Various embodiments include methods and vehicles, such as an autonomous vehicle, a semi-autonomous vehicle, etc., for collaboratively directing one or more headlights by two or more vehicles. Various aspects may include receiving, by a first vehicle processor, a first collaborative lighting message from a second vehicle, in which the first collaborative lighting message may request the first vehicle direct one or more headlights of the first vehicle, in collaboration with the second vehicle directing one or more headlights of the second vehicle according to a collaborative lighting plan, and directing, by the first vehicle processor, one or more of the headlights of the first vehicle in accordance with the collaborative lighting plan.

Various embodiments include methods and vehicles, such as an autonomous vehicle, a semi-autonomous vehicle, etc., for collaboratively directing one or more headlights by two or more vehicles. Various aspects may include receiving, by a first vehicle processor, a first vehicle collaborative lighting message from a second vehicle, in which the first vehicle collaborative lighting message requests that the first vehicle direct one or more headlights of the first vehicle to illuminate a target area of uncertainty that is disposed, relative to the first vehicle, in a direction other than a direction of travel of the first vehicle. The first vehicle processor may direct one or more the headlights of the first vehicle to illuminate the target area in accordance with the first vehicle collaborative lighting message.

Various embodiments include methods and vehicles, such as an autonomous vehicle, a semi-autonomous vehicle, etc., for collaboratively directing one or more headlights among vehicles traveling in a platoon. Various aspects may include transmitting, by a first vehicle processor of a first vehicle traveling in the platoon, a collaborative lighting plan to a second vehicle traveling in the platoon, wherein the collaborative lighting plan may direct the second vehicle to direct one or more headlights of the second vehicle in a direction other than a direction of travel of the platoon. The first vehicle processor may then direct one or more the headlights of the first vehicle in accordance with the collaborative lighting plan.

Various embodiments include methods and vehicles, such as an autonomous vehicle, a semi-autonomous vehicle, etc., for collaboratively directing or configuring one or more headlights of a vehicle to avoid visually interfering with operation of an oncoming vehicle. Various embodiments may include receiving, by a first vehicle processor, a first collaborative lighting message from a second vehicle, wherein the first collaborative lighting message requests that the first vehicle direct one or more headlights of the first vehicle to avoid visual interference with operation of the second vehicle and directing one or more the headlights of the first vehicle in accordance with the collaborative lighting plan. Directing the headlights to avoid visual interference with operation of the second vehicle may include switching the headlights to a low-beam configuration.

A vehicular driver assistance system includes a camera that views through the windshield of the vehicle and a control device having an image processor that processes captured image data. Responsive to processing of captured image data by the image processor, the system adjusts a light beam emitted by a headlamp of the vehicle. The control device, responsive at least in part to image data processing by the image processor, determines when the vehicle is at a construction zone. Responsive to determination that the vehicle is at a construction zone, image processing of image data captured by the camera is adjusted to discriminate construction zone signs from taillights of leading vehicles. Responsive to determination of the vehicle exiting the construction zone, the control device adjusts the light beam emitted by the headlamp of the vehicle responsive to determination of headlamps of approaching vehicles and taillights of leading vehicles.

Methods and systems to mitigate headlight blinding during travel in a vehicle by relaying location data from vehicles to a remote server. The remote server identifies vehicles approaching each other on an otherwise unoccupied roadway and sends one or more of those vehicles a warning signal. The vehicle receiving such as warning signal may then automatically take a headlight mitigation action.

An illumination control system for a mobile machine that operates in coordination with other mobile machines is configured to adjust an illumination lamp disposed on the mobile machine and directed in a travel direction of the machine. The illumination control system includes a positioning/location device that can determine a proximity distance between the mobile machine and a second mobile machine approaching in the travel direction. The illumination control system also includes an electronic controller configured to adjust the illumination device based on the proximity distance as determined. The illumination control system may find particular usefulness in paving and/or milling operations.

A method, apparatus, and computer program product are described herein for determining pedestrian behavior profiles for road segments of a road network, from those pedestrian behavior profiles, determining the likelihood that an adverse pedestrian event will occur, and determining the action to be taken in response. Example embodiments may provide a mapping system including: a memory having map data; and processing circuitry. The processing circuitry may be configured to: receive data points associated with pedestrian movement; associate pedestrian movement with a road segment; determine, based on the data points, a pedestrian behavior profile for the road segment; and in response to the pedestrian behavior profile for the road segment indicating a likelihood for an adverse pedestrian event that satisfies a predetermined likelihood, cause at least one action in response thereto.

A vehicular control system includes a camera, a controller having a processor that processes captured image data, and an exterior temperature sensor. Responsive, at least in part, to a temperature input from the temperature sensor, the controller switches processing of captured image data between (a) a normal processing mode and (b) a cold weather processing mode. Responsive to the temperature input being indicative of the exterior temperature being below a first threshold temperature, the controller processes captured image data in the cold weather processing mode to enhance blockage detection of frost or snow or ice at the camera. When the controller is operating in the cold weather processing mode, the controller switches processing of captured image data to the normal processing mode responsive to the temperature input being indicative of the exterior temperature being above a second threshold temperature that is greater than the first threshold temperature.

In an illumination apparatus arranged on a vehicle, image data of a plurality of pixels of an imaging region in front of the vehicle is created and an image processor calculates a luminance of each of the pixels on the basis of the image data. A controller is configured to calculate an average luminance of each of partial regions of the imaging region on the basis of the luminance of each of the pixels, to determine whether it is necessary to perform luminance adjustment for each of the partial regions, and to perform luminance adjustment for the partial region on the basis of a result of the determination. An illuminating unit having a plurality of light sources illuminates the partial region while allowing each light source to be adjusted so as to have a predetermined light quantity on the basis of the result of the luminance adjustment.