Abstract: The present disclosure relates to a method and apparatus for fabricating an LED signboard, through which an LED signboard is fabricated by printing a circuit pattern with a conductive ink. The method includes generating a design, forming a circuit pattern by printing a conductive ink on an insulation matrix based on the design via a printer, and mounting an LED on the circuit pattern.

Abstract: A semiconductor package system is provided including: providing a substrate having substrate wiring and a cavity provided therein with a heat sink foil closing off the cavity; attaching a semiconductor die in the cavity to the heat sink foil; and bonding the semiconductor die to the substrate wiring.

Abstract: An object is to provide an electronic device of a multilayer structure with high density and high reliability that can be reduced in size while incorporating an electronic component therein, and further provide a production method for easily producing such an electronic device. An electronic device of the present invention includes wiring layers and electrically insulating layers stacked on a core board and establishes predetermined electrical conduction between the wiring layers through upper-lower side conducting vias provided in the electrically insulating layers.

Abstract: Methods for fabricating flip-chips are disclosed. In an exemplary method, a flip-chip is mounted, active-surface downward, onto a substrate such that a back-side of the flip-chip is facing upward and electrical connections are made between the chip and an upward-facing surface of the substrate. An adhesive is applied to selected regions not occupied by the flip-chip. A heat-spreader is applied to contact the applied adhesive without contacting the back-side of the flip-chip, leaving a gap between the heat-spreader and the back-side of the flip-chip. The heat-spreader defines at least one through-hole that, when the heat-spreader is placed, is within a perimeter of the flip-chip. The adhesive is cured, and a thermal-insulating material (TIM) is applied through the at least one through-hole so as to fill the gap with the TIM. The methods substantially reduce the probability of die damage that otherwise occurs during attachment of heat-spreaders.

Abstract: A method of implementing a discrete component in an integrated circuit package is described. The method includes steps of coupling the discrete component to a surface of a substrate of the integrated circuit package, coupling an integrated circuit die to the surface of the substrate, applying a first epoxy material, and applying a second epoxy material to the discrete component, where the first epoxy material is different from the second epoxy material.

Abstract: An integrated circuit package system is provided including attaching an external interconnect on a tape; attaching a backside element on the tape adjacent to the external interconnect; attaching an integrated circuit die with the backside element, the backside element is on a first passive side of the integrated circuit die; connecting a first active side of the integrated circuit die and the external interconnect; and forming a first encapsulation over the integrated circuit die with the backside element exposed.

Abstract: A method of treating a component can include providing a component including a plurality of metallic posts extending generally parallel to one another. The providing step can be performed so that the posts have solder on the tips of the posts but not covering other portions of the posts. The method can include reflowing the solder provided on the posts so that the solder coats the posts. The providing step may be performed so that, prior to the reflowing step, the solder covers only the tips of the posts. The providing step can include depositing portions of the solder on a surface of a metallic sheet and etching the sheet from the surface. The plurality of posts may comprise elongated posts.

Abstract: A method of manufacturing a semiconductor device includes preparing two package substrates, electrically coupling a semiconductor wafer to a measuring apparatus, inspecting the wafer, dicing the semiconductor wafer into semiconductor elements and packaging the semiconductor element over the prepared package substrates.

Abstract: The present invention provides a printed circuit board capable of sufficiently ensuring joint strength and joint reliability when mounting a surface mounted device, and a mounting structure for a surface mounted device using the printed circuit board. A BGA package as a surface mounted device includes a plurality of solder balls arranged thereon and a printed circuit board includes a plurality of mounting pads corresponding respectively to the plurality of solder balls. The BGA package is connected to the mounting pads on the printed circuit board due to melting of the solder balls, thereby mounted on the printed circuit board. A concave via hole is formed on each of the mounting pads having a circular surface shape and a part of the solder ball is in the convex via hole. Here, the center of the convex via hole is apart from the center of each of the mounting pads by at least the diameter of the concave via hole.

