Abstract: A wiring board includes a core substrate including an insulation base member; linear conductors configured to pierce from a first surface of the insulation base member to a second surface of the insulation base member; a ground wiring group including a first ground wiring formed on the first surface of the core substrate, and a belt-shaped second ground wiring formed on the second surface of the core substrate and electrically connected to the first ground wiring by way of a part of the linear conductors; and an electric power supply wiring group including a first electric power supply wiring formed on the first surface, and a second electric power supply wiring formed on the second surface and electrically connected to the first electric power supply wiring by way of a part of the plural linear conductors.

Abstract: An integrated circuit (IC) device includes an interposer having a dielectric substrate having a first side, a second side, and an inner aperture, wherein a plurality of electrically conductive traces are on the first side. An IC die includes a topside semiconductor surface having active circuitry and a bottomside surface, wherein the topside semiconductor surface includes a plurality of bond pads, and is attached over the inner aperture onto the interposer. First wirebond interconnects couple respective bond pads to respective electrically conductive traces. A workpiece includes a top workpiece surface including a plurality of contact pads thereon attached to the first side of the interposer. Second interconnects couple respective conductive traces to respective contact pads on the workpiece.

Abstract: A stacked multichip package comprises a first chip having a first active surface and a first rear surface, a first chip carrier having a first opening and being configured to carrier the first active surface, a plurality of first conductive leads passing through the first opening and being configured to electrically connect the first active surface and the first chip carrier, a second chip having a second active surface and a second rear surface, an adhesive layer configured to enclose the first conductive leads and to electrically couple the first chip carrier to the second rear surface, a second chip carrier having a second opening and being electrically connected to the second active surface, and a plurality of conductive leads passing through the second opening and being configured to electrically connect the second active surface and the second chip carrier.

Abstract: A wiring board including a core substrate made of an insulative material and having a penetrating portion, a first interlayer insulation layer formed on the surface of the core substrate, a first conductive circuit formed on the surface of the first interlayer insulation layer, a first via conductor formed in the first interlayer insulation layer, and an electronic component accommodated in the penetrating portion of the core substrate and including a semiconductor element, a bump body mounted on the semiconductor element, a conductive circuit connected to the bump body, an interlayer resin insulation layer formed on the conductive circuit, and a via conductor formed in the interlayer resin insulation layer. The first via conductor has a tapering direction which is opposite of a tapering direction of the via conductor in the electronic component.

Abstract: A semiconductor package which is structured to allow for the edge mounting thereof in a vertical mount orientation. The semiconductor package comprises a flexible substrate or “flex circuit.” The flexible substrate includes a conductive pattern disposed on a first surface thereof, and a plurality of conductive pads or terminals disposed on a second surface thereof which is disposed in opposed relation to the first surface. Mounted to the first surface of the flexible substrate are one or more electronic components such as semiconductor dies. The semiconductor die(s) is/are electrically connected to the conductive pattern, and thereafter covered or encapsulated by a package body applied to a portion of the first surface of the flexible substrate. That portion of the flexible substrate including the conductive pads or terminals formed on the second surface thereof is thereafter folded and adhered to a portion of the package body through the use of a suitable adhesive.

Abstract: Provided is a semiconductor package including: a semiconductor chip mounted on a die pad; at least one lead connected electrically to the semiconductor chip; and a flexible film substrate including a metal wiring, which electrically connects the semiconductor chip and the at least one lead, wherein the semiconductor chip is electrically connected to the film substrate through a first connection member which contacts the semiconductor chip and the metal wiring; and the film substrate is electrically connected to the at least one lead through a second connection member which contacts the metal wiring and the at least one lead.

Abstract: A semiconductor chip package comprises a lead frame having a chip carrier having a first surface and an opposite second surface. A first semiconductor chip is mounted on the first surface, having a plurality of bonding pads thereon, wherein the first semiconductor chip has an area larger that that of the chip carrier. A package substrate has a central region attached to the second surface of the chip carrier, having an area larger than that of the first semiconductor chip, wherein the package substrate comprises a plurality of fingers on a top surface thereof in a marginal region of the package substrate, which are arranged in an array with a row of inner fingers adjacent to the first semiconductor chip and a row of outer fingers adjacent to an edge of the package substrate, wherein the inner and outer fingers are electrically connected to the bonding pads of the first semiconductor chip and the lead frame respectively.

