To avoid an adverse effect on the sensor by the heater. A controller for a heater installed in a vehicle lamp, where the controller detects a rising edge of a light emission period of a sensor light emitted from an object detection sensor built in the vehicle lamp, and starts supply of a drive voltage to the heater in accordance with the rising edge.

A device for alerting approaching vehicles of a slow-moving vehicle is provided. The device includes a light bar having one or more illumination units positioned on a front face thereof, a sensing unit, and means for activating the one or more illumination units on the light bar. The light bar further includes a mounting mechanism on a rear face thereof for removably mounting the light bar on a vehicle. The sensing unit senses the location and speed of the vehicle and for compares the speed of the vehicle to a posted speed limit for a roadway upon which the vehicle is traveling. The activating means serve to activate the one or more illumination units when the sensing unit determines that the speed of the vehicle is less than a pre-determined value below the posted speed limit for the roadway.

The present disclosure relates to an illumination system for a motor vehicle for illuminating a carriageway section. The aim is to illuminate the carriageway section in such a way that irritations for other road users are avoided as far as possible. The illumination system includes an information system for providing or detecting a stopping point, an illumination device for projecting a calculated light distribution onto the carriageway section, and a control unit for calculating a light distribution, wherein the calculated light distribution is a one-piece area. The one-piece area begins from a predetermined starting section, which constitutes a proximal lighting section relative to the motor vehicle and does not extend beyond the stopping point. This leads to a shortening of a lane light of the motor vehicle, so that said lane light does not illuminate the lane beyond the stopping point. This is advantageous in particular for crossroads.

Systems and methods for an aircraft lighting system (ALS) are provided. The method includes co-locating a central light source subsystem including a blue light generator, red light generator, and green light generator, and a light generating control unit (LGCU) comprising a processor, and distributing a plurality of passive light-heads around an external surface of the aircraft. Each passive light-head of the plurality of passive light-heads is operationally coupled to a first side of a respective light switch of a respective plurality of light switches, the light switch being coupled on a second side to a light emitting output of the central light source subsystem. Controlling and actuating the light generators and the light switches in accordance with a load profile is performed by a light generating control unit (LGCU).

The present invention relates to a support for a light source of a lighting device of a motor vehicle, including a zone for positioning the light source, referencing elements with respect to three given mutually transverse axes, one of the referencing elements, termed a referencing element with two portions, a first portion extending along or parallel to a first axis of the three given axes, and a second portion extending transversely relative to this first given axis.

A covering device for fully or partially covering one or more of a recess, a flat portion, a curved portion, and a stepped portion of at least one of a vehicle body component and a vehicle part includes a cover element provided by a strip element or a cap element, and at least one lip element which is fixedly or detachably connected to the cover element on at least one of its longitudinal sides, the covering device is designed so that light from a lighting device can shine through at least a portion of the covering device, at least one of the cover element and the at least one lip element is made at least partly of a polymeric substrate which is coated with a chromium-based reflective coating material, and the polymeric substrate and the chromium-based reflective coating are at least partially translucent.

Disclosed are a vehicle and a control method thereof configured for performing a vehicle control to detect lighting irradiated from a lamp at the time of vehicle parking and park the vehicle safely and accurately. The vehicle includes a lamp configured to irradiate lighting to a ground, a camera configured to photograph the lighting irradiated to the ground to obtain information on a form of the lighting of the lamp, and a controller configured to determine at least one of the form of the ground to which the lighting is irradiated and whether or not an obstacle exists on the ground to which the lighting is irradiated, based on the information on the obtained form of the lighting of the lamp.

A holographic projection system and method are implemented by a projection device provided on the vehicle; a water mist generating device for generating water mist provided on the vehicle; and a controller in communication with the projection device and the water mist generating device. The controller is configured to detect a signal of user proximity to the vehicle, and activate the water mist generating device and the projection device respectively based on the detected signal, so that the projection device projects an image onto the water mist.

A system, a method, and a computer program product may be provided for user guidance. In an example, the system includes an image projection device configured to project traffic patterns on a surface, at least one non-transitory memory configured to store computer program code, and a processor configured to execute the computer program code to control operation of the image projection device. For example, sensor data from one or more sensors onboard a vehicle is obtained. The sensor data is associated with a state of operation of the vehicle, and proximate movement associated with the vehicle. Based on the sensor data, one or more traffic patterns for projection is determined. Further, an image projection device is controlled to project the one or more traffic patterns in one or more direction of the vehicle.

The present invention is an LED lighting system which can be retrofit to an existing vehicle. The lighting system can provide sequential lighting of multiple lamps for effect. In a non-limiting embodiment, a 7-pin wireless remote controller may be plugged directly into a vehicle's 7-pin hitch harness port where it draws power and receives light signals for stopping, hazard (four-way lights), turning. It then in turn will process and communicate these signals to a wireless LED strip. In another non-limiting embodiment, a 4-pin wireless remote controller may be connected directly to a vehicle's 4-pin harness plug, if equipped, or spliced directly into the vehicle's wire harness if it is not equipped with a 4-pin plug. The 4-pin wireless remote controller will process these light signals and communicate them to a wireless LED strip.