There is provided a vehicular component which include an illumination device capable of favorably illuminating the periphery of a host vehicle. There is provided a vehicular component that includes an illumination device (3) installed on a roof part (30) and configured to cover a vehicle interior space from above. The illumination device (4) includes a light source unit (100) and a light emitting unit (300). The light emitting unit (300) configured to emit light by light emitted from the light source unit (100) is provided along an outer peripheral edge (31) of the roof part (30) in a top view of the vehicle (1).

A light-emitting apparatus includes a first light guide, a converter, a second light guide, and a return. The first light guide includes a first photoreceptor, a second photoreceptor, and a leak. The first light guide guides first light radiated by a radiation apparatus and received by the first photoreceptor and the second photoreceptor. The leak allows second light to be leaked out in a direction crossing a light-guiding direction. The second light is part of the first light. The converter is disposed along the first light guide and converts a wavelength of the second light leaked out of the first light guide. The second light guide does not include the leak and guides third light radiated by the radiation apparatus toward the second photoreceptor. The return returns the third light guided by the second light guide.

A lighting device is provided that includes a light source and an optical element. The light source emits primary light having a primary emission characteristic. The optical element has a light entry face and a light exit face. The optical element includes light guiding elements each forming part of the light entry and exit faces. The light entry faces inject the primary light into the optical element. The light guiding elements each have a boundary surface that totally internally reflects the primary light so that the light exit face emits a secondary light. The optical element reduces a divergence of the primary light such that the secondary light has a secondary emission characteristic with an emission angle (?) that is smaller than an emission angle (?) of the primary emission characteristic. The light exit face is larger than the light entry face.

An electrical device includes a circuit board (101), a light source (104), and a light guide (105). The light guide receives light from the light source and conducts the received light to an end of the light guide so that the light crosses, in a direction parallel with the circuit board, an edge of the circuit board. The end of the light guide constitutes a display surface for showing the light to a user. On a fringe area extending from the edge of the circuit board a distance (D) towards the opposite edge of the circuit board, the light guide is between geometrical planes parallel and coinciding with surfaces of the circuit board. Hence, the light guide does not require room in directions perpendicular to the circuit board. Therefore, for example, more connectors, key buttons, and/or other instruments can be placed on a control panel of the electrical device.

An illuminated indicator for a doorbell can be arranged to receive light along an optical axis (e.g., that is perpendicular to a front face of the doorbell housing) and emit the light from an output portion that defines a closed loop (e.g., that extends around the optical axis) and in a direction that is parallel to the optical axis. The illuminated indicator can include a light pipe that receives light along the optical axis and reflects the light to follow a radially outward and divergent path, e.g., that is perpendicular to the optical axis. The radially outward and divergent light can be reflected to follow a path that is parallel to the optical axis for emission at an output portion of the light pipe. The light pipe can be configured to transmit a doorbell switch activation force to other parts of the doorbell to cause actuation of the switch.

A light-emitting apparatus includes a first light guide, a converter, a second light guide, and a return. The first light guide includes a first photoreceptor, a second photoreceptor, and a leak. The first light guide guides first light radiated by a radiation apparatus and received by the first photoreceptor and the second photoreceptor. The leak allows second light to be leaked out in a direction crossing a light-guiding direction. The second light is part of the first light. The converter is disposed along the first light guide and converts a wavelength of the second light leaked out of the first light guide. The second light guide does not include the leak and guides third light radiated by the radiation apparatus toward the second photoreceptor. The return returns the third light guided by the second light guide.

A variable lighting apparatus allows the light to selectively enter the plurality of optical fibers by changing the position of the light output member having a circular plate shape in the state in which the number of light sources is minimized, such that the optical fibers simultaneously or individually emit light, and thus the patterns in which the light is to be outputted are diversified. In addition, the variable lighting apparatus may minimize the number of required light sources and implement various lighting images only by using the light output member, thereby reducing the manufacturing costs and simplifying the structure.

A medical lighting device, a system for fluorescence image guided surgery and a method to manufacture a medical lighting device are provided. The medical lighting device includes a device body and light guiding optics. The light guiding optics comprise optical fibers and a first ring-shaped mirror encircling the device body. A segment of each optical fiber passes through the first ring-shaped mirror while being guided towards the distal end. After passing through the first ring-shaped mirror, a light guiding element redirects one or more of excitation light and white light ack towards the first ring-shaped mirror. The first ring-shaped mirror reflects the one or more of the emitted excitation light and the white light towards the area to be illuminated by the one or more of the excitation light and the white light.

A semiconductor incandescent lamp retrofit lamp may include: at least one semiconductor light source, at least one light scattering body, and at least one optical waveguide, into which light of the at least one semiconductor light source can be coupled, wherein the at least one light scattering body is configured and arranged for the purpose of diffusely emitting light supplied thereto from the at least one semiconductor light source by way of the at least one optical waveguide.

A system for forming illuminated poured surfaces is provided. The system embeds fiber optic strands into poured surfaces during the formation thereof. Each fiber optic strand may be supported by a positioning apparatus prior to and during the pouring and setting of the poured surface, wherein no part of the positioning apparatus is visible above a top surface of the operable poured surface, yet the fiber optic strands are exposed near the top surface so as to form desired patterns of points of light.