Abstract: An electrical device that is electrically and mechanically connectable to another electrical device includes a face equipped with contact pads. An adhesive layer is on the face equipped with the contact pads. The adhesive layer is composed of a substance with adhesive properties. A plurality of openings through the adhesive are layer over each contact pad, and small metal sticks which have been grown electrolessly or electrochemically are in the areas where the openings have been created to form a plurality of conductive paths over each contact pad, the volume of which is defined by the openings.

Abstract: A rigid wave pattern formed on a first side of a substrate in a semiconductor die package. The rigid wave pattern aligns with and overlies the contact fingers formed on the second side of the substrate. The rigid wave pattern includes a first pattern with an etched portion and an unetched portion around the etched portion. When the substrate and dice are encased during the molding process, the rigid wave pattern effectively reduces deformation of and stresses on the dice, therefore substantially alleviating die cracking.

Abstract: A package structure and an electronic apparatus of the package structure are disclosed. The package structure includes a substrate and a plurality of pins. The plurality of pins is disposed on the substrate. The plurality of pins is interlaced to each other, so that a line along a specific direction will only pass one of the plurality of pins at most.

Abstract: A submount with an electrode layer having excellent wettability in soldering and method of manufacturing the same are disclosed. A submount (1) for having a semiconductor device mounted thereon comprises a submount substrate (2), a substrate protective layer (3) formed on a surface of the submount substrate (2), an electrode layer (4) formed on the substrate protective layer (3) and a solder layer (5) formed on the electrode layer (3) wherein the electrode layer (4) is made having an average surface roughness of less than 1 ?m. The reduced average surface roughness of the electrode layer (4) improves wettability of the solder layer (5), allowing the solder layer (5) and a semiconductor device to be firmly bonded together without any flux therebetween. A submount (1) is thus obtained which with the semiconductor device mounted thereon is reduced in heat resistance, reducing its temperature rise and improving its performance and service life.

Abstract: An integrated circuit device includes dummy through-silicon vias (TSVs) that can be connected to one or more voltage references, thereby increasing a capacitance associated with the integrated circuit device, such as a decoupling capacitance. In addition, the dummy TSVs can be distributed based on the distribution of active TSVs in the device, thus increasing the stability and performance of the TSV manufacturing process.

Abstract: A board-level package includes a printed circuit board, a semiconductor die package mounted on the printed circuit board, a tuned mass structure, and a support structure mounted to the printed circuit board and supporting the tuned mass structure.

Abstract: The present invention relates to processing of PCBA, and provides a method for enhancing reliability of a welding spot of a chip, a printed circuit board and an electronic device. The method for enhancing reliability of the welding spot of the chip includes: dipping an epoxy flux on a weld leg of a chip or coating, with epoxy flux, a bonding pad corresponding to the weld leg of the chip, and mounting the chip to the bonding pad; and performing reflow processing on the bonding pad mounted with the chip, and finishing curing the epoxy flux. By applying the present invention, an Underfill process is not required, thereby reducing the cost of the device and improving the manufacturing efficiency.

Abstract: A semiconductor device is of a PoP structure such that first electrode portions provided on a first device mounting board constituting a first semiconductor module and second electrode portions provided in a second semiconductor module are joined together by solder balls. A first insulating layer having an opening is provided on one main surface of an insulating resin layer which is a substrate, and an electrode portion, whose top portion protrudes above the top surface of the first insulating layer, is formed in the opening. A second insulating layer is provided on top of the first insulating layer in the periphery of the top portion of the first electrode portion; the second insulting layer is located slightly apart from the top portion of the first electrode portion. The first electrode portion is shaped such that the top portion is formed by a curved surface or formed by a curved surface and a plane surface smoothly connected to the curved surface.

Abstract: An interposer including stress-engineered nonplanar microsprings may provide interconnection of bonding pads of electronic structures disposed above and below the interposer. The lateral offset between an anchor portion of a microspring disposed for contact at a bottom surface of the interposer and the tip of the microspring located in a free portion of the microspring for contact and deflection over a top surface of the interposer permits the interconnection of devices having different bonding pad pitches. Microspring contacts at the free portion permit temporary interconnection of devices, while solder applied over the free portion permit permanent connection of devices to the interposer.

