Abstract: A lighting device (100) comprising a collimator (112) having an entrance aperture and an exit aperture (302), a crossed beam splitter (106, 206) and at least four lighting units. Each of the lighting units comprises a light source (102) and a focusing element (104) having an entrance aperture (308) arranged to receive light from the light source (102) and an exit aperture (304). The focusing element (104) is configured to focus light towards the beam splitter (106, 206), and the crossed beam splitter is arranged to receive light from each of the lighting units and configured to split the light from each light source into four beams. Further, the beam splitter (106, 206) is arranged and configured such that said four beams are directed towards the entrance aperture of the collimator (112). The collimator (112) is configured to interact with said beams to provide four images, each image comprising one fourth of the light from each lighting unit.

Abstract: An optical system for collimation of incoming light, comprising: a body (102); a recess (110) formed on a first side (104) of the body (102), the recess (110) having a central light entry surface (114) and a side light entry surface (112); a central light exit surface (118) provided at a second side of the body (108), which second side (108) is opposite to said first side (104); said central light entry surface (114) being arranged in relation to the central light exit surface (118) such that incoming light falling on the central light entry surface (114) is directed to the central light exit surface (118), a total internal reflection surface (116) provided at a side surface of the body (102), which is arranged such that incoming light falling on the side light entry surface (112) of the recess (110) is directed towards the total internal reflection surface (116) so as to be subject to total internal reflection towards the second side (108) of the body (102); and a rejection area (120) surrounding said centra

Abstract: A luminaire has a light source and a shell integrator. The shell integrator has a transparent dome over the light source, with inner and outer surfaces formed as arrays of lenslets. Each lenslet of the inner surface images the light source onto a respective lenslet of the outer surface, and each lenslet of the outer surface images the respective lenslet of the inner surface as a virtual image onto the light source. The dome may be substantially hemispherical. The light source and the integrator may be at an input of a collimator.

Abstract: An optical system for producing uniform illumination on a target, comprising a lens body (204), a recess (202) formed on a bottom side of the lens body (204) at a central region thereof accommodating a light source arranged in an integration zone (206), the recess (202) having a side entry surface (208) and a central entry surface (210), a total internal reflection surface (212) provided at a side surface of the lens body (204), wherein the total internal reflection surface (212) comprises a plurality of first lenslets (216); and an exit surface (214) provided at a top side of the lens body (204), the exit surface (314) comprising a plurality of second lenslets (218), wherein each of the first lenslets (216) forms a pair (220) with each of the second lenslets (218), wherein the first lenslet (216) of the pair (220) focuses light from the integration zone (206) upon the second lenslet (218) of the pair (220), and wherein the second lenslet (218) of the pair (220) focuses the target upon the first lenslet (216)

Abstract: The present invention relates to an illumination device (1) for providing a controllable illumination configuration. The illumination device comprises a light-source unit (2; 20) comprising a plurality of individually controllable solid state light-sources (8); and an optical element (3) arranged to modulate light from the solid state light-sources through a modulation area (16) of the optical element (3). The illumination device (1) further comprises an actuator (4) connected to the light-source unit (2) and controllable to move the light-source unit relative to the optical element (3) in such a way that the solid state light-sources (8) pass the modulation area (16) of the optical element (3) in succession; and a control unit (5) configured to control each of the solid state light-sources (8) to emit light with a time-varying intensity corresponding to the illumination configuration while the solid state light-source (8) moves past the modulation area of the optical element.

Abstract: The present invention relates to an optical arrangement (1) having an optical axis (X) and comprising a base member (70), a cup shaped reflector (10) having an inner surface (12) facing towards the optical axis, at least one solid state light source (40, 42) arranged at the optical axis on the base member, and a lens comprising a center lens portion (20) and an annular lens portion (30), and arranged in front of the at least one solid state light source in a light exit direction. The center lens portion has a dome shaped outer surface (22) and the annular lens portion has an outer surface (32) with a convex shape facing the inner surface of the reflector. The reflector and the lens are formed together as one solid piece of material.

Abstract: According to an embodiment of the present inventive concept there is provided an arrangement 4 comprising: an optical device 8 including a radially inner beam forming portion 10 and a radially outer portion 12, at least partly enclosing the radially inner portion 10. The arrangement 4 further comprises a reflector 6 arranged to reflect, in a first direction towards the radially outer portion 12, light emitted by a light source 2 such that a first optical path is formed from the light source 2 to the radially outer portion 12, via the reflector 6. The radially outer portion 12 is transparent such that incident light reaching the radially outer portion 12 along the first optical path exits the radially outer portion 12 in a direction parallel to the first direction, and at least one of scattering and attenuating for light reaching the radially outer portion 12 along a second optical path extending directly between the light source 2 and the radially outer portion 12.

Abstract: The invention relates to a lighting device (1) comprising a housing (8) with a light source connector for a LED (11) and a reflective collimator (3) and a refractive collimator (9) as well as to a method for their manufacture. The reflective collimator (3) comprises a plurality of reflective segments (4, 4?, 5, 5?, 6, 6?, 7, 7?), which are spaced apart from each other by means of air slits suitable for dissipation of heated air. The segments (4, 4?, 5, 5?, 6, 6?, 7, 7?) are adapted to reflect laterally emitted light generated by the light source (11) towards a direction which is substantially parallel to said main direction. Lighting devices according to this invention may have a compact design and an improved dissipation of the heat generated by the LEDs.

