A lamp for the rear of a vehicle is disclosed with a light transmissive cover having a red first illuminated surface area and a clear second illuminated surface area. It has a first LED light emitter located directly beneath the red first area, a second LED light emitter located directly beneath the clear second area, and a third LED light emitter, also located directly beneath said clear second area. The third red LED light emitter is for emitting red light through the clear second area simultaneously with light transmitted through the red first area, whereby the first and second areas are adapted to collectively form a contiguous red illuminated surface area.

A first light source device emits first light having a first wavelength. A second light source device emits second light having a second wavelength longer than the first wavelength. A splitting unit is configured to split the first light into third light having a third wavelength same as the first wavelength and fourth light having a fourth wavelength same as the first wavelength. A wavelength converter is configured to be excited by the third light to emit fifth light having a luminescence peak at a fifth wavelength between the third wavelength and the second wavelength. A combining optical system is configured to combine the second light, the fourth light, and the fifth light together. A control device is configured to control a light output of the second light source device and a split ratio between the third light and the fourth light in the splitting unit.

A light source can include at least one light emitter and is configured to emit a first light during a region of a light period and emit both the first light and a second light of a different wavelength during a remaining region of the light period. The emitter can include semiconductor layers and an active layer configured to emit light having a specific wavelength due to a band gap difference in an energy band depending on a material used to form the active layer. A plant cultivation device can include the light source and a main body in which a plant can be grown. The light period can be configured to increase a content of an active ingredient in the plant. The first light can have a longer peak wavelength than a peak wavelength of the second light.

A light module includes a first light emitter, a second light emitter, a third light emitter, and a controller. The first light emitter is configured to emit a first light having a first peak wavelength in a visible range, the second light emitter is configured to emit a second light having a waveform having a second peak wavelength higher than the first peak wavelength, and the third light emitter is configured to emit a third light having a third peak wavelength that is shorter than the first peak wavelength. The controller is configured to control the first light emitter, the second light emitter, and the third light emitter to generate a first light pattern and a second light pattern. The first light pattern comprises a first light spectrum and the second light pattern comprises a second light spectrum including at least one more peak wavelength than the first light spectrum.

A LIGHTING DEVICE for illuminating an aquarium (100), comprising: a base layer (111, 611); a plurality of lighting elements (111, 112, 113, 212, 213) mounted on the base layer (111, 611) and comprising a first and a second subset (630A) of lighting elements (111, 112, 113, 212, 213) arranged for emitting a first and a second spectrum of light respectively; a light transmission affecting device arranged for affecting the transmission of light from the plurality of lighting elements (111, 112, 113, 212, 213); wherein the light transmission affecting device is arranged for passing (420) at least a part of the light from at least one lighting element (112, 212, 213, 312) of the first subset (112) having the first emitting spectrum and processing (430) the light from at least one lighting element (112, 212, 213, 312) of the second subset (630A) having the second emitting spectrum; wherein the first emitting spectrum comprises white light or a first colored light; wherein the first colored light comprises wavelength in a first range with peak wavelength below (485) 485 nm; and the second emitting spectrum comprises a second colored light; wherein the second colored light comprises wavelength in a second range with a peak wavelength larger than 485 nm.

White light luminaire for everyday activities that regenerates the retina of the eye in real time, damaged by blue light, contains at least one blue chip covered by a luminophore with the maximum of the radiated energy at the wavelength =670 to 680 nm, whereas the ratio between the blue spectral component from the wavelength range 400 to 490 nm and the green spectral component from the wavelength range 490 to 570 nm is 1:1.6 max., or the ratio between the green spectral component from the wavelength range 490 to 570 nm and the red spectral component from the wavelength range 570 to 780 nm is 1:3 min.

A light assembly includes a light fixture detachably coupled to a mounting subassembly that secures around a firehose nozzle. The light fixture incorporates a housing having a front side formed with a plurality of front apertures, a back side, top side, bottom side, and plurality of lateral sides, one of which carries a side aperture. A plurality of light sources is positioned at the front apertures to emit light in the same direction as the nozzle discharge, while a battery is situated between the light sources and the back side to create a low-profile silhouette. The light fixture and the mounting subassembly comprise complementary interlocking mechanisms for providing fast installation and detachability of the light fixture with the mounting subassembly.

A system for generating white light comprising a plurality of channels to generate light with color points that fall within blue, yellow/green, red, and cyan color ranges, with each channel being driven with a separately controllable drive current to tune the generated light output.

A lighting system and luminaire replicates attributes of natural sunlight and the sky. An array of light emitters capable of emitting light closely mimicking natural sunlight. This emitted light features an adjustable correlated color temperature (CCT) that spans from 1900 K to 6500 K, faithfully reproducing the Sun's appearance across different times of the day. To ensure precision in spectral matching, the system operates within a defined wavelength range of 400 nm to 1400 nm. At least one light emitter with a wavelength within the range of 760 nm to 1400 nm is incorporated to guarantee accurate representation. A luminaire equipped with a panel interacts with the multitude of light emitters, proficiently emitting color-tunable light and simulating diverse sky scenes. To facilitate control and customization, a dedicated control system is seamlessly integrated into the luminaire, enabling precise adjustment of the correlated color temperature and spectral power distribution.

The embodiments disclose an underwater video light system including a chip-on-board LED light configured to project multiple-colored LED light arrays in an underwater environment from a chip-on-board LED module, at least one colored LED light array from a group consisting of a blue light LED array, bluish green light LED array, and green light LED array, a wide-angle coupled to the chip-on-board LED light configured to project the chip-on-board LED light in a wide angle illumination in the underwater environment, at least one digital processor controller coupled to the chip-on-board LED light configured to regulate power transmission to the chip-on-board LED light module, a rechargeable battery pack, and an LED display coupled to the chip-on-board LED light configured to display operating settings and color selections.