Abstract: A printed wiring board includes a Cu wiring pattern formed on a substrate. A first metal layer is formed on the Cu wiring pattern. A second metal layer is formed on the first metal layer. The first metal layer has a less reactivity with Cu than the second metal layer. The first metal layer and the second metal layer together cause an eutectic reaction.

Abstract: The present application describes various embodiments of systems and methods for providing internal and external components for portable computing devices having a thin profile. More particularly, the present application describes internal components configured to fit within a relatively thin outer enclosure, wherein the internal components comprise at least one external interface, such as, for example, a track pad interface.

Abstract: Surface-active dopants are added to a portion of a circuit package before a reflow process to promote wetting and reduce the formation of solder bump bridges. The circuit package has a solder element that electrically connects the circuit package to a substrate. A reflow process is performed to attach the solder element to a pad on the circuit package. During the reflow process, the surface-active dopants diffuse to the surface of the solder element and form an oxide passivation layer on the surface of the solder element.

Abstract: A packaging carrier includes an interposer, a dielectric layer and a built-up structure. The interposer has a first surface and a second surface opposite to each other, and a plurality of first pads and second pads located on the first surface and the second surface, respectively. The dielectric layer has a third surface and a fourth surface opposite to each other. The interposer is embedded in the dielectric layer. The second surface of the interposer is not covered by the fourth surface of the dielectric layer, and has a height difference with the fourth surface. The built-up structure is disposed on the third surface of the dielectric layer and electrically connected to the first pads of the interposer.

Abstract: An electrical connector assembly includes an insulating housing having a number of housing segments, a number of contacts received in the housing segments, a number of caps covering on the housing segments respectively and a number of clips assembled on the caps. Each of the caps includes a retaining mechanism defining an arm for operating by a user and a latch engaging the housing segment. Each of the clips is assembled on the arms of at least two caps so as to operate two caps together.

Abstract: This invention relates to the thermal management, extraction of light, and cost effectiveness of Light Emitting Diode, or LED, electrical circuits. An integrated circuit LED submount is described, for the packaging of high power LEDs. The LED submount provides high thermal conductivity while preserving electrical insulation. In particular, a process is described for anodizing a high thermal conductivity aluminum alloy sheet to form a porous aluminum oxide layer and a non-porous aluminum oxide layer. This anodized aluminum alloy sheet acts as a superior electrical insulator, and also provides surface morphology and mechanical properties that are useful for the fabrication of high-density and high-power multilevel electrical circuits.

Abstract: An electrical connecting element, a method of fabricating the same, and an electrical connecting structure comprising the same are disclosed. The method of fabricating the electrical connecting structure having twinned copper of the present invention comprises steps of: (A) providing a first substrate; (B) forming a nano-twinned copper layer on part of a surface of the first substrate; (C) forming a solder on the nano-twinned copper layer of the first substrate; and (D) reflowing the nano-twinned Cu layer and solder to produce a solder joint, wherein at least part of the solder reacts with the nano-twinned copper layer to produce an intermetallic compound (IMC) layer which comprises a Cu3Sn layer, This invention reduces the voids formation in the interface between the intermetallic compound and the solder, and then enhances the reliability of solder joints.

Abstract: Matrices of multiple cast conductors, and methods for making such matrices are disclosed. Methods according to the disclosure comprise: casting a conductor matrix including a plurality of conductors joined by at least one link; applying a surface treatment to at least a portion of the matrix; finishing a contact face on at least one of the conductors; and separating the conductors from each other at the at least one link.

Abstract: The invention relates to a method for manufacturing LED lead frame. The method comprises steps of: (a) forming a metal base with a plurality of lead areas by injection molding; (b) electroplating the metal base; and (c) forming an insulating casing on each of the lead areas.

Abstract: The invention concerns a method for forming an electrically conductive pattern on an insulating substrate. In the method, particle-type electrically conductive matter is transferred onto a surface of the substrate and the particle-type electrically conductive matter is at least partially sintered at elevated temperature and pressure in order to convert the particle-type electrically conductive matter into a continuously electrically conductive pattern affixed to the substrate. According to the invention, the electrically conductive matter is transferred in the form of a predefined pattern, and the sintering is carried out by using a nip comprising two opposing nip members between which the substrate is fed. The method provides an efficient way of making high-resolution conductor structures at low temperatures.

