A light distribution control device including: an acquirer acquiring information representing a running status of an assistance operation performed for driving assistance from a driving assistance device performing driving assistance of a subject vehicle based on a recognition result of objects disposed in front of the subject vehicle recognized based on detection results acquired by a plurality of sensors including an optical sensor; and a light distribution controller performing light distribution control including change of an output level of a headlight of the subject vehicle, in which the light distribution controller gently performs change of the output level of the headlight in accordance with running of the assistance operation in the light distribution control.

A vehicle headlight (10) includes a light source unit (30) including a plurality of light emitting elements (35), a reflector (39) that scans light from the plurality of light emitting elements (35) to form a light distribution pattern (350), and a control unit (60). The control unit (60) controls the light source unit (30) such that the light amount of light emitted from some light emitting elements to a predetermined region (AR) overlapping a target object does not change and the light amount of light emitted from other some light emitting elements to the predetermined region (AR) overlapping the target object changes among the light emitting elements that emit light to the predetermined region (AR) overlapping the target object in the superimposition region (PA).

Provided are systems and methods for a deep learning based beam control. Sensor data associated with the environment and the corresponding detected objects from a perception system are obtained. Object features and image features are extracted. The extracted object features and image features are fused into fused features. A beam control status is predicted according to the fused features, wherein the beam control status indicates a high beam illumination intensity or a low beam illumination intensity of a light emitting device.

In a vehicle door mirror device, a projection device projects a graphic from a graphic film. The projection device is inserted into a cap in a state in which a holding tube of the cap has been inserted into a through hole in a visor, and the holding tube is held between a peripheral face of the through hole and a protrusion portion of the projection device. The projection device is thus installed at the visor in a manner retained by the cap alone. This thereby enables easy installation of the projection device to the visor.

A vehicular light source system includes: first and second laser emitters configured to emit first and second lasers; a thermometer configured to measure peripheral temperature; and a light source controller. The strength of the first laser at a temperature lower than a threshold temperature is higher than that of the second laser at that temperature. The strength of the first laser at a temperature higher than the threshold temperature is lower than that of the second laser at that temperature. The light source controller is configured to control the first and the second laser emitters such that: the strength of the first laser becomes higher than that of the second laser if the peripheral temperature is lower than the threshold temperature; and the strength of the second laser becomes higher than that of the first laser if the peripheral temperature is higher than or equal to the threshold temperature.

Vehicle headlamp for illuminating a light distribution and for detecting an obstacle in front of the headlamp, the headlamp including: (i) a housing and cover lens, (ii) an obstacle detection device including a camera, disposed inside the housing, for capturing images, and (iii) a camera calibration system for automatically calibrating the spatial orientation of the camera, the system being configured to keep the camera in a predetermined target position and including (a) an adjustment device for adjusting the spatial orientation of the camera within the housing, (b) a reference mark arranged in the housing, wherein each image has a constant predetermined reference mark position sector (PRMPS), and wherein the camera is in the target position when the reference mark is arranged within the PRMPS of the images, and (c) a control device connected to the camera and the adjustment device, the control device being configured to receive the images captured by the camera and to control the adjustment device to remove the deviation from the target position when the reference mark is outside the PRMS of the images in a non-target position.

The present disclosure relates an integrated module including a camera and a lamp, and may include a camera that acquires an image of a periphery of a vehicle and provide the image, at least one first lamp and at least one second lamp disposed at at least one location of an upper side and a lower side of the camera in a direction of a transverse axis of the camera, and a lamp controller that provides electrical energy for the first lamp to the first lamp and provides electrical energy for the second lamp to the second lamp according to daytime/nighttime determination information based on the image.

A camera wing system, a vehicle comprising such camera wing system, and a method to operate such a camera wing system are provided, comprising a camera to record a field of view of the camera in a scenery at least around a rear part of the vehicle, where a presented view is provided to a driver of the vehicle as a part of the field of view, wherein the camera wing system is adapted to automatically panning the presented view of the camera to another presented view different from the previous presented view in order to keep a point of interest of the rear part of the vehicle within the presented view provided to the driver regardless of a driving situation of the vehicle.

Systems and methods for data and confidentiality preservation for feature identification by robotic devices are disclosed herein. According to at least one non-limiting exemplary embodiment, a method for determining if an image depicts a human is disclosed. The determination may be utilized to either (i) censor the face of the human, or (ii) identify features within the image. The determination enhances feature identification by ensuring only uncensored and unobscured images are provided to one or more models for the identification to preserve human confidentiality.

An apparatus mountable on a vehicle includes a movable device, a sensor, and a drive controller. The movable device is mountable on the vehicle so that a person around the vehicle sees the movable device. The movable device has at least one light emitter and is capable of rotating around an imaginary line extending in a height direction of the vehicle. The sensor detects a positional relationship between the vehicle and the person. The drive controller rotates the movable device toward the person based on the positional relationship detected by the sensor. The number of the light emitters shining steadily is increased after the drive controller rotates the movable device toward the person.