A connection assembly includes an electrical cord providing electrical communication between a first light fixture and a second light fixture, and a cover removably coupled to the first light fixture and the second light fixture. The electrical cord includes a first electrical connector coupled to the first light fixture, and a second electrical connector coupled to the second light fixture. The cover extends over the electrical cord, and includes a first end adjacent the first light fixture, a second end adjacent the second light fixture, and a surface extending between the first end and the second end. The cover provides a continuous surface between the first light fixture and the second light fixture.

A linear light-emitting diode (LED) lighting apparatus may include an array of light emitting diodes (LEDs) that may include a first plurality of LEDs that produces a first light having a first color temperature. The first plurality of LEDs aligns within a first linear shape. The second plurality of LEDs may produce a second light having a second color temperature different from the first color temperature. The second plurality of LEDs aligns within a second linear shape. The lighting apparatus may also include a driver circuit that outputs a plurality of currents and a switch assembly that may couple to the driver circuit. The switch assembly may include a first switch that may cause the driver circuit to output one of the plurality of currents and a second switch that may cause the one of the plurality of currents to couple to the first plurality of LEDs, the second plurality of LEDs, or both.

A lighting arrangement includes a first lighting module and a second lighting module. A rail is designed for coupling or at least partially accommodating the first lighting module and the second lighting module. A conductor device is provided along the rail in order to provide electric current and a control signal. The first lighting module is configured to be coupled to the conductor device to receive electric current for supplying the first lighting module and the control signal from the conductor device. The first lighting module is configured to process the control signal and to control the first lighting module in dependence upon the control signal. The first and the second lighting module are configured to be coupled to one another such that a signal for controlling the second lighting module can be communicated from the first lighting module to the second lighting module.

An LED lamp and a power source module thereof are provided. The power source module includes a switch-type DC-to-DC converter integrated with a function for detecting whether a foreign external impedance exists. The switch-type DC-to-DC converter is configured to enter an installation detection mode when the switch-type DC-to-DC converter is activated. When the switch-type DC-to-DC converter is in the installation detection mode, the switch-type DC-to-DC converter receives an external AC signal received by the LED lamp to detect whether a foreign external impedance exists based on the received signal.

A railing assembly includes a bottom rail and a top rail extending parallel thereto and spaced apart therefrom. Both rails include a beam defining through-holes and corresponding pocket-holes located opposite from the other rail to define ledges facing away from the other rail. A plurality of balusters of light-transmissive material each extend between the bottom rail and the top rail, through a corresponding through-hole and pocket-hole in each railing. Retaining rings are disposed around each of the balusters within each of the pocket-holes for engaging the ledges and thereby holding the balusters to each rail. Each rail may include a plate of light-transmissive material extending in a plane adjacent the beam and configured to project light along a length thereof. One or more illumination sources are disposed in the top rail and/or the bottom rail to direct light into the balusters and/or the plate(s) to provide options for multiple illumination effects.

A Flexible LED illumination device, according to the present invention, comprises a translucent positioning strip having a plurality of slots disposed at the center, a plurality of light modules mounted inside of the translucent positioning strip, a plurality of power conductors in communication to the plurality of light modules, a translucent housing covering the plurality of light modules, an elongated light diffuser tube disposed at the top of the translucent housing, and wherein said elongated light diffuser tube is configured to refract light from the plurality of light modules, a potting glue disposed at the bottom of the plurality of power conductors, and exposed power conductors extruding in between the plurality of light modules. The flexible LED illumination device is constructed with flexible material to allow bending to any shapes, and weatherproofing.

A terminal to connect of a tape light with at least one electric element is disclosed. The terminal includes a body having a base, a first sidewall extending outwardly from the base and defining an opening to receive a portion of the tape light, a second sidewall extending outwardly from the base and arranged spaced apart from the first sidewall. The second sidewall defines at least one groove extending inside the body from the second sidewall for receiving the at least one electric element. Further, the terminal includes a roof arranged opposite to the base and defining a plurality of cut-outs extending from the roof to the opening and a plurality of holes extending from the roof to the at least one groove, and a plurality of rails extending from the first sidewall to the second sidewall intersecting the plurality of cut-outs and the plurality of holes.

A lighting system, such as for an indoor growing facility, comprises a frame, an end electrical connector, a light emitting unit comprising at least one LED and a unit electrical connector, wherein the light emitting unit is positionable within a first mounting region of the frame with the unit electrical connector electrically connected to a light emitting unit electrical connector of the frame. The light emitting unit is removably insertable into the first mounting region through a first opening in a sidewall of the frame.

Disclosed herein is a multi-element flexible strap light which includes a plurality of light elements disposed on a flexible chassis. The flexible chassis may include a first flexible layer, a printed circuit board, and a second flexible layer. The flexible chassis may be further contained within a third flexible layer, such as a layer of polycarbonate plastic. Further disclosed is a multi-element flexible strap light system which includes a plurality of light elements disposed on a flexible chassis and a remote battery.

Practical lighting is the technique of using light sources that are seen within the frame of a shot. Apparatus 10 and 10A is a lightweight, magnetically mounted, light diffusing housing for LED ribbon which is designed to look like a standard fluorescent tube when used as practical lighting. Control wires can be easily and repeatedly removed via screwed terminal housings (10) or connected via industry standard phoenix receptacle (10A) housed discreetly one of its two end caps, providing a solderless connection with either apparatus. The magnets internally installed adhere the apparatus to standard metal fluorescent housings without damage to the installed fixture negating the need of additional mounting rigging hardware.