An electric candle including a body having a wax-like exterior configured to mimic an appearance of a wax candle, a first non-laser light source disposed at least partially within the body and configured to produce a light which mimics a flame of a wax candle, and a second light source producing a laser light disposed at least partially within the body and including a lens configured to disperse the laser light.

A landscape light including a housing including a first compartment and a second compartment, the first compartment being substantially weather-proofed and the second compartment being in fluid communication with an exterior of the housing, a light source producing a light disposed in the first compartment, and a heatsink for dissipating heat generated by the light source disposed in the second compartment.

A light exposure apparatus emits light which activates the body of the user. The light exposure apparatus includes a blue light source which emits blue light and a red light source which emits red light. The light includes blue light and red light. Blue light has a peak wavelength in a range from 445 nm to 500 nm. Red light has a peak wavelength in a range from 600 nm to 680 nm. The intensity of the peak wavelength of blue light is the strongest in the spectrum of the light, and the intensity of the peak wavelength of red light is the second strongest in the spectrum of the light. The relative intensity of the peak wavelength of the red light with respect to the peak wavelength of the blue light is in a range from 0.1 to 0.5 inclusive.

An optical device for a light fixture can include a quasi-semi-cylindrical outer perimeter that includes a substantially planar bottom surface, a top surface located adjacent to the bottom surface, where the top surface has a curvature, and a pair of side surfaces located adjacent to the bottom surface and the top surface, where the pair of side surfaces are located opposite each other. The optical device can also include a body bounded by the outer perimeter. The optical device can further include an inner optical feature disposed in the body at the bottom surface, where the inner optical feature forms a cavity bounded by multiple segments, wherein each two adjacent segments form an angle relative to each other. The cavity can be configured to receive a light source of the light fixture.

An illumination device comprising a plurality of light sources emitting light along an optical axis, the light sources comprises a converting material capable of converting light into other wave lengths. An optical gate is arranged along the optical axis and a light collector is arranged between the light sources and the optical gate. The light collector comprises a plurality of lenslets adapted to collect light and to convert the collected light into a plurality of light propagate through the optical gate. An optical projecting system collects and projects at a part the light beams along the optical axis. A retro-reflector is arranged between the light collector and the plurality of light sources and is configured to reflect at least a part light back to the converting material of at least one of the light sources.

An ornament with a backlit film image having a curved substrate with a smooth surface and an at least partially transparent portion viewable therethrough when backlit. The backlit film image includes a flat top surface and a flat bottom surface, wherein one of the flat top surface or the flat bottom surface is positioned flush against the smooth surface of the curved substrate when the backlit film image is removably coupled thereto. A first end cap and a second end cap are configured to receive and retain a portion of the substrate such that the first and second end caps and the substrate support one another into a substantially upright position to define an enclosure. An insert removably engages one of the first or second end caps and includes an aperture having a size and shape for compression-fit engagement with a light source.

A lighting device includes a light source, a reflector having an ellipsoidal reflection surface, an aspherical lens, and an exit pupil. The source is arranged at a first focal point of the reflection surface and a part of the emitted light is reflected from the reflection surface in the direction of a second focal point. The pupil is arranged offset with respect to the second focal point. The lens is arranged between the reflection surface and the pupil in a beam path with the reflected light and is shaped such that a first part of the reflected light passes through the lens with an aperture angle altered by not more than 5 in a central region and passes through the pupil and a second part of the reflected light penetrates through the lens in an outer region and is deflected by the lens and is consequently guided through the pupil.

A mirror assembly is provided for producing beam bundles from the beam of a light source, wherein the beam bundles includes a first beam bundle having a first main beam direction, a second beam bundle having a second main beam direction, and preferably further beam bundles having further main beam directions. The assembly includes a first mirror segment having a first focal point, which converts a first partial region of the beam of the light source into the first beam bundle, a second mirror segment having a second focal point, which converts a second partial region of the beam of the light source into the second beam bundle, and preferably further mirror segments having further focal points, which convert further partial regions of the beam of the light source into further beam bundles. The back side of the mirror segments have a curvature which is concentric to the light source.

An system including a housing defining an enclosure and having an aperture in an exterior surface of the housing; a concave reflector, the reflector being disposed on or in the enclosure of the housing to reflect light emissions; a plurality of solid state light sources disposed within the housing to direct light emissions within the enclosure towards the reflector, the plurality of solid state light sources including multiple groups of solid state light sources; and a mixing chamber defined by a space within the enclosure located between the reflector and the aperture, wherein the reflector is configured to reflect light emissions from the plurality of solid state light sources towards the mixing chamber where the reflected light emissions are to combine before exiting the housing through the aperture.

A member for controlling luminous flux according to an exemplary embodiment of the present invention includes an optical path changing unit embedded in a matrix and including scattering particles scattering incident light, and an optical direction adjustment unit including a coupling surface attached to the optical path changing unit to receive the light scattered from the optical path changing unit, and a refractive surface refracting the received light and emitting the refracted light, whereby an optical diffusion performance of the member for controlling luminous flux according to an exemplary embodiment of the present invention can enhance an optical diffusion performance.