Abstract: A semiconductor device includes a semiconductor integrated circuit device (1). In the semiconductor integrated circuit device (1), a semiconductor integrated circuit (5) is formed on a center of the surface of a semiconductor substrate (3), and a plurality of electrode terminals (71, 73, . . . ) are provided on the surface of the semiconductor substrate (3). A protection film (9) is provided on the surface of the semiconductor substrate (3) such that the surfaces of the electrode terminals (71, 73) are exposed. The electrode terminals (71, 73, . . . ) include an electrode terminal (73) having a thin portion (74). The surface of the thin portion (74) is located below the surfaces of the electrode terminals except for the electrode terminal (73) having the thin portion (74) among the electrode terminals (71, 73, . . . ).

Abstract: An electronic system includes an insulating structural element with a coupling surface configured for coupling the electronic system with at least one further electronic system. The electronic system further includes at least one conducting contact element at least partially exposed on the coupling surface. Each conducting contact element has a soldering surface supporting reflow soldering of the conducting contact element with a corresponding further contact element of the further electronic system. In addition, each conducting contact element has at least one lateral surface protruding from the insulating structural element. The soldering surface of the conducting contact element includes at least one channel having an opened end at the protruding lateral surface, the channel configured to facilitate dispersion of waste gas produced during reflow soldering.

Abstract: Stacked microfeature devices and associated methods of manufacture are disclosed. A package in accordance with one embodiment includes first and second microfeature devices having corresponding first and second bond pad surfaces that face toward each other. First bond pads can be positioned at least proximate to the first bond pad surface and second bond pads can be positioned at least proximate to the second bond pad surface. A package connection site can provide electrical communication between the first microfeature device and components external to the package. A wirebond can be coupled between at least one of the first bond pads and the package connection site, and an electrically conductive link can be coupled between the first microfeature device and at least one of the second bond pads of the second microfeature device. Accordingly, the first microfeature device can form a portion of an electrical link to the second microfeature device.

Abstract: Methods, apparatuses, and computer program products are disclosed for controlling plating stub reflections in a chip package. In one embodiment, a resonance optimizer determines performance characteristics of a bond wire that connects a chip to a substrate of a semiconductor chip mount. In this embodiment, the resonance optimizer selects, based on the performance characteristics of the bond wire, a line width for an open-ended plating stub that extends from a signal interconnect of the substrate to a periphery of the substrate, The resonance optimizer also generates a design of signal traces for the substrate, where the signal traces include the open-ended plating stub with the selected line width.

Abstract: A multi-phase voltage regulator is disclosed where each phase is comprised of an array of high and low side transistors that are integrated onto a single substrate. Further, a system of mounting the voltage regulator onto a flip chip and lead frame is disclosed wherein the source and drain lines form an interdigital pattern.

Abstract: An interconnection component includes a first support portion has a plurality of first conductive vias extending therethrough substantially perpendicular to surfaces thereof such that each via has a first end adjacent a first surface and a second end adjacent a second surface. A second support portion has a plurality of second conductive vias extending therethrough substantially perpendicular to surfaces thereof such that each via has a first end adjacent the first surface and a second end adjacent the second surface. A redistribution layer is disposed between the second surfaces of the first and second support portions, electrically connecting at least some of the first vias with at least some of the second vias. The first and second support portions can have a coefficient of thermal expansion (“CTE”) of less than 12 parts per million per degree, Celsius (“ppm/° C.”).

Abstract: A module (1) includes a first functional device (2) and a second functional device (3). The first functional device (2) includes a base electrode, an emitter electrode and a collector electrode. The second functional device (3) includes at least one electrode. The module (1) further includes a conductive frame (4). One of the base electrode, the emitter electrode, and the collector electrode of the first functional device (2) is directly connected to the frame (4). The electrode of the second functional device (3) is also directly connected to the frame (4). The frame (4) includes a portion serving as a terminal for external connection.

