Examples of the present disclosure are related to systems and methods for lighting fixtures. More particularly, embodiments disclose directly embedded a smart module with a lighting fixture utilizing metal core PCB (MCPCB).

Examples of the present disclosure are related to systems and methods for lighting fixtures. More particularly, embodiments disclose lighting fixtures utilizing metal core PCB (MCPCB) for optical controls.

Examples of the present disclosure are related to systems and methods for lighting fixtures. More particularly, embodiments disclose lighting fixtures utilizing metal core PCB (MCPCB) for optical controls.

A through-hole electrode substrate includes a substrate including a through-hole extending from a first aperture of a first surface to a second aperture of a second surface, an area of the second aperture being larger than that of the first aperture, the through-hole having a minimum aperture part between the first aperture and the second aperture, wherein an area of the minimum aperture part in a planer view is smallest among a plurality of areas of the through-hole in a planer view, a filler arranged within the through-hole, and at least one gas discharge member contacting the filler exposed to one of the first surface and the second surface.

A light emitting diode (LED) module may include a direct current (DC) voltage node formed on a first layer. The DC voltage node may be configured to sink a first current. One or more devices may be formed on the first layer configured to provide a second current to one or more LEDs. A device of the one or more devices may carry a steep slope voltage waveform. A local shielding area may be formed in a second layer directly below the DC voltage node and the one or more devices. The local shielding area may include a substantially continuous area of conductive material. A conductive via may extend through one or more layers. The conductive via may electrically connect the DC voltage node and the local shielding area.

A light emitting diode (LED) module may include a direct current (DC) voltage node formed on a first layer. The DC voltage node may be configured to sink a first current. One or more devices may be formed on the first layer configured to provide a second current to one or more LEDs. A device of the one or more devices may carry a steep slope voltage waveform. A local shielding area may be formed in a second layer directly below the DC voltage node and the one or more devices. The local shielding area may include a substantially continuous area of conductive material. A conductive via may extend through one or more layers. The conductive via may electrically connect the DC voltage node and the local shielding area.

A flexible electronic substrate (FES) includes a metallic layer, a dielectric nanoceramic layer formed by oxidation of a surface of the metallic layer, and an electrical circuit formed on a surface of the dielectric layer. The FES may be used for supporting a device, for example a flexible display, an OLED, an optoelectronic device, or a rf device. The dielectric nanoceramic layer has a crystalline structure consisting of substantially equiaxed grains having an average grain size of 100 nanometers or less, a thickness of between 1 micrometer and 50 micrometers, a dielectric strength of greater than 20 KV mm.sup.1, and a thermal conductivity of greater than 3 W/mK. The FES has a minimum bend radius of lower than 25 cm.

A flexible electronic substrate (FES) includes a metallic layer, a dielectric nanoceramic layer formed by oxidation of a surface of the metallic layer, and an electrical circuit formed on a surface of the dielectric layer. The FES may be used for supporting a device, for example a flexible display, an OLED, an optoelectronic device, or a rf device. The dielectric nanoceramic layer has a crystalline structure consisting of substantially equiaxed grains having an average grain size of 100 nanometers or less, a thickness of between 1 micrometer and 50 micrometers, a dielectric strength of greater than 20 KV mm.sup.1, and a thermal conductivity of greater than 3 W/mK. The FES has a minimum bend radius of lower than 25 cm.

Lighting systems for use in building interiors, for example, which include a plurality of light modules each having an elongate substrate with a lower surface, and electrical circuitry including a plurality of LED units mounted to the lower surface. Each light module is formed as a single-component, packaged construct for easy installation, and facilitates conductive transfer of heat away from the LEDs for enhanced power efficiency. In one embodiment, the light modules are releasably connected to, and extend from, an elongate spine unit which provides structural support and power input to the light modules. In another embodiment, the light modules are disposed parallel to one another and are connected by a series of lateral connectors in laterally spaced relation to one another, with the light modules adjustably mounted to the lateral connectors whereby the spacing between the light modules may be varied.

Techniques and mechanisms for providing thermal insulation with a circuit board. In an embodiment, a circuit board comprises a metal core and an electrical insulator disposed thereon. A first portion and a second portion each comprise at least five percent of the metal core by volume, wherein a first surface of the first portion is at a first level along a height axis, and a second surface of the second portion is at a second level along the height axis. A difference between the first level and the second level is less than, and at least twenty percent of, an overall thickness of the metal core. In another embodiment, the metal core further comprises a trench portion disposed between the first portion and the second portion, wherein a thickness of the trench portion is less each of the respective thicknesses of the first portion and the second portion.