A system of networked lighting devices includes a central controller and a group of lighting devices. Each lighting device may include a fixture controller, one or more lighting modules, and a communication interface. The central controller receives data packets and send them to the lighting devices via a ring topology. The lighting devices may be connected to each other via the ring topology, or a set of routers may be connected in the ring topology, with each router controlling one or more connected lighting devices. The central controller and/or the fixture controllers may each translate data packets from one protocol to a different protocol. The different protocol may be a protocol that is compatible with the local system of networked devices, and/or a protocol that is compatible with the lighting device(s) that will use the data packets to actuate according to a command from the central controller.

A recessed lighting system is disclosed that is capable of providing both direct and indirect lighting. The recessed lighting system may include first and second pluralities of light emitting diodes (LEDs) mounted on, respectively, first and second elongate track members. The first and second elongate track members may be spaced apart from each other by a distance, and a reflector may span at least a portion of that distance. The first and second pluralities of LEDs may be configured to emit light toward the reflector so that the reflector provides indirect lighting. A direct lighting fixture may be arranged between and slidably supported by the first and second elongate track members so that the direct lighting fixture is movable along the first and second elongate track members. Accordingly, the direct lighting fixture can be moved to a preferred position to spotlight an individual object or portion of the room.

Embodiments of the disclosed technology are directed to a light fixture and a method of assembly thereof. The light fixture is generally formed of two opposing side rails joined to two opposing caps. The fixture has two panels: an upper panel and a lower panel. The upper panel is formed of a generally flat, deflectable elongated section having a plurality of lights disposed on or in a surface thereof. The upper panel is deflected to form a substantially curvilinear panel, the edges of which are engaged into a slot on the side rails and/or the end caps. The lower panel is also generally flat and formed of a transparent or translucent material. The lower panel is disposed below the upper panel, such that the light projected from the lights on the upper panel projects through the lower panel.

The present invention includes a removable lighting assembly containing: a housing; a solid state lighting unit contained within the housing and electronically communicating with the housing; and a deflector fixed about the solid state lighting unit for deflection of the light emanating therefrom.

An electronic candle includes: a wax tube, a battery compartment, a PCBA board, and a light string. The wax tube is cylindrical and made from paraffin wax. The wax tube defines a cavity therein and has a first end and a second end, the second end defines an opening communicated to the cavity. The battery compartment is inserted into the cavity from the second end, the battery compartment has a third end and a fourth end, the fourth end defines an opening facing towards the first end. The PCBA board is inserted to the fourth end. At least a portion of the PCBA board is exposed to the cavity. The light string is extending spirally and arranged on an outer surface of the wax tube. The light string extends through the wax tube to be electrically connected to the exposed portion of the PCBA board.

A light fixture includes at least one elongated strut and a socket formed on each strut. Each strut includes a first end, a second end, and an arcuate portion extending between the first end and the second end. An axis extends between the first end and the second end. The arcuate portion extending at least partially around the axis. The socket includes a ridge and a surface supporting a first light-emitting element. The surface is recessed relative to the ridge such that the light emitted by the light-emitting element is directed at an acute angle relative to the axis.

A modular LED lighting system is presently disclosed, the system comprises at least one LED lamp housing configured to house and hold at least one longitudinally extending LED lamp or an array of LEDs. The LED lamp housing comprises two substantially parallel longitudinally extending sidewalls and two substantially parallel end walls, each end wall extends from edges of the sidewalls to form an LED lamp housing with a rectangular lower light opening. Each of the sidewalls are configured to abut with a sidewall of an adjacent LED lamp housing and each of the end walls are configured to abut with an end wall of an adjacent LED lamp housing, in the modular LED lighting system. Each of the at least one LED lamp housings in the modular LED lighting system are configured to adjoin with an adjacent LED lamp housing.

The present invention provides a method for constructing a universal LED bulb, a snap ring structured LED bulb and a lamp. The constructing method comprises: supporting an optical engine core member of the LED bulb in the lens snap ring (8) using a lens snap ring (8) as a supporting main body, using an inner snap ring (81) provided on the inner side of a light distribution optical lens (7) in the optical engine core member as an auxiliary supporting structure, and further using the inner snap ring (81) as an installation base of an optical engine module (4) and a heat conductive bracket (3) or an installation base of an LED bulb radiator (103); the optical engine core member of the LED bulb is composed of the heat conductive bracket (3), the optical engine module (4), the inner snap ring (81) and the light distribution optical lens (7).

A light emitting diode (LED) lighting arrangement for a lighting fixture includes: a lighting strip comprising a plurality of light emitting diodes (LEDs) arranged along a length of the lighting strip; a first multi-faceted side wall reflector extending from a first side of the lighting strip at an angle such that the first multi-faceted side wall reflector extends along an entire length of the lighting strip and away from a bottom portion of a light emitting portion of each of the light emitting diodes (LEDs); and a second multi-faceted side wall reflector extending from a second, opposite side of the lighting strip at an angle such that the second multi-faceted side wall reflector extends along an entire length of the lighting strip away from the bottom portion of the light emitting portion of each of the light emitting diodes (LEDs). The first and second multi-faceted side wall reflectors cause light produced by the plurality of light emitting diodes (LEDs) to be amplified and formed into a uniform beam.