Abstract: Embodiments of the present invention relate to circuit layouts that are compatible with printing electronic inks, printed circuits formed by printing an electronic ink or a combination of printing and conventional blanket deposition and photolithography, and methods of forming circuits by printing electronic inks onto structures having print-compatible shapes. The layouts include features having (i) a print-compatible shape and (ii) an orientation that is either orthogonal or parallel to the orientation of every other feature in the layout.

Abstract: An electrical connection arrangement includes an IC package, and a PCB having a plurality of receiving holes for receiving a plurality of contacts therein. The contact having a contacting portion engaged with the IC package that seated upon the PCB. A retaining device is provided for securing the IC package onto the PCB. Since there is no socket utilized in the present invention, the total profile of the arrangement and the cost are effectively reduced.

Abstract: A wiring board having a lead pin is provided. The wiring board having the lead pin includes a connecting pad which is formed on the wiring board, and to which the lead pin is bonded through a conductive material. The lead pin includes: a shaft portion; a head portion which is provided on one end of the shaft portion; a protruded portion which is formed on a surface side of the head portion opposed to the connection pad; and a first taper portion which is formed between the head portion and a base part of the shaft portion.

Abstract: A multilayered feedthrough for an implantable medical device includes a substrate having a first edge, a second edge, and a substrate length. A plurality of traces is formed on the substrate and extends along the substrate length. The plurality of traces extends to the first and second edges of the substrate. An insulator layer is formed on the substrate and the plurality of traces. A ground plane layer is formed on the insulator layer.

Abstract: An electronic component includes an electrically conductive carrier. The electrically conductive carrier includes a carrier surface and a semiconductor chip includes a chip surface. One or both of the carrier surface and the chip surface include a non-planar structure. The chip is attached to the carrier with the chip surface facing towards the carrier surface so that a gap is provided between the chip surface and the carrier surface due to the non-planar structure of one or both of the carrier surface and the first chip surface. The electronic component further includes a first galvanically deposited metallic layer situated in the gap.

Abstract: A base insulating layer is formed on a suspension body, and write wiring traces and read wiring traces are formed on the base insulating layer. The write wiring trace and the read wiring traces are formed on a body region of the base insulating layer, and the write wiring trace is formed on an auxiliary region of the base insulating layer. The base insulating layer is bent along a bend portion. This causes the write wiring trace to be positioned above the write wiring trace.

Abstract: A microelectronic assembly can include first and second microelectronic packages mounted to respective first and second opposed surfaces of a circuit panel. Each microelectronic package can include a substrate having first and second apertures extending between first and second surfaces thereof, first and second microelectronic elements each having a surface facing the first surface of the substrate and a plurality of contacts at the surface of the respective microelectronic element aligned with at least one of the apertures, a plurality of terminals exposed at the second surface in a central region thereof, and leads electrically connected between the contacts of each microelectronic element and the terminals. The apertures of each substrate can have first and second parallel axes extending in directions of the lengths of the respective apertures. The terminals of each microelectronic package can be configured to carry all of the address signals transferred to the respective microelectronic package.

Abstract: A printed circuit board includes first and second layout layers, first and second components, and a pair of connecting portions. The first layout layer includes a pair of first conducting portions connected to a control chip. The second layout layer includes pairs of second to fourth conducting portions. The connecting portions connect the first and third conducting portions together. When an electronic device is connected to the second conducting portions, and the first and second components are connected to the third and fourth conducting portions to form a first route, signals generated by the control chip are transmitted to the electronic device through the first route. When the electronic device is connected to the fourth conducting portions, and the first and second components are connected to the second and third conducting portions to form a second route, the signals are transmitted to the electronic device through the second route.

Abstract: A stacked integrated circuit (IC) device includes a semiconductor IC having an active face, and an interconnect structure. The active face receives a regulated voltage from a voltage regulator (MEG). An active portion of the VREG, which supplies the regulated voltage to the semiconductor IC is coupled to the interconnect structure. A packaging substrate includes one or more inductors including a first set of through vias. The first set of through vias are coupled to the interconnect structure and cooperate with the active portion to provide the regulated voltage for the semiconductor IC. The IC also includes a printed circuit board (PCB) coupled to the packaging substrate. The PCB includes a second set of through vias coupled to the first set of through vias. The IC also includes one or more conducting paths on the PCB. The conducting path(s) couple together at least two through vias of the second set of through vias.

