Abstract: A lighting module has an array of light-emitting elements that is electrically coupled to a heat sink and a housing having a heat exit. The array of light-emitting elements is positioned in the housing and the heat sink is positioned to dissipate heat generated within the housing so that the heat is expelled through the heat exit. A deflector is secured to the housing and is positioned to extend over some portion of the heat exit. The deflector guides heat away from the housing in a direction. In some configurations, the deflector guides heat away from the housing in a direction that is opposite the direction in which the array of light-emitting elements emit light. Also, some lighting modules have multiple heat exits and may have multiple deflectors extending over a portion of the respective heat exits.

Abstract: A system and method for monitoring and operating one or more light emitting devices is disclosed. In one example, light intensity within a dual elliptical reflecting chamber is sensed and operation of a fiber curing system is adjusted in response to an amount of sensed light energy.

Abstract: A system and method for monitoring a fiber curing system is disclosed. In one example, transmittance of a curing tube is determined so that curing of a coating applied to a fiber may be more uniform.

Abstract: A system and method for operating one or more light emitting devices is disclosed. In one example, the light emitting devices may be deactivated in response to a rate of temperature rise of the light emitting devices.

Abstract: A lighting module has an array of light emitters, a heat sink having a first surface, the array of light emitters being mounted to the first surface, a microchannel cooler arranged on a second surface of the heat sink on an opposite side of the heat sink from the first surface, the microchannel cooler arranged to transport a liquid through a channel on the second surface of the heat sink, and a cooling unit thermally coupled to a microchannel cooler and arranged to remove heat from the liquid.

Abstract: A device for UV curing a coating or printed ink on an workpiece such as an optical fiber comprises dual elliptical reflectors arranged to have a co-located focus. The workpiece is centered at the co-located focus such that the dual elliptical reflectors are disposed on opposing sides of the workpiece. Two separate light sources are positioned at a second focus of each elliptical reflector, wherein light irradiated from the light sources is substantially concentrated onto the surface of the workpiece at the co-located focus.

Abstract: A lighting module has a housing that houses an array of light-emitting elements and has multiple channels that each have an opening at the end of each channel. All of the openings of the channels are positioned along the same plane in some examples. The plane is opposite the surface of the housing that emits the light from the light-emitting elements. An intake fan is positioned in at least one of the channels so that it causes air to enter the housing through that channel's opening. An exhaust fan is positioned in another one of the channels so that it causes air to be forced out of the housing through the other channel's opening. The air flow through the intake channel and the exhaust channel help cool the lighting module during use.

Abstract: A lighting module has at least one array of solid-state lighting elements, a variable resistor having an input of an intensity control voltage for the array of solid-state lighting elements, the variable resistor having an output electrically connected to an input of the array of solid-state lighting elements, and a voltage regulator electrically connected to the output of the variable resistor, the voltage regulator having an output connected to an input of the array of solid-state lighting elements.

Abstract: A light-emitting diode includes a substrate, a lower cladding layer, an active layer having a quantum well of a thirty percent concentration of indium on the lower cladding layer, and an upper cladding layer. A method of manufacturing light-emitting diodes includes forming a lower cladding layer on a substrate, forming an active layer on the lower cladding layer such that the active layer has a quantum well of thirty percent indium, forming an upper cladding layer on the active layer, and forming a metal cap on the upper cladding layer.

Abstract: The present invention provides an optical array module that includes a plurality of semiconductor devices mounted on a thermal substrate formed with a plurality of openings that function as micro-reflectors, wherein each micro-reflector includes a layer of reflective material to reflect light. Such material preferably is conductive so as to provide electrical connection for its associated semiconductor device.

Abstract: A light source including a plate and an emitter array mounted on the plate extending from a first edge to a second edge. The plate can include a first edge; a second edge, the first edge being opposite the second edge; a first mount on the first edge; and a second mount on the second edge. Such light sources can be combined together.

Abstract: Lighting modules include a housing, a window attached to the housing, and an array of light-emitting elements that are positioned within the housing and emit light through the window. The window has a first surface and a second surface. The light from the array of light-emitting elements is emitted through the first surface and the second surface of the window. In some examples, the first surface and the second surface of the window are angled with respect to each other.

Abstract: A lighting module has an array of light emitters, a heat sink having a first surface, the array of light emitters being mounted to the first surface, a microchannel cooler arranged on a second surface of the heat sink on an opposite side of the heat sink from the first surface, the microchannel cooler arranged to transport a liquid through a channel on the second surface of the heat sink, and a cooling unit thermally coupled to a microchannel cooler and arranged to remove heat from the liquid.

Abstract: A lighting module includes an array of light emitters, a heat pipe having a flat portion, the array of light emitters being mounted to the flat portion, a liquid inside the heat pipe, the liquid selected to vaporize upon exposure to heat from the array, and a cooling unit thermally coupled to the heat pipe configured to cool the vaporized liquid.

Abstract: A system and method for operating one or more light emitting devices is disclosed. In one example, the switching of a regulator is ceased in response to a request to stop supplying power to one or more light emitting devices. The approach may reduce power consumption of a lighting system when light is not requested.

Abstract: A semiconductor lighting device has an array of semiconductor light sources arranged in an x-y grid, a power input in electrical connection with the array and arranged to provide power to the light sources, a microcontroller in electrical connection with the array arranged to alter operation of the array as necessary, and a connector in electrical connection with the microcontroller, arranged to provide an interface to the microcontroller. The semiconductor lighting device has a first interface to allow a first level of access to the microcontroller by an end user, a second interface to allow a second level of access to the microcontroller for maintenance operations, and a third interface to allow a third level of access to the microcontroller during production.

Abstract: The present invention provides an optical array module that includes a plurality of semiconductor devices mounted on a thermal substrate formed with a plurality of openings that function as micro-reflectors, wherein each micro-reflector includes a layer of reflective material to reflect light. Such material preferably is conductive so as to provide electrical connection for its associated semiconductor device.

Abstract: A lighting module has an array of light emitters, a heat sink having a first surface, the array of light emitters being mounted to the first surface, a microchannel cooler arranged on a second surface of the heat sink on an opposite side of the heat sink from the first surface, the microchannel cooler arranged to transport a liquid through a channel on the second surface of the heat sink, and a cooling unit thermally coupled to a microchannel cooler and arranged to remove heat from the liquid.

Abstract: Lighting modules include a housing, a window attached to the housing, and an array of light-emitting elements that are positioned within the housing and emit light through the window. The window has a first surface and a second surface. The light from the array of light-emitting elements is emitted through the first surface and the second surface of the window. In some examples, the first surface and the second surface of the window are angled with respect to each other.

Abstract: A light source may comprise a cylindrical lens, for example a cylindrical Fresnel lens, a linear array of light-emitting elements, the linear array aligned with and emitting light through the cylindrical Fresnel lens, wherein the cylindrical Fresnel lens reduces the angular spread of light in a widthwise axis of the linear array, the linear array spanning a lens length.