The present invention provides a display cover, which includes a light transmission layer, a window pattern disposed on the light transmitting layer, at least one light source disposed on the light transmission layer or the window pattern, and a light conduction layer disposed on the light transmission layer to cover the window pattern and the at least one light source. The window pattern is designed corresponding to a predetermined pattern, so as to define a light transmission window of the predetermined pattern in the light transmission layer. Moreover, at least one light guide structure is disposed on one side of the light conduction layer facing away from the light transmission layer. The at least one light guide structure is configured to at least partially guide light emitted from the at least one light source to the light transmission window.

An automobile comprises a light transmitting film with a thickness not greater than 0.5 millimeters with a core layer, a lightguide region of the film comprises a light emitting region with light extracting features positioned to receive and extract light from at least one light source propagating by total internal reflection within the core layer out of the core layer, and a light mixing region positioned between the at least one light source and the light emitting region, wherein a surface of the portion of the automobile is visible through the light emitting region of the film when the at least one light source is not emitting light and the light transmitting film is conformal with the surface of the portion of the automobile. The surface of the film may have arcuate cross-sectional shape conforming to a curved surface of the portion of the automobile.

A method for manufacturing an electronic product, including obtaining a flexible, optically substantially transparent or translucent, substrate sheet, printing, by an additive printed electronics process, a plurality of electrical conductors on the substrate sheet, printing or disposing, a plurality of electronic components including optoelectronic light emissive components on the substrate sheet, at least some of the printed conductors being configured to provide electrical current thereto, providing at least one graphic on the substrate sheet, the at least one graphic configured to enable outcoupling of light, and attaching a flexible, optically substantially transparent, lightguide sheet to the substrate sheet to establish a multi-layer structure, the light emitted by the light emissive components being received by the lightguide sheet, propagating therewithin, and then being at least partly emitted to the environment through the at least one graphic.

A multicolor display apparatus displays a design pattern by reflecting light beams which are incident into a light guide body by arrays of fine shapes and emitting the reflected light beams from the light emission surface, in which, when it is assumed that the gradation values of red, green, blue, and white at a point where a specific color (to be displayed) of the design pattern of the light guide body is displayed using red, green, blue, and white light are set as I(r). I(g). I(b), and I(w), respectively, and when it is assumed that the gradation values of red, green, and blue in the case of displaying a color close to the specific color using only red, green, and blue light without white light are set as Ir, Ig, and Ib, respectively, the fine shapes for each of red, green, blue, and white colors have a height or a pitch which corresponds to the gradation values I(r), I(g), I(b), and I(w) as follows: I(w)=min(Ir, Ig, Ib), ×A/100; I(r)=Ir−I(w); I(g)=Ig−I(w); I(b)=Ib−I(w). Here, A/100 is less than 1. Thus, it is possible to realize a beautiful white color and realize display which has high color reproducibility without influence due to a machining error and allows a user to feel beautiful.

A light guide body rotates integrally with an operation knob, has an incident surface that is a concavely curved surface recessed to a side opposite to a light source side, and rotates about a rotation shaft located so as to intersect the incident surface of the light guide body. The incident surface of the light guide body is a concavely curved surface recessed toward the side opposite to the light source (toward a Z1 direction) on a cross-section taken along an X-Z plane.

A method for making a wide-area illumination panel that uses solid-state light sources is disclosed. The method includes providing a back sheet, a front sheet approximately the same size as the back sheet, and a light emitting panel comprising one or more solid-state light sources and having an area smaller than the front sheet. One or more strips of double sided adhesive tape or other adhesive material with a thickness approximately equal to or greater than the total thickness of the light emitting portion of the light emitting panel are also provided. The light emitting panel is placed between the front and back sheets, and the front sheet is attached to the back sheet along one or more perimeter edges using the adhesive tape or the adhesive material, creating a thin and hollow sheet-like structure enclosing at least part of the light emitting panel.

A light guide film of a mobile device and a mobile device are provided. The light guide film includes a light insulation structure that divides the light guide film into different light guide regions. Each light guide region includes a light inlet configured to receive light from a light source. Different light guide regions correspond to light-transmitting symbols on the mobile device are configured to display different colors.

A backlight assembly includes a reflection sheet, a light-shielding sheet, two light-emitting elements, and a light guide plate. The reflection sheet is disposed on a circuit board and has two through holes. The light-shielding sheet is disposed on the reflection sheet and has a hollow portion having a closed contour. The light-emitting elements are disposed on the circuit board, respectively accommodated in the through holes, and located in the hollow portion. The light guide plate is embedded in the hollow portion and includes two light guide regions. Each of the light guide regions has a light mixing region and a light outputting region. A corresponding one of the light-emitting elements and the light outputting region are respectively located on opposite sides of the first light mixing region. The light-shielding sheet further has a light blocking portion disposed between the light guide regions.

A lighting assembly adapted for placement upon an article of furniture and/or securement to a wall, including: a frame/housing sub-assembly; an electronics sub-assembly; and a display sub-assembly, wherein the display sub-assembly comprises a first substrate, a second substrate, and a third substrate, wherein the substrates cooperatively interact to provide one or more lighted motion effects.

Materials and lightguides formed thereof that are suitable for use in lighting units to impart a color filtering effect to visible light. At least a portion of such a lightguide (16) is formed of a composite material comprising a polymeric matrix material and an inorganic particulate material that contributes a color filtering effect to visible light passing through the composite material, and the particulate material comprises a neodymium compound containing Nd.sup.3+ ions.