Abstract: A multi-chip module (MCM) is described. This MCM includes at least two substrates that are remateably mechanically coupled by positive and negative features on facing surfaces of the substrates. These positive and negative features may mate and self-lock with each other. For example, the positive features on one of the surfaces may include pairs of counterposed micro-springs, and the negative features may include pits or grooves on the other surface. When the substrates are mechanically coupled, a given pair of positive features may provide a force in a plane of the other surface. Furthermore, by compressing the MCM so that the surfaces of the substrates are pushed toward each other, the mechanical coupling may be released.

Abstract: An LED package includes a die pad having a bottom surface, an upper surface and a centrally located recessed cavity. The recessed cavity has a chip attach surface between the bottom surface and upper surface and sidewalls that extend from the recessed chip attach surface to the upper surface. The package additionally has leads arranged on opposing sides of the die pad. The leads have a bottom surface that is coextensive with the bottom surface of the die pad and an upper surface coextensive with the upper surface of the die pad. An LED chip is attached to the chip attach surface. The package further includes a package body having an encapsulant which fills space between the die pad and leads forming a bottom encapsulant surface that is coextensive with the bottom surfaces of the die pad and leads.

Abstract: A board-level package includes a printed circuit board, a semiconductor die package mounted on the printed circuit board, a tuned mass structure, and a support structure mounted to the printed circuit board and supporting the tuned mass structure.

Abstract: An electric drive (1) with a circuit board (2), having conductor tracks (3) and contact openings (4) with plated through-holes (5) and equipped with electronic components (6), the circuit board (2) being coated with a protective layer (7) of insulating material, and press-fit contacts (8) are inserted into the contact openings (4) and in electrical contact areas (9) within the contact openings (4) electrical contact exists between a press-fit contact (8) and the plated through-hole (5) of the contact opening (4). The task of the invention is to reliably protect circuit boards of electric drives exposed to moisture and other chemical environmental effects and contact them economically.

Abstract: A method of forming a stackable treated via package includes coupling interconnection balls to terminals. The interconnection balls are encapsulated in a package body. Via apertures are formed in the package body to expose the interconnection balls. The interconnection balls are treated to form treated interconnection balls comprising treated surfaces. The treated interconnection balls of the stackable treated via package enhance bonding with interconnection balls of a stacked electronic component package thus maximizing yield.

Abstract: An electronic component and a method of manufacturing an electronic component including a first surface mount device and a second surface mount device are provided. The first surface mount device and the second surface mount device are joined to a substrate via joint materials such that either or both of the first and second surface mount devices are shifted from the locations corresponding to land electrodes located on the substrate so as to be aligned with each other and are subjected to a reflow process. The outer land electrodes are formed at locations shifted inwardly from the locations corresponding to a virtual arrangement state in which the first surface mount device and the second surface mount device are arranged in series such that an end surface of the first surface mount device is in contact with an end surface of the second surface mount device.

Abstract: A method of manufacturing a connector is provided. Firstly, a substrate having a first surface, a second surface opposite to the first surface and a through hole is provided. Next, a first conductive layer covering the inside wall of the through hole is formed on the substrate. Then, a filler is filled in the through hole to form a filler post. Next, a conductive elastic cantilever is formed over the first surface and electrically connected to the first conductive layer. Then, a gold layer is formed on the conductive elastic cantilever and over the first surface. A solder ball electrically connected to the first conductive layer is formed over the second surface.

Abstract: In accordance with an embodiment, a substrate layout comprises a ground plane of a first power loop on a layer of a substrate, a first trace rail on the layer extending along a first periphery of the ground plane, and a first perpendicular trace coupled to the first trace rail. The ground plane is between the first trace rail and a die area, and the first perpendicular trace extends perpendicularly from the first trace rail. The first trace rail and the first perpendicular trace are components of a second power loop.

Abstract: A carrier substrate includes a substrate having a chip side and a PCB side, a plurality of bond pads disposed on the chip side for bonding a chip, a plurality of land grid array (LGA) pads disposed on the PCB side, and a plurality of resilient flanges installed on the PCB side in an array manner. The plurality of resilient flanges electrically connects with the LGA pads correspondingly.