Abstract: An electrical connection assembly includes a connector and a cable. The connector includes a plug having a multitude of contacts in electrical communication with the cable wires. The connector further includes a body in which a printed circuit board is inserted. The cable wires are soldered to the bonding pads of the printed circuit board which is encapsulated by an adhesive. The connector further includes a metallic shield enclosing the body and providing a path to the ground. An inner mold encapsulates the space enclosed by the metallic shield. The metallic shield is optionally formed from a pair of metallic shields cans that are crimped and laser welded. The assembly further includes a sleeve attached at a rear face of the metallic shield, an enclosure attached to the connector body, and a pair of face plates attached between the enclosure and the body.

Abstract: It is an objective of the present invention to eliminate wafer testing. Provided is a manufacturing apparatus comprising a detecting section that detects a position of a device terminal of a device; a generating section that generates a substrate-side terminal, which connects to the device terminal, on a substrate at a position corresponding to the device terminal; and a mounting section that mounts the device on the substrate and connects the device terminal to the substrate-side terminal. The detecting section captures an image of the device and detects the position of the device terminal based on the captured image, and the generating section prints a pattern of the substrate-side terminal on the substrate at a position corresponding to the device terminal.

Abstract: An electrical termination unit for a microelectronic device, the electrical termination unit including, a carrier; and at least one metal tab being attached to the carrier; wherein the carrier is provided with at least one connection area where one electrical lead is to be electrically connected to one metal tab, and wherein the at least one connection area is configured to retain the least one electrical lead at least in one spatial dimension in a defined position relative to the one metal tab prior to a metallurgical connection process.

Abstract: A method for manufacturing an LED lamp assembly includes anodizing at least a portion of a surface of an electrically and thermally conductive base, such as an aluminum or aluminum alloy base, so as to form an electrically insulating coating. The base may form a heat sink or be coupled to a heat sink. The anodized surface is chemically etched and circuit traces that include an LED landing are formed on the etched anodized surface. LEDs are electrically and mechanically attached to the LED landing by way of conductive metallic solder such that heat generated from the LED is transferred efficiently through the solder and LED landing to the base and heat sink through a metal-to-metal contact pathway.

Abstract: An interposer is shown with contact points on a lateral edge. When assembled between a board under test and an integrated circuit, traces of the interposer carry signals between the board under test and the integrated circuit and also between signal lines of the integrated circuit and the lateral edge contact points. The signals can then be accessed by test equipment at the lateral edge contact points. The interposer may include additional components connected to the traces.

Abstract: A system controls a group of flash lamps to provide energy to a work product in a continuous motion processes. The system can identify optimal relationships among various parameters, including the speed of the target material, the physical spacing of the flash lamps, the pulse frequency, and the flash sequence of the lamps. The systems can respond to changes in conditions to automatically adjust parameters. These systems can be applied to design practical sintering, annealing, and/or curing systems.

Abstract: A component mounting apparatus includes: a conveyor device for sucking and holding a substrate in a substantially vertical posture and conveying the substrate in a direction extending along its flat plate surface; a plurality of working devices for performing a working process for mounting areas in edge portions of the substantially vertical-postured substrate received from the conveyor device. In the component mounting apparatus, each of the working devices includes: a substrate holder for sucking and holding the substrate in a substantially vertical posture; a holder up/down device for moving the sucked and held substrate to a downward working position; a receiving member for supporting an edge portion of the substrate positioned in the working position from its back face side; and a working unit for performing the working process on the mounting areas of the edge portions of the substrate positioned in the working position from its front face side.

