Abstract: A formed graphite sheet is shaped and sized as a protective shield positioned over an electronic component coupled to a PCB. The formed graphite sheet is used to protect a body of the electronic component from heat applied during the assembly of the electronic component to the PCB, such as the heating steps used in SMT and through-hole technology.

Abstract: A disconnectable snap button connection for connecting electronic devices to fabrics, the disconnectable snap button connection and a method for making the same is described herein. The disconnectable snap button connection includes a component, a piece of conductive material, a piece of non-conductive material; wherein the piece of conductive material is attached to the piece of non-conductive material, a male portion of the disconnectable snap button, wherein the male portion of the disconnectable snap button is attached to the component, and a female portion of the disconnectable snap button, wherein the female portion of the disconnectable snap button is attached to the piece of conductive material. When the male portion of the disconnectable snap button is inserted into the female portion of the disconnectable snap button, a connection is made between the component and the piece of conductive material.

Abstract: A method and apparatus for forming a circuit on an uneven two-dimensional (2-D) or three-dimensional (3-D) surface of an object is described. An amount of electrically conductive material to form a circuit between two points on the object is determined. The determined amount of electrically conductive material is deposited on a first surface of a stretchable substrate. The stretchable substrate with the deposited electrically conductive material is applied to the object to form a circuit between two points on the object.

Abstract: A method for making a Radio Frequency Identification (RFID) device on fabric is described herein. In a first example, an RFID semiconductor chip is attached to a piece of fabric. The RFID semiconductor chip includes two terminals. A solid wire is stitched into the fabric making an RFID antenna. The solid wire is attached to the terminals of the RFID semiconductor chip. In a second example, a metal wire is selected. The metal wire is stitched into fabric making an RFID antenna. The metal wire includes two ends and a conductive adhesive is applied to two ends of the metal wire. An RFID semiconductor chip is attached to the fabric. The RFID semiconductor chip includes two terminals and the RFID semiconductor chip is attached to the fabric at the two terminals. The conductive adhesive is cured. In both examples, the wire and the RFID semiconductor chip are encapsulated in fabric.

Abstract: Embodiments of the present invention relate to a fixture design for pre-attachment package on package component assembly. The fixture design includes a plurality of pockets arranged in a N×M array. The plurality of pockets is sized to receive bottom packages. The fixture design includes global fiducials that are used to locate positions of the pockets on the fixture, and sets of local fiducials, with each set being specific to one of the pockets and used to refine the position of the location of a corresponding pocket. Each of the pockets can include one or more ear cuts for easy component placement and component removal. The fixture design can include a vacuum port for coupling with a vacuum source for drawing a vacuum to hold the bottom packages down. The fixture design can also include a cover that is used with the fixture to keep the components from being disturbed.

Abstract: A method and apparatus for forming a conductor on an uneven two-dimensional (2-D) or three-dimensional (3-D) surface is described. An amount of conductive material needed to form a conductor between two points on a surface of an object is determined. The determined amount of conductive material is deposited on a substrate. The substrate with the deposited conductive material is applied to the object to form a conductor between the two points on the surface of the object. The conductive material and substrate may be stretchable. The conductive material may be deposited by an inkjet printer or an embedded 3-D printer. The substrate with the deposited conductive material may be applied to the object by laminating the substrate with the deposited conductive material to the object.

Abstract: A wearable electronics assembly includes one or more electronic modules coupled to a wearable electronics fabric. Each of the one or more electronic modules includes one or more metal foils, each metal foil electrically coupled at one end to an electrical connection point of the electrical module and at another end to an electrically conductive wire. The electrically conductive wire is stitched to the metal foil and to a fabric onto which the electronic module is attached. The electronic module can include one or more electronic components coupled to a printed circuit board. The metal foils can be formed from interconnects on the printed circuit board or the metal foils can be separate elements coupled to the printed circuit board.

Abstract: A stretchable metal wire assembly includes a metal wire positioned within an elastic tube. The form of the metal wire is such that when the elastic tube is in a relaxed, or non-stretched, state the metal wire forms a tortuous path, such as a waveform, along the elastic tube. The tortuous path of the metal wire provides slack such that as the elastic tube is stretched the slack is taken up. Once released, the elastic tube moves from the stretched position to the relaxed, non-stretched position, and slack is reintroduced into the metal wire in the form of the original tortuous path. The metal wire functions as an electrical conductor, thereby providing a device having an extendable length electrical conducting element. In some applications, the metal wire is electrically coupled at each end to an electrical interconnect component.

Abstract: An electronic module assembly and method of assembling an electronic module to a conductive fabric are provided. An electronic module assembly comprises a non-conductive fabric and a conductive fabric covering at least part of a first side of the non-conductive fabric. An electronics module is disposed on the conductive fabric, and a portion of the electronics module includes a wall defining a through hole. A fastener passing through the through hole and passing through the conductive fabric is configured to electronically couple the electronics module to the conductive fabric.

Abstract: A method and apparatus for forming a conductor on an uneven two-dimensional (2-D) or three-dimensional (3-D) surface is described. An amount of conductive material needed to form a conductor between two points on a surface of an object is determined. The determined amount of conductive material is deposited on a substrate. The substrate with the deposited conductive material is applied to the object to form a conductor between the two points on the surface of the object. The conductive material and substrate may be stretchable. The conductive material may be deposited by an inkjet printer or an embedded 3-D printer. The substrate with the deposited conductive material may be applied to the object by laminating the substrate with the deposited conductive material to the object.