Abstract: An active device array substrate has at least one patterned conductive layer. The patterned conductive layer includes a copper layer. A cross-section of the copper layer which is parallel to a normal line direction of the copper layer includes a first trapezoid and a second trapezoid stacked on the first trapezoid. A base angle of the first trapezoid and a base angle of the second trapezoid are acute angles, and a difference between the base angle of the first trapezoid and the base angle of the second trapezoid is from about 5° to about 30°.

Abstract: A semiconductor device reduces the impedance of a wiring for supplying the circuit excluding a data output circuit with a power source voltage or a ground voltage and of speedup of data signal transmission in the data output circuit. Additional substrates 2a, 2b are on the upper surface of semiconductor chip 1. First additional wiring layer for power source 10d and first additional wiring layer for ground 10s formed on respective additional substrates 2a, 2b form prescribed conductive areas on semiconductor chip 1. First power source wiring 40C1d or first ground wiring 40C1s are interconnected through additional wiring layers 10d and 10s. Second power source wiring 40C2d and second ground wiring 40C2s, which is extended in the same direction as with DQ system signal wiring 40CDQ, forms a feedback current path. Second power source wiring 40C2d and second ground wiring 40C2s are disposed adjacent to DQ system signal wiring 40CDQ.

Abstract: The invention relates to an electronic module comprising a stack of n packages of predetermined thickness E, which are provided on a lower surface with connection balls of predetermined thickness eb, said connection balls being connected to a printed circuit for interconnecting the package. The printed circuit is placed on the lower surface of the package level with the balls, is drilled with metallized holes, in which the balls are located and to which they are connected, and has a thickness eci less than eb so as to obtain a module with a total thickness not exceeding n (E+10% eb).

Abstract: A printed circuit board includes a signal layer, a power layer, and a ground layer. The signal layer includes an analog audio input/output (I/O) port and an audio chip. The audio chip includes a main body, a first group of signal pins connected to the analog audio I/O port and a second group of signal pins connected to a control chip. The power layer and the ground layer each is divided into two unconnected parts, an audio part and a digital part, by a dividing groove. The two audio parts act as a whole reference plane for traces between the analog audio I/O port and the first group of signal pins of the audio chip. The two digital parts act as reference planes for traces between the control chip and the second group of signal pins of the audio chip.

Abstract: An electronic component package includes: an insulating carrier substrate; a connection wiring that is provided on one side of the carrier substrate; an IC chip that is connected to the connection wiring; an external connection land that is disposed on the other side of the carrier substrate and is connected to the connection wiring via a wiring in the carrier substrate; and a solder ball that is disposed on the external connection land. A region of the external connection land that can be bonded to the solder ball has an outer shape that includes at least one arc portion and at least one straight portion. With this configuration, it is possible to provide an electronic component mounted apparatus in which bonding failure of the external connection land and the circuit board-side land with the solder ball can be reduced, and the bonding state can be easily inspected, and a method of inspecting a bonding portion therein.

Abstract: In one embodiment, differential signaling and ground contacts are located in a rectilinear array of rows and columns with ground contacts spaced apart by three times the pitch distance between adjacent rows or columns and signaling contacts are located immediately adjacent the ground contacts. In particular, the two contacts of each differential pair are located one pitch distance apart from each other and one contact of each differential pair of contacts is located one pitch distance from a ground contact and the other contact of the differential pair is located approximately sqrt(2)*pitch distance from the same ground contact. In a second embodiment, differential signaling and ground contacts are located in a hexagonal array with ground contacts located three times the pitch distance between adjacent contacts and signaling contacts located immediately adjacent the ground contacts.

Abstract: Provided is a simplified structure of a circuit device in which a power element generating a large amount of heat is incorporated. The circuit device according to the present invention includes: a circuit board whose surface is covered with an insulating layer; a conductive pattern formed on the surface of the insulating layer; a circuit element electrically connected to the conductive pattern; and a lead connected to a pad formed of the conductive pattern. Furthermore, a power element is fixed to the top surface of a land portion formed of a part of the lead. Accordingly, the land portion serves as a heat sink, thereby contributing to heat dissipation.