Abstract: An automated assembly sensor cable has a generally wide and flat elongated body and a registration feature generally traversing the length of the body so as to identify the relative locations of conductors within the body. This cable configuration facilitates the automated attachment of the cable to an optical sensor circuit and corresponding connector. In various embodiments, the automated assembly sensor cable has a conductor set of insulated wires, a conductive inner jacket generally surrounding the conductor set, an outer jacket generally surrounding the inner jacket and a registration feature disposed along the surface of the outer jacket and a conductive drain line is embedded within the inner jacket. A strength member may be embedded within the inner jacket.

Abstract: Electronic components each having a chip module with module contacts and an antenna having antenna contacts is made by securing a plurality of the chip modules the inner face of a module film strip having an outer periphery projecting past the chip module with the chip modules spaced from one another at a uniform predetermined module spacing. A plurality of the antennas are secured to an inner face of an elongated antenna strip with the antennas spaced from one another by a predetermined antenna spacing. The module strip is longitudinally subdivided into sections each of which is of a length equal to the predetermined module spacing and each of which carries a respective chip module. The module-strip sections are pressed against the antenna strip such that the module contacts of each of the chip modules engage and bear on the antenna contacts of a respective antenna.

Abstract: A light strip includes a conductive plate including at least two first conductive strips, at least one column second conductive strips; first electric conductors including light sources soldered at said distance between said second conductive strips, second electric conductors soldered between said first conductive strips and said second conductive strips the light strip of the present invention not only has simple structures, but also has good stability.

Abstract: A board-mountable connector is provided. The connector includes a shield and an insulative housing with a tongue. Terminals are supported by the housing in two rows and the rows extend from a mating interface to a board mounting interface. The terminals may be mounted to the board via surface mount technology in two rows that are at about 0.4 mm pitch. The two rows of terminals are configured in a signal, signal, ground triangular configuration so as to provide a triangular terminal arrangement that extends from the mating interface to the mounting interface.

Abstract: An electrical connector and method assembling the same. A device may comprise a connector frame, a flexible printed circuit board connected to the connector frame, a filter mounted to the flexible printed circuit board; and at least one terminal mounted to the flexible printed circuit board and in electrical communication with the filter. A method to assemble an electrical connector may comprise: providing a flexible printed circuit board having two conductive pads and a filter in electrical communication with the two conductive pads; connecting each conductive pad to a corresponding terminal; inserting each terminal into corresponding holders in a connector frame; placing the flexible printed circuit board in a curved pathway of the connector frame to form a connector subassembly; and inserting the connector subassembly into a connector housing.

Abstract: An electronics module housing includes an external recess adapted to receive an associated DIN rail or other associated mounting structure. A latch mechanism is associated with the external recess and is adapted to engage the DIN rail. An electronics circuit board is located in the housing. An electrical connector is physically and electrically connected to the circuit board. The electrical connector includes: (i) a connector body; (ii) a plurality of electrical contacts secured to said connector body and comprising contact pins physically and electrically connected to the circuit board; and (iii) a ground contact secured to the connector body and including a ground pin physically and electrically connected to said circuit board. The ground contact includes a ground contact body that extends from the connector body into the housing recess. The ground contact body includes a ground contact face located adjacent the recess and adapted to contact the associated DIN rail to which the module is mounted.

Abstract: An electrical interconnect has an adhesive layer in which is formed an array of apertures, the apertures being of non-circular shape. An electrical circuit apparatus has a first circuit having at least one electrical contact, a second circuit having at least one electrical contact aligned to the electrical contact of the first circuit, and a standoff structure between the first and second circuits having at least one aperture aligned to one electrical contact of the first and second circuits, the aperture being of a non-circular shape.

Abstract: Forming antenna structures having several conductor turns (wire, foil, conductive material) on a an antenna substrate (carrier layer or film or web), removing the antenna structures individually from the antenna substrate using pick & place gantry or by means of die punching, laser cutting or laminating, and transferring the antenna structure with it's end portions (termination ends) in a fixed position for mounting onto or into selected transponder sites on an inlay substrate, and connecting the aligned termination ends of the antenna structure to an RFID (radio frequency identification) chip or chip module disposed on or in the inlay substrate. A contact transfer process is capable of transferring several antenna structures simultaneously to several transponder sites.

