A vehicle front headlight device includes a light source, a rotating mirror configured by a plurality of mirror bodies, that are rotationally driven about a shaft, and, while rotating, reflecting light emitted by the light source, a lens transmitting light that is reflected by the rotating mirror, a recognition unit configured to recognize a leading vehicle traveling ahead, and a controller controlling a timing at which the light source is switched off and a timing at which the light source is switched on, such that light is not illuminated onto the leading vehicle recognized by the recognition unit and such that an illumination intensity of light illuminated in a vicinity of both ends in a vehicle width direction of the leading vehicle is lower than an illumination intensity of light illuminated at an outer side of the vicinity of the both ends in the vehicle width direction of the leading vehicle.

A motor-vehicle lighting system including a device for projecting a low beam into a projection zone, wherein the projecting device is configured so that the low beam includes a zone of lesser illumination located in the interior of the projection zone. A preferred application is the field of lighting equipment for motor vehicles.

To improve pedestrian visibility. Provided is a headlight controller connectable to a first headlight and a second headlight spaced apart in a vehicle width direction at the front of the vehicle, the headlight controller including: a rainfall amount detection means installed in the vehicle; and a controller installed in the vehicle, where the controller is connected to the rainfall amount detection means, and the controller carries out control such that when rainfall amount detected by the rainfall amount detection means is equal to or more than a predetermined value, irradiation light from the first headlight becomes relatively darker than irradiation light from the second headlight.

There is provided a lighting device arranged to produce a controllable light beam for illuminating a scene. The device comprises an addressable spatial light modulator arranged to provide a selectable phase delay distribution to a beam of incident light. The device further comprises Fourier optics arranged to receive phase-modulated light from the spatial light modulator and form a light distribution. The device further comprises projection optics arranged to project the light distribution to form a pattern of illumination as said controllable light beam.

A vehicle lamp control device includes an information acquisition unit that acquires snowfall information, and a controller that controls a vehicle lamp capable of changing a formation position of a light distribution pattern. The controller controls the vehicle lamp so as to lower the formation position from a predetermined reference position when snowfall is perceived, and when the snowfall amount is larger than a predetermined value, the controller substantially lowers the formation position as compared with the formation position when the snowfall amount is smaller than the predetermined value.

A method and system for controlling exterior lights on a vehicle. The method includes receiving an input indicative of a desired mode of operation of the exterior lights from a user-selectable input device. The user-selectable input device includes an on-setting, an off-setting, and an automatic-setting. The method further includes receiving sensor data indicative of a level of visibility outside the vehicle, comparing the sensor data to a threshold, and generating, by an electronic processor, a notification indicative of an improper positioning of the user-selectable input device when the sensor data indicates that the level of visibility is less than the threshold and the user-selectable input device is positioned in the off-setting.

A sensing system for a vehicle includes a sensor disposed at a vehicle and a control that includes a processor for processing sensor data captured by the sensor. A first polarizer is disposed in a light emitting path of at least one light source of the vehicle and a second polarizer is disposed in a light receiving path of the sensor. The second polarizer has an opposite-handed polarization configuration relative to the first polarizer. Some of the polarized light as polarized by the first polarizer impinges precipitation present in the field of sensing of the sensor and returns toward the sensor as refracted-reflected light. The second polarizer attenuates the refracted-reflected light and allows light reflected from objects present in the sensor's field of sensing to pass through to the sensor. The control, responsive to processing of captured sensor data, detects objects in the field of sensing of the sensor.

A lamp light control technical solution includes obtaining current location information of a vehicle, obtaining a control instruction determined based on predetermined information and a predetermined control rule, where the predetermined information at least including information determined according to the current location information, and the predetermined control rule including a correspondence between the predetermined information and the control instruction. The lamp light control technical solution further includes executing the control instruction, to control lamp light of the vehicle. A computer storage medium and an in-vehicle device for implementing the lamp light control are also provided.

A pulsed laser may illuminate a scene that is obscured by dense, dynamic and heterogeneous fog. Light may reflect back to a time-resolved camera. Each pixel of the camera may detect a single photon during each frame. The imaging system may accurately determine reflectance and depth of the fog-obscured target, without any calibration or prior knowledge of the scene depth. The imaging system may perform a probabilistic algorithm that exploits the fact that times of arrival of photons reflected from fog have a Gamma distribution that is different than the Gaussian distribution of times of arrival of photons reflected from the target. The probabilistic algorithm may take into account times of arrival of all types of measured photons, including scattered and un-scattered photons.

Aspects of this disclosure relate to controlling one or more vehicle systems based on a determined weather condition. In some embodiments, a radar system can be mounted on a vehicle and can collect weather data by receiving electromagnetic signals. A weather condition can be determined based on the collected weather data, and a vehicle system can be controlled based on the determined weather condition, such as vehicle lighting, windscreen wipers, or cruise control. In some embodiments, weather conditions can include fog, sleet, or smog. The weather condition can be determined by analyzing scattered reflections from incident microwaves and/or radio waves to determine a level of attenuation of the scattered electromagnetic energy indicative of a presence or absence of particles. A map can be displayed displaying the weather condition and controlling vehicle navigation systems. The collected weather data can be compared with data from a LiDAR or camera system for reliability.