Abstract: An environment-resistant module which provides both thermal and vibration isolation for a packaged micromachined or MEMS device is disclosed. A microplatform and a support structure for the microplatform provide the thermal and vibration isolation. The package is both hermetic and vacuum compatible and provides vertical feedthroughs for signal transfer. A micromachined or MEMS device transfer method is also disclosed that can handle a wide variety of individual micromachined or MEMS dies or wafers, in either a hybrid or integrated fashion. The module simultaneously provides both thermal and vibration isolation for the MEMS device using the microplatform and the support structure which may be fabricated from a thin glass wafer that is patterned to create crab-leg shaped suspension tethers or beams.

Abstract: A chip package includes: a substrate; a plurality of conductive connections in contact with the silicon carrier; a silicon carrier in a prefabricated shape disposed above the substrate, the silicon carrier including: a plurality of through silicon vias for providing interconnections through the silicon carrier to the chip; liquid microchannels for cooling; a liquid coolant flowing through the microchannels; and an interconnect to one or more chips or chip stacks.

Abstract: A semiconductor device includes a semiconductor element provided over a wiring board; sealing resin configured to seal the semiconductor element; and reinforcing resin provided at least at a part of a boundary part of the sealing resin and the wiring board. In the above-mentioned semiconductor device, the reinforcing resin may be provided along a perimeter of the boundary part of the sealing resin and the wiring board. The reinforcing resin may be provided at a boundary part of the sealing resin and the wiring board in a vicinity of a corner part of the sealing resin.

Abstract: A thermoelectric module includes a first substrate, a second substrate having a second surface which is apart from and faces a first surface of the first substrate, a plurality of thermoelectric elements arranged on the first and the second surfaces, a plurality of electrodes on the first and second surfaces each electrically connected to at least one of the plurality of thermoelectric elements, and a ground electrode on at least the first surface. The plurality of electrodes on at least the first surface comprises a plurality of columns each of which comprises two or more electrodes aligned in a longitudinal direction, and the ground electrode is between two adjacent columns among the plurality of columns.

Abstract: A device mounting board includes an insulating layer formed of an insulating resin, a glass cloth covering the surface of the insulating layer, and an electrode provided in a through hole extending through the glass cloth. The angle of contact with solder of the glass cloth is larger than that of the resin. Thus, solder bumps are formed on the electrode 14 of the device mounting board 10 with high precision.

Abstract: A packaged microelectronic element includes a microelectronic element having a front surface and a plurality of first solid metal posts extending away from the front surface. A substrate has a major surface and a plurality of conductive elements exposed at the major surface and joined to the first solid metal posts. In particular examples, the conductive elements can be bond pads or can be second posts having top surfaces and edge surfaces extending at substantial angles away therefrom. Each first solid metal post includes a base region adjacent the microelectronic element and a tip region remote from the microelectronic element, the base region and tip region having respective concave circumferential surfaces. Each first solid metal post has a horizontal dimension which is a first function of vertical location in the base region and which is a second function of vertical location in the tip region.

Abstract: A method for fabricating an encapsulant cavity integrated circuit package system includes: providing an interposer; forming a first integrated circuit package with an inverted bottom terminal having an encapsulant cavity and the interposer; and attaching a component on the interposer in the encapsulant cavity.

Abstract: A method of manufacture of an integrated circuit packaging system includes: providing a through silicon via die having an interconnect through a silicon substrate; depositing a re-distribution layer on the through silicon via die and connected to the interconnects; mounting a structure over the through silicon via die; connecting the structure to the interconnect of the through silicon via die with a direct interconnect; and encapsulating the through silicon via die and partially encapsulating the structure with an encapsulation.

Abstract: A circuit board has an insulative layer including a first surface and a second surface opposite to the first surface. A plurality of electrically conductive patterns is formed on the first surface of the insulative layer. Conductive lands are formed in a die mounting region of the first surface of the insulative layer and electrically connected to one of the plurality of conductive patterns on the first surface. An extending pattern extends from the conductive lands to outside of the mounting region. A protective layer covers the first surface of the insulative layer and the electrically conductive patterns. A trench is formed in the protective layer to expose the conductive lands and the extending patterns.