Abstract: A method of manufacturing an electronic component, which includes arranging a plurality of first electrode pads on a first substrate, and a plurality of second electrode pads on a second substrate, so that the first and second electrode pads correspond to each other. The method further includes forming a plurality of solder bumps on the second electrode pads and putting the first substrate over the second substrate. The first and second substrates are shifted in parallel to each other, in a horizontal direction, while the solder bumps are melting, so that the solder bumps are stretched in a slant direction to cause the solder bumps to be solidified into hourglass-shapes.

Abstract: A transceiver for a two-connector system includes a circuit board, at least one cable attached to the circuit board, and a housing arranged to contain the circuit board. The two-connector system includes a front connector and a back connector. When the transceiver is connected to the two-connector system, a front edge of the circuit board is arranged to engage with the front connector and an intermediate portion of the circuit board is arranged to engage with the back connector.

Abstract: The coaxial connector 10 to be connected with a coaxial cable has a surface covering layer 20 formed of a metal material which causes an eutectic reaction with In on the surface of a terminal 12 which is a core conductor. Because of the surface covering layer 20 of a metal material which causes the eutectic reaction with In formed on the surface of the terminal of the coaxial connector, the terminal of the coaxial connector and the electrode of a superconductor device can be jointed to each other by the solder layer of In-based solder at a relatively low temperature. Thus, the discharge of oxygen from the inside of the superconductor film of a superconductor filter can be suppressed, and the decrease of the critical temperature TC can be suppressed.

Abstract: According to one embodiment, a wiring board device is provided in which even if the temperature of a ceramic board becomes high, the influence on a connector can be reduced and the occurrence of defects due to heat can be prevented. The wiring board device includes a common member. The ceramic board and the connector are placed on the common member. A wiring pattern of the ceramic board and the connector are electrically connected by wiring.

Abstract: A vented BGA package is reconfigured by first applying a continuous bead of adhesive around the perimeter of the package to seal the gap between the lid and substrate. The continuous bead defines a channel through the pressure relief vents to a polarity through-hole in the lid. The BGA package is reflow soldered to a PWB at an elevated temperature using solder flux, clean or no-clean. The IC die achieves elevated temperature pressure relief through the pressure relief vents along the channel and out the polarity through-hole. After reflow a seal is applied to plug the polarity through-hole. The PWB is washed in an aqueous cleaner solution to remove flux residue. The continuous bead of adhesive and the seal form a cleaner solution barrier that prevents the solution from contacting conductors inside the package. The seal may be removed or left intact depending on the operating environment.

Abstract: The invention relates to a method to conductively connect an electrical component with at least one conductive layer, whereby the conductive layer is applied to a substrate which is essentially transparent in the visible wavelength zone of light, comprising the following steps: the electrical component or the conductive layer is provided with a soldering material in the area where the component is to be connected to the conductive layer; the soldering material is provided with energy supplied by an energy source, such that the soldering material melts and a non-detachable, material-bonded conductive connection between the electrical component and the conductive layer is established.

Abstract: A die having a base formed of a first material is connected to a board having a base formed of a second material. An interposer having a coefficient of thermal expansion intermediate coefficients of thermal expansion of the first and second materials is positioned between the die and the board.

Abstract: A cooling device for cooling electronic components includes a base plate, a power source, and a cooling module. The cooling module includes a cooling sheet and a thermal conductive base. The cooling sheet includes a hot surface and a cooling surface. The thermal conductive base is located above the cooling surface of the cooling sheet, and configured to support electronic components on a printed circuit board and transfer heat between the electronic components and the cooling surface. When the cooling sheet is powered on, the cooling surface is in a constant state of low temperature. Due to the heat transfer between the cooling surface and the thermal conductive base, heat from the electronic components can be transferred from the thermal conductive base to the cooling surface continuously.

Abstract: A connection structure for connecting an outer conductor of a differential signal transmission cable to a substrate includes a connecting member including a main body portion and a protruding portion protruding from the main body portion. The outer conductor is connected via the connecting member to the substrate. The connecting member is solder-connected to the outer conductor via the main body portion and is solder-connected to the substrate via the protruding portion.

