A vehicle lamp includes a first light source, a second light source, a scanning unit, an optical sensor and a control unit. The scanning unit scans light emitted from the second light source such that the light emitted from the second light source irradiates a linear region that extends in a horizontal direction. The scanning unit includes a reflector in which a portion that reflects light of the first light source toward a front side of the lamp and a portion that reflects light of the second light source toward the front side are the same, or a reflector in which a portion that reflects the light of the first light source toward the front side and a portion that reflects the light of the second light source toward the front side are integrated.

A vehicle lamp system mounted on a vehicle includes an in-vehicle sensor includes an IR light source, a scanning unit, an infrared camera, a region setting unit for comparing information acquired from the in-vehicle sensor and information acquired by the infrared camera and setting a dimming area and/or an emphasis area, and a lamp control unit for controlling an applied power amount and turning on and off of the IR light source such that a specific region is irradiated with the infrared rays emitted from the IR light source based on output of the region setting unit.

The present invention relates to a vehicle head lamp driving apparatus and a vehicle provided with the same. The vehicle head lamp driving apparatus of the present invention comprises: a light output unit to output structured visible light to the front of a vehicle; a light receiving unit to receive reception light corresponding to the structured visible light; and a processor to calculate a distance to and a location of an object positioned in front of the vehicle, on the basis of the received reception light and structured visible light, wherein the light output unit comprises: a laser diode to output structured visible light having a first color; a light conversion unit for converting, into structured visible light having second and third colors, at least a part of the structured visible light having the first color; and a light diffusing unit for diffusing and outputting the structured visible light having the first to third colors to the front of the vehicle. Therefore, the distance to the object in front of the vehicle can be detected on the basis of visible light.

Provided is a vehicular lighting apparatus which is relatively small, can be manufactured at low cost, is superior in mountability to an automobile, and is superior in recognizeability of an object illuminated by a head lamp. The vehicular lighting apparatus attachable to a front end part of a vehicle includes: a composite lens element that is a light guide element constructed by molding a translucent resin substantially into a plate-like shape; a planar light-emitting unit that emits illumination light; an optical system that transforms planar light from the light-emitting unit into linear light and that causes the linear transformed light to be incident on a rear side face of the light guide element; and a diffraction lens formed on the rear side face of the light guide element on which the linear transformed light is incident, and condensing the linear transformed light. The light condensed by the lens means is emitted from a front side face of the light guide element onto a road surface in front of the vehicle. The light-emitting element emits whit light including red light.

A vehicle lamp includes: a first light source configured to irradiate visible light; a second light source configured to emit infrared light; a rotating reflector configured to be rotated while reflecting the visible light and the infrared light, and scan the visible light and the infrared light along a horizontal direction on a virtual vertical screen; a light receiving unit configured to receive the infrared light emitted from the second light source and reflected by a target object; and a controller configured to control an irradiation area of the visible light based on the infrared light received by the receiving unit. When determined that there is an abnormality in at least one of the second light source or the light receiving unit, the controller is configured to control the irradiation area based on the surrounding information of the vehicle obtained from outside the vehicle lamp.

An exterior aircraft light unit for emitting light of a first wavelength and light of a second wavelength, different from the first wavelength is disclosed. The exterior aircraft light unit has an integrated optical structure, which in turn has a first light source configured to emit the light of the first wavelength, a second light source configured to emit the light of the second wavelength, the second light source being positioned adjacent to the first light source, and an optical element for shaping a light emission distribution of the integrated optical structure. The optical element is arranged with respect to the first light source and the second light source in such a way that it affects both the light of the first wavelength and the light of the second wavelength.

A lighting system including a lighting device configured to be connected to an object. The lighting device includes a body, at least one visible light source connected to the body, and at least one ultraviolet light source connected to the body. The at least one ultraviolet light source is operably coupled to the at least one visible light source. The lighting device is configured for strobing the visible light and ultraviolet light sources by turning the at least one ultraviolet light source on upon the at least one visible light source turning off and turning the at least one ultraviolet light source off upon the at least one visible light source turning on such that a reflectance material of an object, which is not being illuminated by the at least one visible light source, is illuminated by the at least one ultraviolet light source.

A lighting system including a lighting device configured to be connected to an object. The lighting device includes a body, at least one visible light source connected to the body, and at least one ultraviolet light source connected to the body. The at least one ultraviolet light source is operably coupled to the at least one visible light source. The lighting device is configured for strobing the visible light and ultraviolet light sources by turning the at least one ultraviolet light source on upon the at least one visible light source turning off and turning the at least one ultraviolet light source off upon the at least one visible light source turning on such that a reflectance material of an object, which is not being illuminated by the at least one visible light source, is illuminated by the at least one ultraviolet light source.

A semiconductor light source and driving aid system for a motor vehicle comprising a semiconductor light source. The semiconductor light source includes a plurality of electroluminescent rods of submillimetric dimensions. At least certain rods are electrically interconnected in a first assembly dedicated to an emission of a light beam at a first wavelength, and other rods are electrically interconnected in a second assembly dedicated to an emission of a light beam at a second wavelength different from the first wavelength, the first and the second assemblies forming two selectively activable emission areas.

In various embodiments, an arrangement is provided. The arrangement includes a light source for a light system; an adaptive mirror arrangement connected downstream of the light source via which adaptive mirror arrangement light that is emittable by the light source is directable, and a radiation source for a sensor system for capturing an environment. The radiation from the radiation source for the sensor system is directable via the adaptive mirror arrangement.