Abstract: Provided are a hybrid substrate, a semiconductor package including the same, and a method for fabricating the semiconductor package. The hybrid substrate may include an insulation layer, and an organic layer. The insulation layer may include a top, a bottom opposite to the top, and a conductive pattern having different pitches. The organic layer may be connected to the bottom of the insulation layer, and may include a circuit pattern connected to the conductive pattern. The conductive pattern may include a first metal pattern, and a second conductive pattern. The first metal pattern may have a first pitch, and may be disposed in the top of the insulation layer. The second conductive pattern may have a second pitch greater than the first pitch, and may be extended from the first metal pattern to be connected to the circuit pattern through the insulation layer.

Abstract: A semiconductor device includes a base film, a semiconductor chip mounted on the base film, and a plurality of leads formed on the base film, each of the leads including one end coupled to the semiconductor chip and another end being opposite to the one end. The another end of a first one of the leads and the another end of a second one of the leads are located at different positions respectively between the semiconductor chip and a cut line along which the base film is cut.

Abstract: Semiconductor die packages are disclosed. An exemplary semiconductor die package includes a premolded substrate. The premolded substrate can have a semiconductor die attached to it, and an encapsulating material may be disposed over the semiconductor die.

Abstract: Including a wiring board having an electronic component mounted at least on a first surface, a resin applied at least between the electronic component and the wiring board, and a through-hole provided in a region corresponding to the mounting position of the electronic component in the wiring board, a protrusion is formed on the wiring board so as to overlap at least with the electronic component, around a region corresponding to the mounting position of the electronic component.

Abstract: A semiconductor device, such as a semiconductor device of chip on film package, is provided. The semiconductor device includes at least an integrated circuit formed on a film base, each integrated circuit includes a chip and a plurality of leads formed interior to a boundary of a predetermined range, each lead is formed with a predetermined distance from the boundary. While the integrated circuit is punched from the film base along the boundary, conductive residue of leads left on the puncher is therefore reduced or avoided.

Abstract: A semiconductor package including a semiconductor chip; a base member on which the semiconductor chip is mounted; a plurality of leads formed on the base member, the leads including inner ends electrically connected to the semiconductor chip and outer ends; and an index for identifying locations of specific leads.

Abstract: The mounting height of a semiconductor device is reduced. A wiring substrate has an upper surface with multiple bonding leads formed therein and a lower surface with multiple lands formed therein. This wiring substrate is a multilayer wiring substrate and multiple wiring layers and multiple insulating layers are alternately formed on the upper surface side and on the lower surface side of the core material of the wiring substrate. The bonding leads are formed of part of the uppermost wiring layer and the lands are formed of part of the lowermost wiring layer. The insulating layers include second insulating layers containing fiber and resin and third insulating layers smaller in fiber content than the second insulating layers. The second insulating layers are formed on the upper surface side and on the lower surface side of the core material. The third insulating layers are formed on the upper surface side and on the lower surface side of the core material with the second insulating layers in-between.

Abstract: A semiconductor device includes a circuit base including an inner lead portion and an outer lead portion. The inner lead portion has a plurality of inner leads. At least part of the inner leads is routed inside a chip mounting area. On both upper and lower surfaces of the circuit base, a first and a second semiconductor chip are mounted. At least part of electrode pads of the first semiconductor chip are electrically connected to electrode pads of the second semiconductor chip via the inner leads.

Abstract: An LED lead frame comprises an insulative housing including a top surface, a bottom surface, and four side surfaces connected the top surface and the bottom surface, and a cavity recessed from the top surface. A pair of conductive leads each has a portion embedded into the insulative housing and another portion exposed out of the insulative housing. The another portion includes an end portion extending downwardly along one of the side surface, a bottom soldering portion extending continuously from the end portion along the bottom surface, and a pair of side soldering portions extending upwardly from two ends of the bottom soldering portion along another two opposite side surfaces. The bottom soldering portion and the side soldering portions can be used as an alternative mounting surface.

Abstract: In one embodiment of the present invention, an IC chip mounting package includes a film base member and an IC chip connected via an interposer. Connecting terminals on the film base member side of the interposer are provided so as to have a pitch larger than that of connecting terminals of the IC. A device hole is opened to the film base member, and the IC chip is provided in the device hole. A distance between an inner lead leading end and a periphery of the device hole is set as not less than 10 ?m.