Abstract: Connector receptacles that have a reduced height when combined with a printed circuit board and reduce wasted space inside an electronic device. One example provides a connector receptacle having contacts that may connect to edge contacts along an edge of a printed circuit board. This edge may be formed along a side of printed circuit board, by a hole or opening in a printed circuit board, or by a notch in a printed circuit board. Edge contacts may have straight surfaces, rounded surfaces, or they may have other types of surfaces. Connector receptacle contacts may have a “U,” fishhook, or other shape.

Abstract: An interconnect structure, an interconnect structure for interconnecting first and second components, an interconnect structure for interconnecting a multiple component stack and a substrate, and a method of fabricating an interconnect structure. The interconnect structure comprising a base portion formed on a mounting surface of a first component; a pillar portion extending from the base portion and substantially perpendicularly to the mounting surface; and a head portion formed on the pillar portion and having larger lateral dimensions than the pillar portion; wherein the base portion and the pillar portion are integrally formed of a homogeneous material.

Abstract: A method for manufacturing a probe card is provided wherein probes are held in a holding plate such that the respective probes correspond to through holes with their connecting end portions projected from one surface of the holding plate. A plate-like member including openings having larger diameters than diameters of the through holes and housing the connecting end portions in the openings is arranged by making one surface of the plate-like member abut the one surface of the holding plate. After supplying solder cream in the respective openings from the other surface of the plate-like member, a connection base plate and the holding plate are relatively fixed so that the solder cream, burying the connecting end portions of the respective probes held in the holding plate with the plate-like member removed, may abut the respective corresponding connection pads, and the solder cream is heated to melt the solder cream.

Abstract: A conductive rubber component (10) of the present invention includes a metal coating (2) formed on at least one surface located perpendicular to a compression direction of a conductive rubber single body (1) by atomic and/or molecular deposition, and can be surface mounted and soldered. In a method for mounting a conductive rubber component (10) of the present invention, the conductive rubber component (10) is surface mounted on a wiring layer (8) on a printed wiring board (9) and is fixed by a solder layer (7) thereto and thereby is incorporated to electrically connect the printed circuit board (9) and an electronic component (11) to each other.

Abstract: A microelectronic package can include wire bonds having bases bonded to respective ones of conductive elements exposed at a surface of a substrate. The wire bonds may have exterior edge surfaces disposed at an angle between 25° and 92° relative to the bases, and ends remote, e.g., opposite, from the bases, and remote from the ends which are connected to the bases. A dielectric encapsulation layer extends from the substrate and covers portions of the wire bonds such that covered portions of the wire bonds are separated from one another by the encapsulation layer, wherein unencapsulated portions of the wire bonds are defined by portions of the wire bonds that are uncovered by the encapsulation layer, the unencapsulated portions including the ends of the wire bonds.

Abstract: A first patterned etch stop layer and a first patterned conductor layer are laminated by a dielectric material to a second patterned etch stop layer and a second patterned conductor layer. As the etch stop metal of the first and second patterned etch stop layers is selectively etchable compared to a conductor metal of the first and second patterned conductor layers, the first and second patterned etch stop layers provide an etch stop for substrate formation etch processes. In this manner, etching of the first and second patterned conductor layers is avoided insuring that impedance is controlled to within tight tolerance.

Abstract: A method of interconnecting a conductor and a hermetic feedthrough of an implantable medical device includes welding a lead to a pad on a feedthrough. The feedthrough includes a ceramic insulator and a via hermetically bonded to the insulator. The via includes platinum. The pad is bonded to the insulator and electrically connected to the via, includes platinum, and has a thickness of at least 50 ?m.

Abstract: The electronic component mounting line includes a computing unit for calculating a print position of solder paste printed on board-side electrodes, an electronic component placement device for placing an electronic component onto the board-side electrodes by referencing the print position of the solder paste, a placement position control device for controlling the placement position of the electronic component by referencing the print position of the solder paste, a bonding device for melting the solder paste to bond the electronic component and the board-side electrodes to each other, and a mounting-position control device for controlling the mounting position of the electronic component by referencing the board-side electrode position. In this configuration, position control responsive to displacement of the electronic component by the self alignment effect exerted by the molten solder paste is fulfilled.

