To provide a vehicular lamp that can improve the degree of freedom in the arrangement position of a road surface irradiation unit. The vehicular lamp comprises a road surface irradiation unit for forming an irradiation pattern around the vehicle with light from a light emitting portion for a road surface; and a shielding part for covering the light emitting portion for the road surface when the road surface irradiation unit is viewed from the front. The vehicular lamp may further comprise a lamp unit housed in a lamp chamber together with the road surface irradiation unit, and the road surface irradiation unit may be turned on and off interlocked with the lamp unit.

A vehicular lighted exterior door handle system includes a lighted exterior door handle assembly having a light module, which includes a circuit board and at least three linearly arranged illumination sources at the circuit board. When the illumination sources are actuated, light emitted by each of the illumination sources is emitted outboard away from the door of the equipped vehicle. With the lighted exterior door handle assembly mounted at the door of the equipped vehicle, and when the illumination sources are actuated with the door of the equipped vehicle unlocked, the light module emits light in a first pattern. With the lighted exterior door handle assembly mounted at the door of the equipped vehicle, and when the illumination sources are actuated with the door of the equipped vehicle locked, the light module emits light in a second pattern that is different from the first pattern.

A turn signal unit for an external mirror for a motor vehicle is designed to radiate a flashing light forwards in the direction of travel with the turn signal unit and the external mirror in the installation position at the side of the vehicle. The turn signal unit includes a light source and a lens disposed in front of the light source. A film with alternating light transmissive and non-light transmissive structures is clamped in the space between the light source and the lens. The film is clamped via a clamping structure which includes structure that is part of the lens and/or a housing portion of the turn signal unit.

The present invention relates to a vehicle U-turn indicator system to alert other motorists, cyclists and pedestrians of a potential U-turn made by a vehicle. The indicator is an inverted “U” shaped device having LED lights configured to blink in a running manner from one end to other and vice versa. The blinking of LED lights in one direction indicates U-turn of the vehicle in one direction (i.e. left) and in another direction indicates a U-turn of the vehicle in another direction (i.e. right). The indicator can be mounted to the front and rear of the vehicle in addition to side mirrors. An actuator is used for activating the U-turn indicator in a preferred direction.

An illuminating device for vehicles, including an elongated light guide, which has an end face for coupling light into the light guide and has a lateral surface, at which the coupled-in light may be totally reflected in a coupling direction. An elongated reflector is arranged so that it follows the light guide and at least partially behind the light guide in the main emission direction. The light guide is designed such that the coupled-in light is coupled out on a rear-side lateral surface and/or side lateral surface facing the reflector and on a front lateral surface facing away from the reflector. The light guide and the reflector each have a corner region, in which sections of the light guide and sections of the reflector enclose an acute or right or obtuse angle.

A lighting device for a motor vehicle includes a lighting component having one or more light sources and one or more transparent facet bodies, each of which bodies has a surface consisting of a plurality of planar first facets. Light originating from the one or more light sources is radiated into the one or more transparent facet bodies as first luminous radiation. The first luminous radiation is at least partially refracted on first facets of the one or more transparent facet bodies and subsequently exits the lighting device as second luminous radiation in order to produce light distribution. One or more translucent optical components are located in the lighting device between the lighting component and the one or more transparent facet bodies.

A lamp unit in which an opening of a unit case is covered with an outer lens is provided. The lamp unit includes a first inner lens provided inside the outer lens, a second inner lens provided inside the outer lens, a first light source facing an incident surface of the first inner lens, and a second light source facing an incident surface of the second inner lens. A space inside the first inner lens and a space inside the second inner lens are continuous. At least a part of the incident surface of the second inner lens is disposed in an irradiation range of the first light source.

A vehicle lamp includes: a first light source and a second light source having light emission colors different from each other; and a light guide body that receives and emits light from the first light source and the second light source. The light guide body includes an incident portion on which the light is incident, a reflecting portion that reflects the light incident from the incident portion, and an emitting portion that emits the light reflected by the reflecting portion. The reflecting portion includes a plurality of first light distribution control surfaces that reflects the light from the first light source toward a predetermined direction and a plurality of second light distribution control surfaces that reflects the light from the second light source toward the predetermined direction. The plurality of first and second light distribution control surfaces are alternately arranged.

An automotive light comprising a lighting assembly which is located inside the rear body, is adapted to backlight a corresponding transparent or semi-transparent sector of the front half-shell, and comprises: a pair of light-guide bars made of photoconductive material, which extend toward each other inside the rear body, while remaining both substantially grazing the front half-shell, and have their respective proximal ends adjacent and aligned to one another; and a pair of electrically-powered light sources that are located within the rear body each adjacent to the distal end of a respective light-guide bar, and are oriented so as to direct the light produced inside the body of the facing light-guide bar; the proximal ends of both light-guide bars being shaped so as to form respective plate-like heads that are locally substantially coplanar to each other and are arranged inside the rear body one spaced beside the other, so as to form/delimit therebetween a small transversal slot, which is substantially straight and is inclined with respect to the local longitudinal axis of the same light-guide bars.

A lighting apparatus includes light emitting elements having an emission peak wavelength of 400 to 510 nm, a first phosphor having an emission peak wavelength of 485 to 700 nm, a second phosphor having an emission peak wavelength of 510 to 590 nm, a third phosphor having an emission peak wavelength of 600 to 700 nm, and a color filter having transmittance for light with a wavelength of 600 to 730 nm that is 80% or more and transmittance for light with a wavelength of 410 to 480 nm that is 3% or more and 50% or less. The color filter transmits a part of light emitted from the first phosphor, at least a part of light emitted from the second phosphor, and at least a part of light emitted from the third phosphor. Light transmitted through the color filter is emitted to the outside.