Abstract: A component built-in wiring board is provided. The component built-in wiring board 10 includes a core substrate 11, a first component 61, a first built-up layer 31 and a capacitor 101. The core substrate 11 has a housing hole 90 and the first component 61 is housed in the housing hole 90. A component mounting region 20 capable of mounting a second component 21 is provided in a surface 39 of the first built-up layer 31. The capacitor 101 has electrode layers 102 and 103 and a dielectric layer 104. The capacitor 101 is embedded in the first built-up layer 31 such that a first front surface 105 and a second front surface 106 in the electrode layer 102 and a first front surface 107 and a second front surface 108 in the electrode layer 103 are disposed in parallel with the surface 39 of the first built-up layer 31.

Abstract: A pressure sensor includes a sense element port, a support ring and a plurality of interference fit slits to provide a flexible interference fit between the sense element port and the support ring to form a substantially flush lap joint. The sensor also includes an electronics board inside the support ring and attached to planar mounting tabs which provide a stable mounting. Gel flow barriers protect electronics board features from unwanted non-conductive gel. Double-ended symmetrical, tapered contact springs provide manufacturing cost savings and contribute to improved alignment of an interface connector of the sensor.

Abstract: Embodiments in accordance with the present invention relate to techniques which avoid the problems of deformation in the shape of a solder connection in a flip chip package, resulting from solder reflow. In one embodiment, a solder-repellent surface is created adjacent to the solder to constrain the reflow and thereby maintain the vertical profile of the solder. Examples of such a solder-repellent surface include an oxide (such as Brown Oxide) of the lead frame, or a tape (such as Kapton) which is used as a dam bar to control/constrain the solder flow on the leads prior to the encapsulation step. In another embodiment, the solder connection may be formed from at least two components. The first component may reflow at high temperatures to provide the necessary adhesion between solder ball and the die, with the second component reflowing at a lower temperature to provide the necessary adhesion between the solder ball and the leads.

Abstract: Stress concentration at the connecting portion of the electronic component and the curved board and the area around the connecting portion is suppressed. In a flexible wiring board, insulation layers (11, 13) and wiring layers (12, 15) are piled up alternately and wiring layers (12, 15) are via-connected each other. The board comprises reinforced area (10a) reinforced against external stress, bending area (10c) bending easier than the reinforced area (10a) by external stress, and a stress relaxation area (10b) provided in area between the reinforced area (10a) and the bending area (10c), bending easier than the reinforced area (10a) but not easier than the bending area (10c) by the external stress, and relaxing the stress carried from the bending area (10c) to the reinforced area (10a).

Abstract: A wiring structure having a wiring-terminal-connection adhesive that includes a curing agent capable of generating a free radical upon heating, a radically polymerizable substance and silicone particles.

Abstract: This invention provides a wiring-terminal-connecting adhesive comprising a curing agent capable of generating a free radical upon heating, a radically polymerizable substance and silicone particles, and a wiring-terminal-connecting method and a wiring structure which make use of such an adhesive.

Abstract: A sensing module comprises a carrier, a sensor, a substrate, and a plurality of chips. The carrier has a carrying surface and a back surface opposite to the carrying surface. The sensor and the substrate are disposed on the carrying surface and are electrically connected to the carrier respectively. The chips are disposed on the substrate and are electrically connected to the substrate respectively. The production cost of the sensing module is low.

Abstract: A tape carrier substrate includes: a tape carrier base 1; a first terminal section 2A including a plurality of first terminals 2a arranged with one another in a first direction W; a second terminal section 2B including a plurality of second terminals 2b; and first and second conductive wires 3a and 3b. A plurality of slits 7 arranged with one another in the first direction are provided in the tape carrier base. An interval between one of the plurality of slits placed at one end in the first direction and a corresponding end of the tape carrier base in the first direction and an interval between another one of the plurality of slits placed at the other end in the first direction and a corresponding end of the tape carrier base in the first direction are greater than an interval between adjacent ones of the plurality of slits.

Abstract: An integral impedence is formed on or within a lead frame pin of a semiconductor package and receives a connection from an electrode of a semiconductor die within the package to eliminate the need for adjustment and protective impedences external of the package. The impedence comprises passives such as resistors, capacitors, diodes or inductors which modify the performance of the package for new semiconductor device characteristics. The impedences may have positive or negative temperature coefficients and are in close thermal communication with the semiconductor die.

