Abstract: In accordance with various embodiments, planar light sheets are conformed to interior volumes of housings to produce predetermined spatial optical characteristics such as luminous intensity distributions.

Abstract: In accordance with certain embodiments, a semiconductor die is adhered directly to a yielding substrate with a pressure-activated adhesive notwithstanding any nonplanarity of the surface of the semiconductor die or non-coplanarity of the semiconductor die contacts.

Abstract: In accordance with various embodiments, planar light sheets are conformed to interior volumes of housings to produce predetermined spatial optical characteristics such as luminous intensity distributions.

Abstract: In accordance with certain embodiments, a semiconductor die is adhered directly to a yielding substrate with a pressure-activated adhesive notwithstanding any nonplanarity of the surface of the semiconductor die or non-coplanarity of the semiconductor die contacts.

Abstract: In various embodiments, packages include one or more lighting devices having electrical contact points, a flexible substrate for supporting the lighting devices, a plurality of electrically conductive traces defined on the substrate and electrically connected to the contact points of the lighting devices, and an adhesive layer mounting each of the lighting devices on the substrate.

Abstract: In accordance with certain embodiments, an illumination system comprising a plurality of power strings features elements facilitating compensation for failure of one or more light-emitting elements connected along each power string.

Abstract: In accordance with certain embodiments, an unpackaged inorganic LED die is adhered directly to a yielding substrate with a pressure-activated adhesive notwithstanding any nonplanarity of the surface of the unpackaged inorganic LED die or non-coplanarity of the contacts thereof.

Abstract: In accordance with certain embodiments, illumination systems are formed by aligning light-emitting elements with optical elements and/or disposing light-conversion materials on the light-emitting elements, as well as by providing electrical connectivity to the light-emitting elements

Abstract: In accordance with certain embodiments, a semiconductor die is adhered directly to a yielding substrate with a pressure-activated adhesive notwithstanding any nonplanarity of the surface of the semiconductor die or non-coplanarity of the semiconductor die contacts.

Abstract: In various embodiments, packages include one or more lighting devices having electrical contact points, a flexible substrate for supporting the lighting devices, a plurality of electrically conductive traces defined on the substrate and electrically connected to the contact points of the lighting devices, and an adhesive layer mounting each of the lighting devices on the substrate.

Abstract: In accordance with certain embodiments, an unpackaged inorganic LED die is adhered directly to a yielding substrate with a pressure-activated adhesive notwithstanding any nonplanarity of the surface of the unpackaged inorganic LED die or non-coplanarity of the contacts thereof.

Abstract: In accordance with certain embodiments, an illumination system comprising a plurality of power strings features elements facilitating compensation for failure of one or more light-emitting elements connected along each power string.

Abstract: In accordance with certain embodiments, a semiconductor die is adhered directly to a yielding substrate with a pressure-activated adhesive notwithstanding any nonplanarity of the surface of the semiconductor die or non-coplanarity of the semiconductor die contacts.

Abstract: The present invention provides a lighting device package with one or more light-emitting elements operatively coupled to a substrate and a frame disposed at least in part around the one or more light-emitting elements. The frame and substrate define a cavity in which the one or more light-emitting elements are positioned, wherein this cavity can be substantially enclosed by an optically transmissive system. At least a portion of the cavity can be filled with an encapsulation material. The frame defines one or more passageways, wherein each passageway interconnects the cavity with the outside through an outside port. For example, the outside port can be accessible from the ambient when the lighting device package is in an assembled state, thereby enabling fluidic movement of the encapsulation material into and/or out of the cavity.

Abstract: The present invention provides an integrated self-contained lighting module which can be used on its own, or in conjunction with other modules to produce white light, or light of any other colour within the colour spectrum. Each module comprises one or more light-emitting elements, a drive and control system, a feedback system, thermal management system, optical system, and optionally a communication system enabling communication between modules and/or other control systems. Depending on the configuration, the lighting module can operate autonomously or its functionality can be determined based on either or both internal signals and externally received signals.

Abstract: The present invention provides an electronic device package that can be fabricated using standard package fabrication technologies while providing a desired level of thermal transfer capability to an attachable thermal management system. The electronic device package according to the present invention comprises a housing that is specifically designed to couple with an evaporator portion of a thermal management system, for example a heat pipe. One or more electronic devices are mounted in thermal contact with the evaporator portion of the thermal management system. Upon completion of the fabrication of the package using standard techniques, the evaporator portion of the electronic device package is operatively coupled with a secondary portion of the thermal management system. In this manner the electronic device package can be fabricated to incorporate a desired thermal management system, while being fabricated using standard package fabrication processes and machinery.

Abstract: A traditional passive thermal management system can only be used effectively in a single orientation because it relies on the buoyancy of the heated air to create natural convection. A passive thermal management system is provided which includes means for transferring heat away from a heat source (10) in any orientation. The system comprises a heat pipe (14) which is thermally coupled to the heat source (10). The heat pipe (14) is capable of transferring heat away from the heat source (10), wherein this heat is transferred along the length of the heat pipe (14). Thermally coupled to the heat pipe (14) is a fin system (12), which provides a means for extraction of the heat from the heat pipe (14) and transfer of this heat to the environment thereby dissipating the heat generated at the heat source (10). The fin system (12) is configured to provide a desired level of heat transfer to the environment independent of the orientation of the thermal management system.

Abstract: The present invention provides a lighting device package, which can provide a means for efficient thermal access to the lighting device package in addition to a desired level of light extraction from the one or more light-emitting elements within the lighting device package. The lighting device package comprises a substrate having a thermally conductive region to which one or more light-emitting elements are thermally connected, wherein the light-emitting elements may be relatively closely packed. An optical system is optically coupled to one or more light emitting elements, and is positioned relative to the substrate such that the optical system substantially encloses the one or more light-emitting elements on the substrate. The optical system is adapted to extract the light from the one or more light-emitting elements.

Abstract: The present invention provides a lighting device package with one or more light-emitting elements operatively coupled to a substrate and a frame disposed at least in part around the one or more light-emitting elements. The frame and substrate define a cavity in which the one or more light-emitting elements are positioned, wherein this cavity can be substantially enclosed by an optically transmissive system. At least a portion of the cavity can be filled with an encapsulation material. The frame defines one or more passageways, wherein each passageway interconnects the cavity with the outside through an outside port. For example, the outside port can be accessible from the ambient when the lighting device package is in an assembled state, thereby enabling fluidic movement of the encapsulation material into and/or out of the cavity.

Abstract: The present invention provides a method and apparatus for coupling a device to a heat pipe, wherein a heat transformable material is placed at the location on the heat pipe at which the device is to be coupled. The device is positioned relative to this location and in contact with the heat transformable material and subsequent heat is applied to the end of the heat pipe opposite the coupling location. The external heat which is applied to the heat pipe is transferred along the heat pipe to the proximity of the coupling location. The heat transformable material undergoes a change due to the application of heat and mates the device with the heat pipe. The heat transformable material changes into a substantially solid state upon the removal of the external heat source, thereby coupling the device to the heat pipe.