A side-edge type surface light emitting apparatus includes: a light guide plate having a first light emitting surface, a light distribution controlling surface opposing the first light emitting surface and a light incident surface; a light source disposed on the light incident surface; a first prism sheet having multiple first prisms opposing the first light emitting surface and a second light emitting surface opposing the multiple first prisms; a light absorbing sheet opposing the light distribution controlling surface; and a second prism sheet having a flat surface opposing the light distribution controlling surface and multiple second prisms opposing the light absorbing sheet, the multiple second prisms being perpendicular to the light incident surface of the light guide plate.

According to one implementation an assembly is provided that includes an end emitting optical that is configured to end emit bacterial disinfecting light. A portion of the length of the end emitting optical fiber resides in a lumen of a body. The body has an internal disinfecting target area. The end emitted bacterial disinfecting light is configured to impinge on one or more surfaces disposed on or in the body, the one or more surfaces being configured to alter the trajectory of the bacterial disinfecting light so that the bacterial disinfecting light is directed toward the disinfecting target area via a designated disinfecting light pathway.

A semiconductor package and a manufacturing method thereof are provided. The semiconductor package includes a photonic die, an encapsulant and a wave guide structure. The photonic die includes a substrate and a dielectric layer. The substrate has a wave guide pattern. The dielectric layer is disposed over the substrate. The photonic die is encapsulated by the encapsulant. The wave guide structure spans over the front side of the photonic die and a top surface of the encapsulant, and penetrates the dielectric layer to be optically coupled with the wave guide pattern.

Methods for providing flammability protection for plastic optical fiber (POF) embedded inside avionics line replaceable units (LRUs) or other equipment used in airborne vehicles such as commercial or fighter aircrafts. A thin and flexible flammability protection tube is placed around the POF. In one proposed implementation, a very thin (100 to 250 microns in wall thickness) polyimide tube is placed outside and around the POF cable embedded inside an LRU or other equipment. The thin-walled polyimide tube does not diminish the flexibility of the POF cable.

A molded component assembly includes a printed circuit board with a first face and an oppositely facing second face. Multiple light emitting diodes are mounted on a first portion of the first face. Multiple electronics components are mounted on a second portion of the first face. A light guide of a light translucent polymeric material has a contact surface, multiple light outlets, and multiple light emitting diode receiving pockets defining recesses in the contact surface, each sized to receive one of the light emitting diodes when the contact surface directly contacts the first portion of the first face, with visible light from the light emitting diodes transmitted through the light guide to the light outlets. A first polymeric material is molded over a portion of the second portion of the first face encapsulating the electronics components and contacting a portion of the light guide.

An optical waveguide-forming material has a low propagation loss even in a long wavelength region and has a high refractive index at a wavelength of 1,550 nm. An optical waveguide-forming composition includes (a) 100 parts by mass of a reactive silsesquioxane compound that is a polycondensation product of an alkoxysilane compound A of the following Formula [1]:

Ar.sup.1Si(OR.sup.1).sub.3[1]

and an alkoxysilane compound B of the following Formula [2]:

Ar.sup.2Si(OR.sup.2).sub.3[2]

and (b) 10 to 500 parts by mass of a fluorene compound of the following Formula [3]:

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An optical waveguide can be formed by using the composition.

The disclosed embodiments generally relate to extruding multiple layers of micro- to nano-polymer layers in a tubular shape. In particular, the aspects of the disclosed embodiments are directed to a method for producing a Bragg reflector comprising co-extrusion of micro- to nano-polymer layers in a tubular shape.

An optical waveguide and manufacturing method thereof, display substrate and display device. The optical waveguide comprises an optical fiber array arranged on a surface where each optical fiber in the optical fiber array has a cylindrical shape and the axis of each optical fiber is perpendicular to the surface. With the effect of limitation and mixing of the optical fibers, the intensity and color of the light from the optical waveguide are basically homogeneous in the whole emitting range, such that the viewing angle characteristics of the display device are effectively improved and the problem of uneven brightness and color bias in the range of viewing angle is solved.

An optical waveguide and manufacturing method thereof, display substrate and display device. The optical waveguide comprises an optical fiber array arranged on a surface where each optical fiber in the optical fiber array has a cylindrical shape and the axis of each optical fiber is perpendicular to the surface. With the effect of limitation and mixing of the optical fibers, the intensity and color of the light from the optical waveguide are basically homogeneous in the whole emitting range, such that the viewing angle characteristics of the display device are effectively improved and the problem of uneven brightness and color bias in the range of viewing angle is solved.

An illumination structure of the present invention is an illumination structure that lights a sunshade or a glass roof. The illumination structure includes: a frame-like first bracket coupled to a headliner along the circumferential edge of a headliner opening for reinforcing the headliner opening; a frame-like second bracket coupled to the first bracket so as to be overlaid on the back side of the first bracket for reinforcing the headliner opening in cooperation with the first bracket; and a light emitter held between the first bracket and the second bracket. Light from the light emitter is emitted through a gap between the first bracket and the second bracket.