Abstract: A portion of a frame body is fixed on a surface of a heat-radiating plate, and on frame body, a semiconductor chip is die-bonded. Next, a prescribed electrode of semiconductor chip and corresponding lead terminal and the like are electrically connected by a prescribed wire. Next, the lead frame is set in a metal mold such that the semiconductor chip is covered with resin from above the semiconductor chip. Thermoplastic resin is introduced into the metal mold, and semiconductor chip and the like are sealed. By taking out the resulting body from the metal mold, a semiconductor is formed. Thus, a semiconductor device can be provided with reduced manufacturing cost.

Abstract: A TSOP (Thin Small Outline Package) contains a MOSFET and a Schottky diode. The MOSFET has a source terminal a gate terminal and a drain terminal. The Schottky diode has a cathode terminal, a anode terminal. The TSOP contains the MOSFET and the Schottky diode with a special configuration by placing the drain terminal of the MOSFET and the anode terminal of the Schottky diode on a same side. Specifically, the TSOP implements a leadframe that comprises a plurality of leads. The drain terminal of the MOSFET and the anode terminal extends outside of the TSOP separate on the same side of the package.

Abstract: A BGA type semiconductor device includes: a substrate having wirings and electrodes; a semiconductor element disposed on the substrate, having a rectangular plan shape, and a plurality of electrodes disposed along each side of the semiconductor element; a plurality of wires connecting the electrodes on the semiconductor element with the electrodes on the substrate; a heat dissipation member disposed on the substrate, covering the semiconductor element, and having openings formed in areas facing apex portions of the plurality of wires connected to the electrodes formed along each side of the semiconductor element; and a sealing resin member for covering and sealing the semiconductor element and heat dissipation member.

Abstract: Disclosed herein are a trench substrate and a method of manufacturing the same. The trench substrate includes a base substrate, an insulating layer formed on one side or both sides of the base substrate and including trenches formed in a circuit region and a dummy region positioned at a peripheral edge of the trench substrate, and a circuit layer formed in the trenches of the circuit region through a plating process and including a circuit pattern and vias. Thanks to formation of the trenches in the dummy region and the cutting region, deviation in thickness of a plating layer formed on the insulating layer in a plating process is improved upon.

Abstract: An assembly of microelectronic devices and method for forming an assembly of microelectronic devices. In one embodiment, the method includes positioning a first packaged microelectronic device adjacent to a support member having support member circuitry, with the first packaged microelectronic device having a first microelectronic die at least partially encased in a first encapsulant to define a first package configuration. The method can further include electrically connecting the first packaged microelectronic device to a first portion of the support member circuitry and positioning at least proximate to the first packaged microelectronic device a second packaged microelectronic device having a second microelectronic die at least partially encased in a second encapsulant to define a second package configuration different than the first package configuration. The first packaged microelectronic device can be positioned between the support member and the second packaged microelectronic device.

Abstract: A COF package having a tape substrate including external input terminals and external output terminals provided in a chip non-mounting area, input wirings connected to the external input terminals respectively, output wirings connected to the external output terminals respectively, internal input wirings which are provided from the chip non-mounting area to a chip mounting area and provided between the input wirings and which are connected to the external input terminals, respectively, and a dummy wiring provided from the chip non-mounting area to the chip mounting area and provided between the internal input wirings; and a semiconductor chip including input electrodes connected to the input wirings respectively, output electrodes connected to the output wirings respectively, internal input electrodes connected to the internal input wirings respectively, and a dummy electrode provided spaced from each input electrode along one side of the chip surface, and connected to the dummy wiring.

Abstract: An assembly includes a substrate, a chip mounted on the substrate, a voltage controlled oscillator circuit including an inductor and further circuit elements. The inductor is mounted on or in the substrate, and the further circuit elements are mounted on or in the chip. An assembly is disclosed that includes a substrate including a first metallization plane and a second metallization plane, a chip mounted on the substrate, and an inductor mounted on or in the substrate. The inductor includes a first inductor portion in the first metallization plane and a second inductor portion in the second metallization plane. An assembly is also disclosed including a substrate, a chip mounted onto the substrate, and a transformer formed at least in part on or in the substrate.