Abstract: High-speed interposer connectors that may be space-efficient, reliable, and may be readily manufactured. One example may provide an interposer connector that may be particularly space-efficient in a vertical direction by using an interposer to form an electrical connection between conductors and a main-logic board or other appropriate substrate. Another example may provide a reliable connection between conductors and a main-logic board by using fasteners to fix an interposer to the main-logic board. Another example may provide connectors that are well-suited to handling high-speed signals by providing a shield to at least partially cover a top of an interposer connector.

Abstract: A method for manufacturing a liquid discharge head includes heating the surface portion of power line that is to be in contact with a member made of resin, thereby forming, from a precious metal layer and a nickel layer, an adhesion layer made of an alloy containing precious metal and nickel as major components.

Abstract: In a lead mounting method of mounting, onto a principal surface of a printed board, a lead to be connected to a terminal, a flat lead is prepared which lead has a mounted part to be disposed on the principal surface of the printed board and a connected part to be connected to the terminal. The flat lead is bent into an L shape so that the mounted part and the connected part are perpendicular to each other to obtain an L-shaped lead. The mounted part of the L-shaped lead is connected and fixed onto the principal surface of the printed board by soldering.

Abstract: A charging receptacle having a barrel and a base configured to facilitate interconnecting electrical elements of a cordset with a vehicle charging system. The barrel may be configured to facilitate alignment of the electrical elements and the base may be configured to facilitate mounting the charger receptacle to a vehicle or other device having a system reliant on electrical energy provided through the cordset.

Abstract: A microelectronic package includes a microelectronic element including a first surface having contacts thereon, a second surface remote therefrom, and edge surfaces extending between the first and second surfaces. A reinforcing layer adheres to the at least one edge surface and extends in a direction away therefrom, the reinforcing layer not extending along the first surface of the microelectronic element. A conductive redistribution layer including a plurality of conductive elements extends from the contacts along the first surface and along a surface of the reinforcing layer beyond the at least one edge surface. An encapsulant overlies at least the reinforcing layer. The microelectronic element has a first coefficient of thermal expansion, the encapsulant has a second coefficient of thermal expansion, and the reinforcing layer has a third coefficient of thermal expansion that is between the first and second coefficients of thermal expansion.

Abstract: A method for bonding two electronic components includes inserting hollow and open inserts into full convex elements of a lower hardness than that of the inserts, where, when an insert is inserted into a full element at least one surface of the open end of the insert is left free from the full element so as to create an outlet passage for gases contained in the insert.

Abstract: A chip element in the form of a substantially rectangular parallelepiped having end surfaces and side surfaces is formed (step of forming chip element). An electrically conductive green sheet is formed (step of forming electrically conductive green sheet). An electrically conductive paste is applied to the end surfaces of the chip element (step of application electrically conductive paste). A chip element is formed in which the electrically conductive green sheet is attached to the end surface via the electrically conductive paste applied to the end surface of the chip element (step of attaching electrically conductive sheet). In the step of attaching, the end surface of the electrically conductive green sheet on the side of the side surfaces is positioned on the outside of the side surfaces, and the electrically conductive paste applied to the end surface is pressed out into a space between the electrically conductive green sheet and ridge portions.

Abstract: The invention relates to a method for applying a connection material with a specified shape on at least one surface of at least one workpiece, wherein the connection material and the surface have complementary wetting or wettable properties, and wherein the connection material (3) is deposited on at least one of the surfaces (2) and a shaping device (10, 10?) is arranged at least for the period of a flowable state of the connection material adjacent to the connection material as well as at least partially surrounding this material on the surface (2), wherein this device has a surface (11, 12) that is non-wettable with respect to the wetting properties of the connection material and that is designed for the forced guidance of the flow of the still flowable connection material in the region of the non-wettable surface that thus assumes a specified shape; and the shaped connection material is hardened.