Abstract: An RFID device assembly is fabricated by stitching an electrically conductive wire into a fabric as a pattern that forms an antenna. The two ends of the electrically conductive wire are positioned for coupling to antenna contact pads on an RFID device. The RFID device is attached to the fabric either before or after the electrically conductive wire is stitched to the fabric.

Abstract: A wearable electronics assembly includes one or more electronic modules coupled to a wearable electronics fabric. Each of the one or more electronic modules includes one or more plated through holes, through each of which is coupled an electrically conductive wire. The electrically conductive wire is stitched through the plated through hole and to a fabric onto which the electronic module is attached. The electronic module can include one or more electronic components coupled to a printed circuit board.

Abstract: According to an embodiment of a high power package, the package includes a heat sink containing enough copper to have a thermal conductivity of at least 350 W/mK, an electrically insulating attached to the heat sink with an epoxy and a semiconductor chip attached to the heat sink on the same side as the lead frame with an electrically conductive material having a melting point of 280° C. or greater.

Abstract: An electronic circuit interconnect apparatus that includes two zipper tracks configured to zip together thereby causing a first circuit to electrically couple with a second circuit. Specifically, each of the zipper tracks include a plurality of teeth, one or more of which are electrically coupled to the first circuit or the second circuit. As a result, when the teeth coupled to the first circuit are zipped to the teeth coupled to the second circuit it causes the first and second circuits to be electrically coupled.

Abstract: An apparatus and method are disclosed for providing monolithic optical packages. An embodiment optical package includes a base made of aluminum-nitride (AlN) that is configured to support an optical component, a plurality of sidewalls made of AlN that are coupled to the base, the sidewalls are configured to surround the optical component, and a feed-through made of AlN that is coupled to one of the sidewalls, wherein the feed-through is configured to feed a plurality of leads through the one sidewall to provide an electrical connection to the optical component, wherein the base, the sidewalls, and the feed-through have a same coefficient of thermal expansion (CTE) for AlN. An embodiment method includes punching and printing AlN tapes to build a base, a plurality of sidewalls joined to the base, and a feed-through coupled to the sidewalls, and attaching a plurality of electrical leads into the feed-through.

Abstract: A printed circuit including a non-conductive substrate, a first conductive layer printed on the non-conductive substrate and one or more additional layers printed on the substrate. The first conductive layer is able to have one or more antennas each forming a predetermined pattern, a first conductive sheet and one or more conductive traces. The one or more additional layers include a first electrode printed on the top of the first conductive sheet, a buffer printed on top of the first electrode, a second electrode printed on top of the buffer and a second conductive sheet printed on top of the second electrode. The printed circuit is further able to include an RFID chip electrically coupled with the antennas and at least one of the first and second conductive sheets via the conductive traces, wherein the first and second conductive sheets, the buffer and the first and second electrodes form a power source that provides electrical power to the RFID chip.

Abstract: Polyimide-based redistribution layers (RDLs) can be employed to reduce thermo-mechanical stress that is exerted on conductive interconnections bonded to interposers in 2.5 D semiconductor packaging configurations. The polyimide-based RDL is located on an upper or lower face of an interposer. Additionally, height differentials between laterally adjacent semiconductor dies in 2.5 D semiconductor packages can be reduced or eliminated by using different diameter micro-bumps, different height copper pillars, or a multi-tiered interposer to lower taller semiconductor dies in relation to shorter semiconductor dies.

Abstract: Lower semiconductor dies in 2.5 D semiconductor packaging configurations can be cooled by thermally coupling the lower semiconductor dies to a heat sink positioned above the interposer, to an upper semiconductor die, to a heat sink affixed beneath a substrate, or to free-flowing air circulating above the interposer or beneath the substrate. The thermal coupling can be achieved using heat pipes, thermal vias, or other conductive passage ways.

Abstract: Lower semiconductor dies in 2.5 D semiconductor packaging configurations can be cooled by thermally coupling the lower semiconductor dies to a heat sink positioned above the interposer, to an upper semiconductor die, to a heat sink affixed beneath a substrate, or to free-flowing air circulating above the interposer or beneath the substrate. The thermal coupling can be achieved using heat pipes, thermal vias, or other conductive passage ways.

Abstract: An apparatus and method are disclosed for providing monolithic optical packages. An embodiment optical package includes a base made of aluminum-nitride (AlN) that is configured to support an optical component, a plurality of sidewalls made of AlN that are coupled to the base, the sidewalls are configured to surround the optical component, and a feed-through made of AlN that is coupled to one of the sidewalls, wherein the feed-through is configured to feed a plurality of leads through the one sidewall to provide an electrical connection to the optical component, wherein the base, the sidewalls, and the feed-through have a same coefficient of thermal expansion (CTE) for AlN. An embodiment method includes punching and printing AlN tapes to build a base, a plurality of sidewalls joined to the base, and a feed-through coupled to the sidewalls, and attaching a plurality of electrical leads into the feed-through.