Abstract: A semiconductor package with isolated inner lead(s) is revealed. A chip is disposed on a leadframe segment and encapsulated by an encapsulant. The leadframe segment includes a plurality of leads, an isolated lead, and an external lead where each lead has an internal portion and an external portion. The isolated inner lead is completely formed inside the encapsulant and the external lead is partially formed inside and extended outside the encapsulant. At least one of the internal portions of the leads is located between the isolated inner lead and the external lead. Two fingers are formed at two opposing ends of the isolated inner lead without covering by the chip. One of the fingers imitates a plurality of fingers of the leads to arrange along a first side of the chip. The other finger of the isolated inner lead and a finger of the external lead are arranged along a second side of the chip.

Abstract: A printed circuit board includes a core layer, an insulation layer formed on the core layer and having a cavity formed on a part of the insulation layer, and a circuit pattern formed on the insulation layer, wherein the circuit pattern comprises one or more external terminals positioned above the cavity.

Abstract: A chip package structure including a chip, a lead frame, first bonding wires and second bonding wires is provided. The chip has an active surface and chip bonding pads disposed thereon. The lead frame is fixed on the chip and the lead frame includes inner leads, at least one bus bar, an insulating layer and transfer bonding pads. The bus bar is located between the chip bonding pads and the inner leads. The insulating layer is disposed on the bus bar and the transfer bonding pads are disposed thereon. The inner leads and the bus bar are located above the active surface. The chip and the insulating layer are located respectively on two opposite surfaces of the bus bar. The first bonding wires respectively connect the chip bonding pads and the transfer bonding pads. The second bonding wires respectively connect the transfer bonding pads and the inner leads.

Abstract: A semiconductor package with a semiconductor chip having under bump metallizations (UBMs) on a first surface and a substrate having open vias. The substrate is attached to the semiconductor chip with the UBMs in alignment with the open vias. An encapsulant surrounds the semiconductor chip and the substrate and a conductor fills the open vias to form external package connections.

Abstract: A control device has a base plate, a cover plate coupled to the base plate, a cavity formed between the base plate and the cover plate, a circuit carrier disposed in the cavity, and a conducting track carrier electrically coupled to the circuit carrier. The base plate has a continuous recess that is configured and arranged for feeding a casting compound into the cavity between the base plate and the cover plate. The casting compound is embodied to at least partly enclose the circuit carrier and/or the conducting track carrier in a vibration-damping manner.

Abstract: A semiconductor device is provided comprising: a semiconductor element including a plurality of electrodes; first wirings coupled to the electrodes and directed toward a center of the semiconductor element from a portion coupled to the electrodes; second wirings coupled between the first wirings and external terminals, the second wirings being directed to an outer area of the semiconductor element relative to the center; and at least one resin layer formed between the first wirings and the second wirings.

Abstract: According to one embodiment, a semiconductor memory device including an organic substrate with an external connection terminal and a semiconductor memory chip. The semiconductor memory device further includes a lead frame having a bonded portion and an installation portion. It further includes a resin mold for sealing the semiconductor memory chip. The lead frame is provided with a plurality of extensions at least from one of the installation portion and the bonded portion, in a way of extending at least to two or more sides of the resin mold.

Abstract: A packaging substrate structure with electronic components embedded therein and a method for fabricating the same are disclosed. The packaging substrate structure comprises a core board with a wiring layer on the two opposite surfaces thereof; a first built-up structure disposed on at least one surface of the core board and having a cavity to expose the surface of the core board; an electronic component disposed in the cavity and having an active surface and an inactive surface, where the active surface has pluralities of electrode pads and the inactive surface faces the surface of the core board; and a solder mask disposed on the surfaces of the first built-up structure and the electronic component, where the solder mask has pluralities of first openings to expose the electrode pads of the electronic component. Accordingly, the packaging substrate disclosed by the present invention can efficiently enhance electrical performance and product reliability.

Abstract: A chip on film (COF) structure includes a flexible circuit board and a chip. The flexible circuit board includes a flexible base film and a conductive layer. The flexible base film has a polyimide layer and an anisotropic conductive layer (ACL). The conductive layer is disposed on the flexible base film. The conductive layer and the ACL are separated by the polyimide layer. The chip is mounted with the conductive layer via interconnectors.

