A variety of illumination devices are disclosed that are configured to manipulate light provided by one or more light-emitting elements (LEEs). In general, embodiments of the illumination devices feature one or more optical couplers that redirect illumination from the LEEs to a reflector which then directs the light into a range of angles. In some embodiments, the illumination device includes a second reflector that reflects at least some of the light from the first reflector. In certain embodiments, the illumination device includes a light guide that guides light from the collector to the first reflector. The components of the illumination device can be configured to provide illumination devices that can provide a variety of intensity distributions. Such illumination devices can be configured to provide light for particular lighting applications, including office lighting, task lighting, cabinet lighting, garage lighting, wall wash, stack lighting, and downlighting.

A variety of illumination devices are disclosed that are configured to manipulate light provided by one or more light-emitting elements (LEEs). In general, embodiments of the illumination devices feature one or more optical couplers that redirect illumination from the LEEs to a reflector which then directs the light into a range of angles. In some embodiments, the illumination device includes a second reflector that reflects at least some of the light from the first reflector. In certain embodiments, the illumination device includes a light guide that guides light from the collector to the first reflector. The components of the illumination device can be configured to provide illumination devices that can provide a variety of intensity distributions. Such illumination devices can be configured to provide light for particular lighting applications, including office lighting, task lighting, cabinet lighting, garage lighting, wall wash, stack lighting, and downlighting.

An illumination device includes: an optical fiber, the optical fiber allowing light emitted from a light source to be introduced at a first end portion thereof and to be guided through the optical fiber while emitting a portion of the light through a side surface of the optical fiber; a light-transmissive tube, the light-transmissive tube covering the side surface of the optical fiber such that a gap is located between the tube and the side surface of the optical fiber; and a light-shielding cap covering a second end portion of the tube at a side opposite the light source such that a space is located between a bottom portion of the cap and the second end portion of the tube. A second end portion of the optical fiber projects past the second end portion of the tube and is located at an inner side of the cap.

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.

According to aspects of the embodiments, a lighting fixture is designed to help prevent the accumulation of snow or ice on the light emitting face (e.g., lens) of the lighting fixture. The lighting fixture harvests both the light and heat generated by at least one light source, such as but not limited to at least one LED light source. The lighting fixture adopts a flip-mount light source mounting design in which one side of a passive heat exchanger is mounted or secured closely adjacent or proximate to the lens, and the light source is mounted or secured to another side of the passive heat exchanger. The heat generated by the light source is conducted by the passive heat exchanger to heat the lens. Additionally, the light emitted from the light source is redirected back through the passive heat exchanger and to the lens using a bundle of light fiber cables.

A method for manufacturing a display includes providing a plurality of light guiding fibers or other elements extending out from a display screen. The light guiding elements are in a matrix to form a first light guiding body forming a strip along the edges of each individual display screen. The first light guiding bodies form a compensating portion of an image compensating apparatus, a cross-sectional area of each light guiding element increasing from light-collecting end (closest to the display screen) to opposite light-releasing end. The compensating portion includes a light incident surface and a light emitting surface.

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 method for manufacturing a display includes providing a plurality of light guiding fibers or other elements extending out from a display screen. The light guiding elements are in a matrix to form a first light guiding body forming a strip along the edges of each individual display screen. The first light guiding bodies form a compensating portion of an image compensating apparatus, a cross-sectional area of each light guiding element increasing from light-collecting end (closest to the display screen) to opposite light-releasing end. The compensating portion includes a light incident surface and a light emitting surface.

An electronic device such as a wrist band may include a strip of fabric that wraps around a longitudinal axis. A one-dimensional array of light sources may be embedded in the strip of fabric and may emit light parallel to the longitudinal axis to produce edge illumination along an edge of the strip of fabric. Optical structures such as light-diffusing strands, light-diffusing polymer structures, and/or light guides may be located between the light sources and the edge of the strip of fabric to help diffuse light and/or guide light to the edge of the strip of fabric. Light-reflecting layers may be formed on inner surfaces of the fabric. Control circuitry may control the light sources to produce the edge illumination in response to an event occurring on an external electronic device such as a notification on an external display.

Aspects of electronic illuminator systems and methods are disclosed herein, including subsystems and methods of use. In one aspect, a sensory system for an electronic illuminator to detect the presence and color of a fiber optic cable is disclosed. The system comprises a fiber optic cable having a proximal end with a fiber funnel cap and a terminal end with a protective cover. An electronic illuminator that further comprises a housing, a printed circuit board (PCB), a light emitting diode (LED), and a power source. The system further comprises an ambient light sensor, configured within the housing of the electronic illuminator, wherein the ambient light sensor converts light intensity to a digital signal. The system further comprises a fiber detection assembly, having a three dimensional magnetic flux density. Lastly, the system comprises a cap color detection assembly, wherein the cap color detection assembly detects the color of the fiber funnel cap on the proximal end of the fiber optic cable.