A luminous film has a plurality of light-emitting diodes, a carrier layer and a light-conducting layer having microoptical structures which make it possible to deflect multidirectionally emitted light in a common emission direction of the luminous film, in order to allow uniform illumination of the luminous film surface with a low light-emitting diode population of the luminous film.

The present disclosure discloses a transparent lampshade used for solar lamp, comprising a transparent lampshade body, an upper side of the lampshade body is provided with an installing recess for installing a solar luminous lamp assembly, and an upper light-transmitting portion located on a circumference of the installing recess and capable of exposing the solar luminous lamp assembly and transmitting light upwardly. Through cooperation of the installing recess and the upper light-transmitting portion in the disclosure, not only the installation of the solar luminous lamp assembly but also the use effect of light transmission on the upper side can be realized, and the outstanding effect close to the full-lighting even can be achieved, thus to maximally improve lighting effect of the whole solar lamp and bring people a more impressive visual impact, thereby greatly meeting more practical needs and facilitating further innovation and development of industry.

A linear lighting assembly is disclosed which produces tailored light distributions valuable in many illumination applications. The linear lighting assembly comprises a unique light scattering optical element within a single edge lit linear lighting module housing configured to fit within a linear light fixture housing, both housings capable of being fabricated in a continuous extrusion process and cut to length as need for specific linear lighting assembly lengths. Light distributions attainable using the invention include, but are not limited to, symmetric and asymmetric bi-lobed “batwing” distributions for wide area direct and indirect lighting, and tilted or asymmetric distributions for perimeter lighting. It is also possible to achieve more rounded and symmetric distributions by an additional diffuser as a cover lens. The invention is particularly well-suited for linear lighting fixtures that are surface mounted, suspended or recessed. Various embodiments also provide means for adjusting light distributions dynamically to control light output characteristics by controlling the input signals to the LED board included in the assembly.

A linear lighting assembly is disclosed which produces tailored light distributions valuable in many illumination applications. The linear lighting assembly comprises a unique light scattering optical element within a single edge lit linear lighting module housing configured to fit within a linear light fixture housing, both housings capable of being fabricated in a continuous extrusion process and cut to length as need for specific linear lighting assembly lengths. Light distributions attainable using the invention include, but are not limited to, symmetric and asymmetric bi-lobed “batwing” distributions for wide area direct and indirect lighting, and tilted or asymmetric distributions for perimeter lighting. It is also possible to achieve more rounded and symmetric distributions by an additional diffuser as a cover lens. The invention is particularly well-suited for linear lighting fixtures that are surface mounted, suspended or recessed. Various embodiments also provide means for adjusting light distributions dynamically to control light output characteristics by controlling the input signals to the LED board included in the assembly.

An electronic module group can include an electronic module including a first housing defining a housing cavity; a power supply driving module positioned within the housing cavity; and a first concentric terminal connected in electrical communication with the power supply driving module by a first wire and a second wire; and a second concentric terminal rotatably connected in electrical communication with the first concentric terminal, the second concentric terminal configured to transmit power to the first concentric terminal.

A light emitting device comprising: a carrier; a plurality of light sources disposed thereon; a plurality of lenses disposed on the carrier covering the light sources, a light shielding structure comprising reflective barriers having an outer surface and a first reflective inner surface; wherein a light transmitting material extends between the outer surface and the first reflective inner surface, said outer surface being oriented such that part of light rays emitted by a first light source of the plurality of light sources is transmitted through a first lens of the plurality of lenses and through a first portion of said outer surface in the direction f the first reflective inner surface. The first reflective inner surface is configured for reflecting the light rays in the direction of a second portion of said outer surface being located further away from a base portion of the first lens than the first portion.

The invention relates to a luminaire (100), comprising lighting means (18) and a cover (20), which has at least one planar region (25) for emitting light, the planar region for emitting light (25) consisting of a transparent material and being provided, on at least one side, with a structure (26), and a plate-shaped light-influencing element (30) being arranged between the lighting means (18) and the planar region (25) for emitting light, a pattern (35) being printed on the light-influencing element.

Light fixtures and methods of making the same which include an outer container includes a back wall and one or more outer walls extending upward from the periphery of the back wall, wherein the walls of the outer container form a cavity, wherein the one or more surfaces of the one or more outer walls of the outer container that face inward are coated with, painted with or intrinsically have diffuse, white reflecting surfaces, wherein one or more of the inward facing surfaces of the one or more outer walls of the outer container have circuit boards, flexible circuit boards or tapes mounted on or adhered to them, wherein the circuit boards, flexible circuit boards, or tapes have light emitting devices mounted on them, and wherein the cavity formed by the outer walls of the container is filled with a clear, transparent material.

Light fixtures and methods of making the same which include an outer container includes a back wall and one or more outer walls extending upward from the periphery of the back wall, wherein the walls of the outer container form a cavity, wherein the one or more surfaces of the one or more outer walls of the outer container that face inward are coated with, painted with or intrinsically have diffuse, white reflecting surfaces, wherein one or more of the inward facing surfaces of the one or more outer walls of the outer container have circuit boards, flexible circuit boards or tapes mounted on or adhered to them, wherein the circuit boards, flexible circuit boards, or tapes have light emitting devices mounted on them, and wherein the cavity formed by the outer walls of the container is filled with a clear, transparent material.

An illumination apparatus comprises a plurality of LEDs aligned to an array of directional optical elements wherein the LEDs are substantially at the input aperture of respective optical elements. An electrode array is formed on the array of optical elements to provide at least a first electrical connection to the array of LED elements. Advantageously such an arrangement provides low cost and high efficiency from the directional LED array.