Abstract: A heat dissipating wiring board includes a metal wiring plate with a circuit pattern formed therein, a filler containing resin layer embedded with the metal wiring plate such that a top surface of the metal wiring plate is exposed, and a heat dissipating plate arranged on an under surface of the filler containing resin layer. The circuit pattern is formed of a through groove provided in the metal wiring plate. The through groove includes a fine groove that opens at the top surface of the metal wiring plate and an expanded groove that expands from a lower end of the fine groove toward the under surface of the metal wiring plate. The heat dissipating wiring board is capable of improving reliability against electric insulation due to dust or the like in a space of the through groove.

Abstract: According to one embodiment, a semiconductor storage device includes an organic board provided with external connection terminals on one surface and formed as an individual piece into a plane shape substantially identical to that of an area where the external connection terminals are provided, a lead frame having a mounting area positioned relative to the organic board, and a semiconductor memory chip bonded to the mounting area.

Abstract: Provided is an adhesive tape which adheres two members to each other and decreases problems that may occur due to contraction and expansion of the adhered members when the temperature of the adhered two members changes. The adhesive tape includes: a base film having insulating properties; and an adhesive agent that adheres on both sides of the base film, wherein a coefficient of thermal expansion of the base film is 10 ppm or lower, a coefficient of thermal expansion of the adhesive tape is lower than 17 ppm, and an occupation rate of the base film in the adhesive tape exceeds 50%.

Abstract: A carrier with embedded components comprises a substrate and at least one embedded component. The substrate has at least one slot and a first composite layer. The embedded component is disposed at the slot of the substrate. The first composite layer has a degassing structure, at least one first through hole and at least one first fastener, wherein the degassing structure corresponds to the slot, the first through hole exposes the embedded component, and the first fastener is formed at the first through hole and contacts the embedded component. According to the present invention, the degassing structure can smoothly discharge the hydrosphere existing within the carrier under high temperature circumstances and the first fastener is in contact with the embedded component, which increases the joint strength between the embedded component and the substrate.

Abstract: A semiconductor component includes a semiconductor element that has a plurality of signals, a wiring board that is disposed below the semiconductor element and that draws the plurality of signals of the semiconductor element, a heat conduction member that dissipates heat generated by the semiconductor element, a joining member that is disposed between the semiconductor element and the heat conduction member and that joins the heat conduction member to the semiconductor element, a support member formed with an opening so as to surround the semiconductor element that supports the heat conduction member, a first adhesive member that is disposed between the support member and the wiring board to bond the support member with the wiring board and a second adhesive member that is disposed between the support member and the heat conduction member to bond the support member with the heat conduction member.

Abstract: A flexible base includes a main region configured for forming flexible printed circuit board units; and two conveying regions respectively arranged on two sides of the main region. Each of the conveying regions includes an insulating substrate, a plurality of sprocket holes, and a patterned supporting layer. The sprocket holes are defined along a lengthwise direction of the insulating substrate. The patterned supporting layer is formed on the insulating substrate. The patterned supporting layer extends from an edge of each sprocket hole towards a periphery region of the corresponding sprocket.

Abstract: A resin layer made of thermoplastic resin is formed on a supporting substrate, and then, an insulating layer is formed on the first resin layer. Then, an interlayer connector is formed through the insulating layer and then, a wiring layer is formed on the first resin layer so as to be electrically connected with the interlayer connector. Thereafter, a first semiconductor chip is mounted on the wiring layer. Then, the first resin layer is heated so that the supporting substrate and the insulating layer are relatively shifted one another to shear the first resin layer, thereby separating the supporting substrate and the insulating layer and forming a semiconductor device.

Abstract: The present invention provides an electronic assembly 400 and a method for its manufacture 800, 900, 1000 1200, 1400, 1500, 1600, 1700. The assembly 400 uses no solder. Components 406, or component packages 402, 802, 804, 806 with I/O leads 412 are placed 800 onto a planar substrate 808. The assembly is encapsulated 900 with electrically insulating material 908 with vias 420, 1002 formed or drilled 1000 through the substrate 808 to the components' leads 412. Then the assembly is plated 1200 and the encapsulation and drilling process 1500 repeated to build up desired layers 422, 1502, 1702. Assemblies may be mated 1800. Within the mated assemblies, items may be inserted including pins 2202a, 2202b, and 2202c, mezzanine interconnection devices 2204, heat spreaders 2402, and combination heat spreaders and heat sinks 2602. Edge card connectors 2802 may be attached to the mated assemblies.