Abstract: The present invention relates to an illumination device (1) for providing a controllable illumination configuration. The illumination device comprises a light-source unit (2; 20) comprising a plurality of individually controllable solid state light-sources (8); and an optical element (3) arranged to modulate light from the solid state light-sources through a modulation area (16) of the optical element (3). The illumination device (1) further comprises an actuator (4) connected to the light-source unit (2) and controllable to move the light-source unit relative to the optical element (3) in such a way that the solid state light-sources (8) pass the modulation area (16) of the optical element (3) in succession; and a control unit (5) configured to control each of the solid state light-sources (8) to emit light with a time-varying intensity corresponding to the illumination configuration while the solid state light-source (8) moves past the modulation area of the optical element.

Abstract: A folded circularly symmetric illumination optic comprising a first light transfer mode having a first central refractive surface and a second central refractive surface, wherein one of the first and second central refractive surfaces has at least one peened feature; a second light transfer mode having a first refractive surface, a first TIR surface, a second TIR surface and a second refractive surface; a third light transfer mode having a first refractive surface, a first TIR surface and a second refractive surface, wherein the first TIR surface has at least one peening feature, and wherein the second refractive surface is conical; wherein the first TIR surface and second refractive surface of the second light transfer mode is coincident at least one point, wherein the second refractive surface of the third light transfer mode is coincident with the first TIR surface and second refractive surface of the second light transfer mode.

Abstract: The present embodiments provide methods and systems to homogenize illumination on a target.

Abstract: A luminaire has a light source and a shell integrator. The shell integrator has a transparent dome over the light source, with inner and outer surfaces formed as arrays of lenslets. Each lenslet of the inner surface images the light source onto a respective lenslet of the outer surface, and each lenslet of the outer surface images the respective lenslet of the inner surface as a virtual image onto the light source. The dome may be substantially hemispherical. The light source and the integrator may be at an input of a collimator.

Abstract: Some embodiments provide an illumination optical system. The optical system can include a first surface and a second surface. Each of the first and second surfaces can further comprises a multiplicity of corresponding Cartesian-oval lenticulations such that each lenticulation of the first surface focuses a source upon a corresponding lenticulation of the second surface and each lenticulation of the second surface focuses a target upon a corresponding lenticulation of the first surface.

Abstract: A folded circularly symmetric illumination optic comprising a first light transfer mode having a first central refractive surface and a second central refractive surface, wherein one of the first and second central refractive surfaces has at least one peened feature; a second light transfer mode having a first refractive surface, a first TIR surface, a second TIR surface and a second refractive surface; a third light transfer mode having a first refractive surface, a first TIR surface and a second refractive surface, wherein the first TIR surface has at least one peening feature, and wherein the second refractive surface is conical; wherein the first TIR surface and second refractive surface of the second light transfer mode is coincident at least one point, wherein the second refractive surface of the third light transfer mode is coincident with the first TIR surface and second refractive surface of the second light transfer mode.

Abstract: A light funnel collimator has a central lens surface and a back reflecting surface, shaped to provide a wider back-ground beam and a narrower hotspot beam within but off-center of the wider beam. One of the beams is on-axis of the collimator, and the other beam is off-axis. The reflector is at least partly asymmetrical relative to the axis, and provides or contributes to the off-axis beam.

Abstract: An optical device for coupling the luminous output of a light-emitting diode (LED) to a predominantly spherical pattern comprises a transfer section that receives the LED's light within it and an ejector positioned adjacent the transfer section to receive light from the transfer section and spread the light generally spherically. A base of the transfer section is optically aligned and/or coupled to the LED so that the LED's light enters the transfer section. The transfer section can comprises a compound elliptic concentrator operating via total internal reflection. The ejector section can have a variety of shapes, and can have diffusive features on its surface as well, including a phosphor coating. The transfer section can in some implementations be polygonal, V-grooved, faceted and other configurations.

Abstract: A cylindrical light source comprises multiple LEDs mounted on either the exterior or interior surface of the cylinder, with heat-sink fins respectively on its interior or exterior. The LEDs emit radially, but their emission is redirected along the cylinder axis by individual ellipsoidal reflectors.

Abstract: The present embodiments provide systems, backlights, films, apparatuses and methods of generating back lighting. Some embodiments provide backlights that include a cavity with at least one interior light source and diffusely reflecting wall of high reflectivity, a top surface with multiple intermittently spaced holes allowing exit of light generated by the light sources, and external collimators extending from each of the holes such that the external collimators spatially expand and angularly narrow the light exiting the holes.

Abstract: The present embodiments provide methods and systems for use in providing enhanced illumination. Some embodiments include at least two light sources and one or more smoothly rotating wheels, where the one or more wheels comprises at least one mirror sector, the circumferential portion of the mirror sector is the inverse of the number of said sources, a first source of the sources is so disposed that the mirror sector reflects light from the first source into a common output path, where the first source pulsing such that a duty cycle of the first source corresponds to a time the mirror sector reflects light from the first source into the common output path.

Abstract: An array of reflectors that transform a collimated beam into one that uniformly illuminates a specific patch of target surface, in particular obliquely presented rectangles, such as billboards. Each reflector is square, with a concave shape that uniformly illuminates a rectangular target. An algorithm is disclosed for producing a shape appropriate for any given illumination geometry. An array of such reflectors can be utilized with a nonuniform collimated beam and still produce uniform illumination. Hexagonal reflectors could also be arrayed to illuminate a hexagon, or an obliquely presented circle in the case of a collimated input beam with some divergence, which causes a blurring of the cutoff at the edges of the target. Non-tiling shapes such as alphanumeric characters will require some of the light of the collimated beam to be discarded. Reflector shapes and methods of calculating such shapes are also disclosed.