Abstract: Disclosed herein are a soldering connecting pin, a semiconductor package substrate and a method of mounting a semiconductor chip using the same. A semiconductor chip is mounted on the printed circuit board using the soldering connecting pin inserted into a through-hole of the printed circuit board, thereby preventing deformation of the semiconductor package substrate and fatigue failure due to external shocks.

Abstract: Cylindrical packages are provided. The cylindrical package includes a cylindrical substrate having a hollow region therein and at least one semiconductor chip mounted on an outer circumference of the cylindrical substrate. Related electronic products and related fabrication methods are also provided.

Abstract: Apparatus for electrically connecting two substrates using a land grid array (LGA) connector provided with a frame structure having power distribution elements. In an embodiment, the frame structure includes a frame having one or more conductive layers sandwiched between non-conductive layers. The frame may, for example, be a printed wire board (PWB) having power planes that distribute power from a first substrate (e.g., a system PWB) and/or a power cable to a second substrate (e.g., an electronic module). The frame includes one or more apertures configured to receive an LGA interposer for electrically connecting the two substrates. Preferably, the frame includes four apertures arranged in quadrants that each receive an interposer, and at least one power plane extends between two quadrants and/or adjacent to a peripheral edge of one or more quadrants in the form of stacked and/or parallel bus bars each defining a power domain.

Abstract: An array of contact pads on a semiconductor structure has a pitch less than twice an overlay tolerance of a bonding process employed to vertically stack semiconductor structures. A set of contact pads within the area of overlay variation for a matching contact pin may be electrically connected to an array of programmable contacts such that one programmable contact is connected to each contact pad within the area of overlay variation. One contact pad may be provided with a plurality of programmable contacts. The variability of contacts between contact pins and contact pads is accommodated by connecting or disconnecting programmable contacts after the stacking of semiconductor structures. Since the pitch of the array of contact pins may be less than twice the overlay variation of the bonding process, a high density of interconnections is provided in the vertically stacked structure.

Abstract: A leadframe for the assembly of a semiconductor chip has regions (112) with an original smooth surface of glossy appearance and regions (113, 114, 210) of a frosty appearance with rough surface contours. The regions of rough surface contours include two-dimensional arrays of spots (401) comprising a central area (402) below the original surface (400) and a piled ring (403) above the original surface. The piled ring (403) consists of the leadframe material in amorphous configuration.

Abstract: Provided is a structure and disposing method of a radio frequency (RF) layered module using three dimensional (3D) vertical wiring. A first wafer in the RF layered module having the 3D vertical wiring may include a first RF device and at least one first via- hole. A second wafer may include a second RF device and at least one second via-hole disposed at a location corresponding to the at least one first via-hole. A vertical wiring may connect the at least one first via-hole and the at least one second via-hole. The vertical wiring may be configured to be connected to an external device through a bottom surface of the at least one first via-hole or a top surface of the at least one second via-hole.

Abstract: An apparatus and method uses a first Faraday cage portion and a second Faraday cage portion to provide a Faraday cage enclosure surrounding at least one circuit device. For example, the first Faraday cage portion may include a first conductive portion of a Faraday cage enclosure surrounding the at least one circuit device, and a second Faraday cage portion may include a second conductive portion of the Faraday cage enclosure surrounding the at least one circuit device. Further, for example, the first Faraday cage portion may include a connection surface having one or more conductive contact portions terminating the first conductive portion of the Faraday cage enclosure the second Faraday cage portion may include a connection surface having one or more conductive contact portions terminating the second conductive portion of the Faraday cage enclosure. An electrical connection may be provided between the conductive contact portions of the first and second Faraday cage portions.

Abstract: In a multi-layered wiring substrate according to an exemplary aspect of the present invention, a conductor formed in an edge face area functions as a pad for mounting a connector.

Abstract: In accordance with some embodiments of the present disclosure, a chip package is provided. The chip package may include a chip, a substrate, and an interconnect layer disposed between the chip and the substrate. In some embodiments, the interconnect layer may include an array of bonding interconnects configured to provide electrical communication between the chip and a printed circuit board and reinforcement interconnects arranged around an outermost row of the array of bonding interconnects.