When light is off, a transparent appearance is obtained, while when the light is on, light is seen through a transparent spot. The present invention includes a light source portion and a reflective portion. The light source portion emits light. The light source portion is disposed at a position shifted with respect to an emitting direction of emitted light from the reflective portion. The reflective portion reflects the light from the light source portion and emits it in a predetermined direction. The reflective portion is constituted by a transparent member with a refractive index at least in a visible light area larger than 1. As a result, in the present invention, the transparent appearance is obtained when the light is off, while the light is seen through the transparent spot when the light is on.

Provided is a lamp mounted on a vehicle where a lamp housing of the lamp is equipped with a lamp camera that captures an image of an object existing outside the vehicle and a lamp unit of which light distribution of emitted light beams is controlled to change based on positional information of the object captured by the lamp camera, in which the lamp camera has an imaging optical axis directed in a predetermined direction with respect to the vehicle, and the lamp unit is configured such that an illumination optical axis is controlled to change in an up-down direction based on the positional information of the object.

Provided is a lamp mounted on a vehicle where a lamp housing of the lamp is equipped with a lamp camera that captures an image of an object existing outside the vehicle and a lamp unit of which light distribution of emitted light beams is controlled to change based on positional information of the object captured by the lamp camera, in which the lamp camera has an imaging optical axis directed in a predetermined direction with respect to the vehicle, and the lamp unit is configured such that an illumination optical axis is controlled to change in an up-down direction based on the positional information of the object.

A vehicle lamp includes a light source and a compound optical lens that emits light forward. The compound optical lens has an incidence surface, an emission surface, and a shade part. The emission surface emits the light received by the incidence surface forward. The shade part is disposed between the incidence surface and the emission surface. The compound optical lens has first and second reflector surfaces. The first reflector surface reflects light forming a first light distribution pattern toward the emission surface. The second reflector surface reflects light forming a condensed-light distribution pattern toward the emission surface. The width of the first reflector surface is larger than the width of the second reflector surface in a vehicle width direction at a position where the first reflector surface and the second reflector surface are adjacent to each other.

A light source unit of a vehicle lighting system includes: a light source to emit excitation light; a light generating unit including a luminescent layer to emit generation light by being irradiated with the excitation light and a holding member holding the luminescent layer; and a lens member to output generation light from the luminescent layer toward the front, with the light source unit mounted on the vehicle.

A vehicle lamp includes a light source and a compound optical lens that emits light forward. The compound optical lens has an incidence surface, an emission surface, and a shade part. The emission surface emits the light received by the incidence surface forward. The shade part is disposed between the incidence surface and the emission surface. The compound optical lens has first and second reflector surfaces. The first reflector surface reflects light forming a first light distribution pattern toward the emission surface. The second reflector surface reflects light forming a condensed-light distribution pattern toward the emission surface. The width of the first reflector surface is larger than the width of the second reflector surface in a vehicle width direction at a position where the first reflector surface and the second reflector surface are adjacent to each other.

A light source device includes a semiconductor light-emitting device which emits coherent excitation light, and a wavelength conversion element which is spaced from the semiconductor light-emitting device, generates fluorescence by converting the wavelength of the excitation light emitted from semiconductor light-emitting device, and generates scattered light by scattering the excitation light. The wavelength conversion element includes a support member, and a wavelength converter disposed on the support member. The wavelength converter includes a first wavelength converter, and a second wavelength converter which is disposed around the first wavelength converter to surround the first wavelength converter in a top view of the surface of the support member on which the wavelength converter is disposed. The ratio of the intensity of fluorescence to that of scattered light is lower in the second wavelength converter than in the first wavelength converter.

A light source device includes a semiconductor light-emitting device which emits coherent excitation light, and a wavelength conversion element which is spaced from the semiconductor light-emitting device, generates fluorescence by converting the wavelength of the excitation light emitted from semiconductor light-emitting device, and generates scattered light by scattering the excitation light. The wavelength conversion element includes a support member, and a wavelength converter disposed on the support member. The wavelength converter includes a first wavelength converter, and a second wavelength converter which is disposed around the first wavelength converter to surround the first wavelength converter in a top view of the surface of the support member on which the wavelength converter is disposed. The ratio of the intensity of fluorescence to that of scattered light is lower in the second wavelength converter than in the first wavelength converter.

Intrinsically safe laser sourced illumination. A system for illumination is disclosed, including a plurality of laser illumination sources configured to transmit laser beams; a dichroic mirror spaced from the plurality of laser illumination sources and having an aperture configured to allow the laser beams to pass through the dichroic mirror, the remaining surfaces of the dichroic mirror configured to reflect the laser beams; a phosphor element spaced from the dichroic mirror and coated with a substance to fluoresce when struck by the laser beams and configured to disperse the laser beams and to output combined light that includes fluorescent light and the dispersed laser beams; and an illumination output arranged to receive the combined light from the phosphor element and to output illuminating light containing both the fluorescent light and the dispersed laser beams. Methods are also disclosed.

Intrinsically safe laser sourced illumination. A system for illumination is disclosed, including a plurality of laser illumination sources configured to transmit laser beams; a dichroic mirror spaced from the plurality of laser illumination sources and having an aperture configured to allow the laser beams to pass through the dichroic mirror, the remaining surfaces of the dichroic mirror configured to reflect the laser beams; a phosphor element spaced from the dichroic mirror and coated with a substance to fluoresce when struck by the laser beams and configured to disperse the laser beams and to output combined light that includes fluorescent light and the dispersed laser beams; and an illumination output arranged to receive the combined light from the phosphor element and to output illuminating light containing both the fluorescent light and the dispersed laser beams. Methods are also disclosed.