A light system comprising: (a) a plurality of printed circuit boards; (b) a plurality of sets of light sources on each of the plurality of printed circuit boards that are configured to provide a different lighting function, wherein each of the plurality of sets of light sources include one or more light source that generates light; (c) a plurality of light bars that distribute the light from each of the plurality of sets of light sources; and (d) one or more light guides on each of the plurality of light bars, wherein each of the one or more light guides is aligned with one or more of the one or more light sources so that the light passes from the one or more light sources into one of the one or more light guides and into one of the plurality of light bars to provide one of the different lighting functions.

A lamp system applied to a vehicle according to the present disclosure is provided with any one of a reflector, an optical member, a digital micromirror display (DMD), a shield, or a shield optical module, and combined with a rotation light source device for generating light of a specific LED turned on at a synchronized rotation position of one or more LED chips of first to Nth LED chips (N is an integer of 2 or more) per one rotation while being rotated by a current application of a signal transmitter receiving a lamp turn-on signal of the vehicle, thereby generating various lighting patterns even while eliminating all problems of increasing the layout/decreasing the light amount/increasing the amount of property changed, lowering the reflection efficiency/transmission efficiency, and losing the optical efficiency with the circular LED array.

Embodiments of the present disclosure provides an electric lighting apparatus for stimulating at least one sensory effect on a user. The electric lighting apparatus comprises one or more light sources arranged to be in contact with a diffuser for causing diffusion of flameless light generated by the one or more light sources, wherein each of the one or more light sources is operable at a time interval. The electric lighting apparatus further comprises an aroma compartment being operable to dispense aroma while providing the diffused flameless light. The electric lighting apparatus further comprises an output unit being operable to provide an audio output, wherein the diffused flameless light, the aroma, and the audio output stimulate the at least one sensory effect on the user.

A vehicle headlight (1), which is one aspect of a vehicle illumination lamp, includes: light sources (52R, 52G, 52B), and diffraction gratings (54R, 54G, 54B) for diffracting light incident from the light sources (52R, 52G, 52B). The light diffracted by the diffraction gratings (54R, 54G, 54B) is irradiated in a predetermined light distribution pattern. A projection area (AR) to which are projected components (LC.sub.R, LC.sub.G, LC.sub.B) advancing and passing through the diffraction gratings (54R, 54G, 54B) among the light incident on the diffraction gratings (54R, 54G, 54B) is positioned below the light distribution pattern and within a range (RNG) in which a field of view of a driver of a vehicle is obstructed by the vehicle.

Disclosed are various embodiments for a lighting system. The lighting system may include a headguard adapted to be worn on a head of an operator, where the headguard comprising a headguard cavity, as well as an elongated flashlight base comprising a flashlight base cavity. A detachable flashlight head is adapted to be positioned in either of the headguard cavity and the flashlight base cavity. The detachable flashlight is sized and positioned such that, when positioned in the headguard cavity, the detachable flashlight magnetically and electrically couples to the headguard. Similarly, the detachable flashlight is sized and positioned such that, when positioned in the flashlight base cavity, the detachable flashlight magnetically and electrically couples to the elongated flashlight base.

A linear luminaire includes a linear channel defining an interior space and a linear light inset configured for being inserted into the channel in the interior space. The light inset includes a cover and a printed circuit board fixed to the cover. The printed circuit board supports a plurality of light emitting diodes. The cover base wall includes a translucent portion. The light emitting diodes are arranged for emitting light through the translucent portion. The cover includes two cover connectors, each configured for being snapped into the channel to hold the cover in the interior space. The cover connectors are on an opposite side of the printed circuit board as the translucent portion.

A luminous device includes a luminous module. The luminous module includes a plurality of LED chips, a driving chip and a package body. The driving chip is configured to selectively drive the LED chips to emit light. The driving chip includes a power pad, a plurality of LED pads corresponding to the plurality of LED chips respectively and a ground pad. The driving chip receives a power signal having a selecting signal and a luminous signal by the power pin, and determines the LED chips to emit light according to the luminous signal or not based on the selecting signal. The luminous device uses the power signal of selecting the LED chip as the driving power for driving the LED chips to emit light in the same time. The luminous device not only reduces the volume, but also saves the cost.

The invention provides a light generating device (1000) configured to generate device light (1001), wherein the light generating device (1000) comprises (i) a first light source (110) configured to generate blue first light source light (111), wherein the first light source (110) is a first laser light source (10), (ii) a first luminescent material (210) configured to convert part of the blue first light source light (111) into first luminescent material light (211) having an emission band having wavelengths in one or more of the green and yellow, (iii) an optical filter (410) configured to optically filter the first luminescent material light (211) into optically filtered first luminescent material light (213), whereby the optically filtered first luminescent material light (213) is red-shifted relative to the first luminescent material light (211), and (iv) a second light source (120) configured to generate red second light source light (121), wherein the second light source (120) comprises a second laser light source (20); wherein in one or more operational modes of the light generating device (1000) the light generating device (1000) is configured to generate white device light (1001) comprising the first light source light (111), the optically filtered first luminescent material light (213), and the second light source light (121).

A lighting device includes a plurality of LED light sources, a plurality of lens parts respectively disposed on front surfaces of the plurality of LED light sources to collect and irradiate light emitted from each of the plurality of LED light sources, and a controller for controlling operations of the plurality of LED light sources, wherein the plurality of LED light sources include visible-light LEDs and at least one ultraviolet LED and each of the plurality of lens parts includes a condensing lens disposed on the front surface of each of the plurality of LED light sources to decrease a divergence angle of light emitted from each of the plurality of LED light sources and a fly eye lens part disposed on a front surface of the condensing lens to stack the light on a light receiving surface.

A method for simulating a candle flame with at least one computing device. The method may include controlling at least one lighting element according to at least a current wind value and a current flame value. The method may include controlling the current wind value and the current flame value by iteratively determining whether a first event occurred. When the first event is determined to have occurred, the method may include setting the current wind value to a random wind value and then changing the current wind value toward a baseline wind value. When the first event is determined to have not occurred, the method may include changing the current wind value toward the baseline wind value, determining whether a second event occurred. When the second event is determined to have occurred, the method may include setting the current flame value to a random flame value.