A drone receiving apparatus is provided including a landing area including a platform, a lighting system, and/or a surface on which a drone is receivable, a charging plate for providing electrical power to charge the drone received by the landing area, and a communication system by which a signal is communicable to exchange data with the drone that is within a communicable proximity to the communication system. A method to receive a drone is also provided.

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.

A lighting system for LED lights, including a plurality of discrete extruded elements interconectable to create various housing, support and light modifiers to be used in luminaire assemblies.

A system of scalable modular LED light fixtures is provided herein for accommodating different levels of generated lighting and to accommodate different mountings.

A luminaire includes a light emitter, an asymmetric lens, and a mechanism. The light emitter includes an exit aperture and emits a light beam having an optical axis. The asymmetric lens receives the light beam and projects a projected beam. The mechanism rotates the light emitter about an axis of rotation passing through the exit aperture, thereby moving a point of entry of the light beam into the asymmetric lens. A size and location of a hot-spot of the projected beam varies as the point of entry of the light beam into the asymmetric lens moves. The asymmetric lens includes a long axis, a short axis, and an asymmetric surface, which has a long axis parallel to the long axis of the asymmetric lens. The asymmetric surface is asymmetric in a cross-section taken in a plane perpendicular to the short axis of the asymmetric lens.

An LED module includes a base, a rear plate, an LED chip board and a glass window. The back surface of the base includes a channel for introducing cooling water. A sealing ring is compressed between the back surface of the base and the rear plate to seal the channel. A plurality of LED chips connected in series form the LED chip board which is mounted on the front surface of the base and is covered with the glass window.

An optical system includes a light source, a lens, and a light effect ring. The lens has first and second surfaces and receives a first light beam from the light source at the first surface and emits a second light beam from the second surface. The light effect ring includes a first plurality of light emitters emitting second light beams that obliquely illuminate the first surface of the lens and a second plurality of emitters that emit third light beams through the lens. The light effect ring may include a plurality of segments that move into and out of the first light beam, where each segment includes a first subset of the first plurality of light emitters and a second subset of the second plurality of emitters.

A luminaire includes an elongated body, a plurality of light sources arranged between opposing ends of the body, mounting plates provided at the opposing ends, and an electrical outlet configured to receive power. The mounting plates include a threaded portion configured to receive a threaded connector for supporting the luminaire from a mounting surface. A lighting modifier might be provided to alter the lighting output.

The present invention relates to a track lighting system (1) comprising: a power track (2) having a longitudinal extension (L) and being connectable to an electric supply; a plurality of individually controllable lighting devices comprising at least one first lighting device (3) and at least one second lighting device (4), each being connectable to the power track (2), wherein the at least one first lighting device (3) comprises a first light source and a first light exit window (5) having a first form factor, wherein the at least one second lighting device (4) comprises a second light source and a second light exit window (6) having a second form factor; wherein at least one first lighting device (3) is a first pixelated lighting device wherein the first light source comprises a plurality of individually controllable first LED pixels; wherein the track lighting system (1) further comprises at least one control unit arranged to individually control the lighting devices (3, 4); and wherein the control unit is further arranged to control at least one first LED pixel of the plurality of individually controllable first LED pixels of the at least one first lighting device (3) to illuminate only a first portion of the first light exit window such that a light pattern is providable by the track lighting system (1) in the first light exit window.

The invention provides a light generating system (1000) configured to generate system light (1001), wherein the light generating system (1000) comprises a first light generating device (110), wherein: (A) the first light generating device (110) comprises a first light source (10) and a first luminescent converter (210); (B) the first light source (10) comprises a solid state light source, wherein the first light source (10) is configured to generate first light source light (11) having a first light source centroid wavelength (.sub.S, 1) selected from the range of 380-420 nm; (C) the first luminescent converter (210) is configured to convert at least part of the first light source light (11) into first converter light (211) having a first converter centroid wavelength (.sub.c, 1) selected from the green-yellow wavelength range; (D) the first light generating device (110) is configured to generate first device light (111) having a spectral power distribution in the wavelength range of 380-780 nm with at least 60% of the spectral power provided by the first light source light (11) and at maximum 40% of the spectral power provided by the first converter light (211).