A precision approach path indicator (PAPI) employs an LED light source with first and second arrays of LEDs or other efficient light sources, disposed one above the other and emitting their respective color lights along an optic axis to a collimating lens of focal length f. First and (optional) second aperture plates positioned along the optic axis, each being a respective frame with a cut-out defining a horizontally elongated aperture for light passing along the optic axis. Intermediate aperture plate(s) can be positioned between the first and second aperture plates. The first frame is positioned between the light source and the collimating lens at the focal distance f from the lens. The optional second aperture plate is positioned at the collimating lens and covers top, bottom, and side edge portions of the lens. A planar blade extends from the light source to the first frame and has a distal edge extending across the aperture of the first aperture plate, substantially at the focus of the collimating lens, dividing the beam into white and red sectors. The intermediate aperture plate(s) can be adjusted for optimal separation. The PAPI can be considered to have an illumination portion formed of the light source(s), blade, and first frame; and an imaging portion formed of an enclosure and a lens positioned at its focal length distant from the front frame aperture and edge of the blade.

Disclosed is a flashlight which may include of a first window arranged at a first end of the flashlight, a light source configured to generate light, a first reflector configured to reflect light from the light source to the first window to generate a first beam of light, and a second reflector configured to reflect stray light from the light source through one of a first aperture and a first gap in the first reflector to generate a second beam of light leaving the flashlight through a second window.

An aimer system for an imaging-based indicia scanner includes a diaphragm comprising a light receiving side, a light projecting side positioned opposite the light receiving side, and a light passing aperture extending through the diaphragm from the light receiving side to the light projecting side and having a predetermined shape; a light emitting diode positioned on the light receiving side of the diaphragm; and a lightpipe positioned between the light emitting diode and the diaphragm.

An aimer system for an imaging-based indicia scanner includes a diaphragm comprising a light receiving side, a light projecting side positioned opposite the light receiving side, and a light passing aperture extending through the diaphragm from the light receiving side to the light projecting side and having a predetermined shape; a light emitting diode positioned on the light receiving side of the diaphragm; and a lightpipe positioned between the light emitting diode and the diaphragm.

A beam shading device capable of accurately positioning includes a substrate, a plurality of shading blades mounted on the substrate, and driving mechanisms for driving the shading blades to move. The substrate is provided with a first light-passing hole through which beams pass, the plurality of shading blades are arranged around the periphery of the first light-passing hole, and the driving mechanisms drive the shading blades to move back and forth between blocking and opening the first light-passing hole. Each shading blade is configured with at least two driving mechanisms, and each driving mechanism includes a driving gear and a driving plate. The driving plate is hinged with the shading blade, and the driving plate is provided with a rack that meshes with the driving gear.

A solid state disk is provided, including: a main body, including a shell portion, a substrate which is disposed on the shell portion and a memory module which is disposed on the substrate, the substrate including a transmission port, the memory module being electrically connected to the transmission port; at least one light-emitting portion, disposed on the substrate and electrically connected to the transmission port; at least one scattering light-guiding portion, arranged on the substrate correspondingly to the light-emitting portion without covering any part of the at least one light-emitting portion, each said scattering light-guiding portion having a scattering structure, at least one part of light emitted from each said light-emitting portion projecting toward the scattering structure and the light being scattered evenly via the scattering light-guiding portion to an exterior of the solid state disk.

The current invention make a big improvement than conventional market all kind of LED or-and Laser bulb which only can offer near-by areas illumination, The current invention (1) has more than one bulb-base, or (2) has more than one optics-elements and at least one is optics-lens for 180 of degree flat or ½ ball, ⅔ ball, sphere, dome shape top cover of the said LED or-and Laser Bulb which has refractive optics properties to enlarge the image or lighted patterns to wider range or big area, or (3) has built-in or add-on flexible bendable arms to can change position, or direction or orientation of LED or-and Laser light beam by variety choice of moveable parts, or (4) can offer near-by and far-away illumination, image, lighted patterns, or any combination with all market available light effects or digital data display images, Or (5) has more than one light beam emit out from LED or-and Laser bulb which under controller or IC or circuitry, Or ( ) has more than one function to emit light beam may selected from power failure, remote control, Infra-red controller, blue-tooth, wifi, internet, App software, motion sensor and wireless with multiple-way communication to trigger at least one of the light beam to offer illumination or-and image or-and lighted patterns effects.

A precision approach path indicator (PAPI) employs an LED light source with first and second arrays of LEDs or other efficient light sources, disposed one above the other and emitting their respective color lights along an optic axis to a collimating lens of focal length f. First and (optional) second aperture plates positioned along the optic axis, each being a respective frame with a cut-out defining a horizontally elongated aperture for light passing along the optic axis. Intermediate aperture plate(s) can be positioned between the first and second aperture plates. The first frame is positioned between the light source and the collimating lens at the focal distance f from the lens. The optional second aperture plate is positioned at the collimating lens and covers top, bottom, and side edge portions of the lens. A planar blade extends from the light source to the first frame and has a distal edge extending across the aperture of the first aperture plate, substantially at the focus of the collimating lens, dividing the beam into white and red sectors. The intermediate aperture plate(s) can be adjusted for optimal separation. The PAPI can be considered to have an illumination portion formed of the light source(s), blade, and first frame; and an imaging portion formed of an enclosure and a lens positioned at its focal length distant from the front frame aperture and edge of the blade.

A precision approach path indicator (PAPI) employs an LED light source with first and second arrays of LEDs or other efficient light sources, disposed one above the other and emitting their respective color lights along an optic axis to a collimating lens of focal length f. First and (optional) second aperture plates positioned along the optic axis, each being a respective frame with a cut-out defining a horizontally elongated aperture for light passing along the optic axis. Intermediate aperture plate(s) can be positioned between the first and second aperture plates. The first frame is positioned between the light source and the collimating lens at the focal distance f from the lens. The optional second aperture plate is positioned at the collimating lens and covers top, bottom, and side edge portions of the lens. A planar blade extends from the light source to the first frame and has a distal edge extending across the aperture of the first aperture plate, substantially at the focus of the collimating lens, dividing the beam into white and red sectors. The intermediate aperture plate(s) can be adjusted for optimal separation. The PAPI can be considered to have an illumination portion formed of the light source(s), blade, and first frame; and an imaging portion formed of an enclosure and a lens positioned at its focal length distant from the front frame aperture and edge of the blade.

A user-wearable fluorescence based visualization system comprising a multi-light lamp assembly that provides for the selected output of light using multiple light emitting sources, wherein the outputted light may be tailored to generate response wavelength by the interaction of the emitted light and a tissue illuminated by the emitted light, through the process of fluorescence, and a viewing system that allows a practitioner view the fluorescent light generated by the tissue, and distinguish between healthy and diseased tissues.