped vehicle and operable to capture image data. A control operable to process captured image data utilizing algorithmic decision-making, which uses an edge detection algorithm. The control is operable to process captured image data to detect a pedestrian present in the field of view of the camera. The control is operable to process captured image data to detect an oncoming headlight or a leading taillight of another vehicle ahead of the equipped vehicle. Responsive to pedestrian detection, the control is operable to generate an alert to a driver of the equipped vehicle. Responsive to detection of an oncoming headlight or a leading taillight of another vehicle ahead of the equipped vehicle, a light beam of a headlight of the equipped vehicle is adjusted.

In an illumination device for a vehicle, when a recognition part has recognized that a pedestrian may be present on an advancing route and when a detection part has detected that a driver has recognized the pedestrian, an exterior light is brought into either a first lit or first not-lit state, and when the recognition part has recognized that the pedestrian may be present on the advancing route and when the detection part has detected that the driver has not recognized the pedestrian, the exterior light is brought into either a second lit or second not-lit state, and the first lit state and the second lit state are different from each other and the first not-lit state and the second not-lit state are different from each other.

An automated headlight system for vehicles replaces the high and low beam with a continuum of beam patterns, with further variable spatial distribution of intensities and color spectrum. The digital-headlight is comprised of a controller, sensors and multiple, individually-controllable light-sources modified by optical-control elements to form narrow-beams which are then combined to create the overall headlamp beam. Utilizing real-time sensor data regarding beings, objects and vehicles in the way-ahead, as well as optional information on the driver, vehicle and environment, the logical controller dynamically adapts the headlight system's illumination so as to provide vehicle operators with optimal visibility while preventing discomfort-glare from reaching the eyes oncoming traffic or pedestrians.

The present disclosure relates to a method for selectively highlighting visual zones associated with a vehicle. A point of origin and a gaze direction of a vehicle occupant are determined and a virtual projection plotted corresponding to the gaze of the vehicle occupant. The virtual projection extends from the determined point of origin in a direction of the determined gaze direction. With reference to a three-dimensional model comprising a plurality of pre-defined areas of interest, an intersection of the virtual projection with one of the plurality of areas of interest is identified. The method comprises controlling an illumination source that is associated with the determined one of said plurality of areas of interest so as to highlight a visual zone associated with the vehicle.

An adaptive lighting system of an off-road utility vehicle includes an illumination device controllable with respect to its emission characteristic or light intensity, and a control unit in communication with the illumination device. The control unit is configured to adapt the emission characteristic or light intensity level by controlling the illumination device based upon a determined gaze direction of a vehicle operator, an identified extraneous light effects, a determined relative position of an external off-road utility vehicle, or cartographic location information.

A lighting device is provided for controlling the photometric distribution of light emitted by two or more LEDs. The lighting device may be integrated with a control system of the vehicle and may be controlled by a remote controller. The lighting device may be capable of being operated in one or more modes of operation based on operating conditions, user input, or both. Operating conditions may include vehicle conditions, environmental conditions, and user conditions. The controller may operate a software application to enable the user to modify, control, or otherwise regulate any mode of operation or other feature of the lighting system.