Abstract: A method for providing access to a feature on a device wafer, and located outside an encapsulation region is described. The method includes forming a cavity in the lid wafer, aligning the lid wafer with the device wafer so that the cavity is located substantially above the feature, and removing material substantially uniformly from the bottom surface of the lid wafer, until an aperture is formed at the cavity, over the feature on the device wafer. By removing material from the lid wafer in a substantially uniform manner, difficulties with the prior art procedure of saw cutting, such as alignment and debris generation, are avoided.

Abstract: A method for forming circuit patterns on a surface of a substrate is provided and has steps of: providing and pre-heating a substrate having an insulation surface on one side thereof; providing an activation connection device for oscillating and painting an activation solder onto the pre-heated insulation surface to heat and melt the activation solder; applying ultrasonic waves to the melted activation solder by the activation connection device, so as to activate the activation solder and the insulation surface by the ultrasonic waves; and moving the activation connection device, so as to form a circuit pattern on the insulation surface by the activation solder.

Abstract: A circuitized substrate including a dielectric layer having a p-aramid paper impregnated with a halogen-free, low moisture absorptivity resin and not including continuous or semi-continuous fiberglass fibers as part thereof, and a first circuitized layer positioned on the dielectric layer. A method of making this substrate is also provided.

Abstract: A semiconductor device has a semiconductor die with a die bump pad and substrate with a trace line and integrated bump pad. Conductive bump material is deposited on the substrate bump pad or die bump pad. The semiconductor die is mounted over the substrate so that the bump material is disposed between the die bump pad and substrate bump pad. The bump material is reflowed without a solder mask around the die bump pad or substrate bump pad to form an interconnect. The bump material is self-confined within a footprint of the die bump pad or substrate bump pad. The bump material can be immersed in a flux solution prior to reflow to increase wettability. Alternatively, the interconnect includes a non-fusible base and fusible cap. The volume of bump material is selected so that a surface tension maintains self-confinement of the bump material within the bump pads during reflow.

Abstract: A wafer level package structure, in which a plurality of compact sensor devices with small variations in sensor characteristics are formed, and a method of producing the same are provided. This package structure has a semiconductor wafer having plural sensor units, and a package wafer bonded to the semiconductor wafer. The semiconductor wafer has a first metal layer formed with respect to each of the sensor units. The package wafer has a bonding metal layer at a position facing the first metal layer. Since a bonding portion between the semiconductor wafer and the package wafer is formed at room temperature by a direct bonding between activated surfaces of the first metal layer and the bonding metal layer, it is possible to prevent that variations in sensor characteristics occur due to residual stress at the bonding portion.

Abstract: One aspect of the invention includes a copper substrate; a catalyst on top of the copper substrate surface; and a thermal interface material that comprises a layer containing carbon nanotubes that contacts the catalyst. The carbon nanotubes are oriented substantially perpendicular to the surface of the copper substrate. A Raman spectrum of the layer containing carbon nanotubes has a D peak at ˜1350 cm?1 with an intensity ID, a G peak at ˜1585 cm?1 with an intensity IG, and an intensity ratio ID/IG of less than 0.7 at a laser excitation wavelength of 514 nm. The thermal interface material has: a bulk thermal resistance, a contact resistance at an interface between the thermal interface material and the copper substrate, and a contact resistance at an interface between the thermal interface material and a solid-state device. A summation of these resistances has a value of 0.06 cm2K/W or less.

Abstract: A back-side lamination (BSL) is applied after thinning a microelectronic die. The BSL is configured to be a thermal-expansion complementary structure to a metal wiring interconnect layout that is disposed on the active side of the microelectronic die.

Abstract: A semiconductor device includes: a wiring board including a first electrode pad on a surface thereof; a circuit board disposed to stand on the wiring board, and including an interconnection connected to the first electrode pad; and a semiconductor package disposed to face the wiring board with the circuit board interposed therebetween, and including a second electrode pad on a surface thereof, the second electrode pad being connected to the interconnection.

Abstract: A semiconductor chip includes a contact pad on a main surface of the chip. An electrically conductive layer is applied onto the contact pad. The main surface of the semiconductor chip is covered with an insulating layer. An electrically conductive contact area is formed within the insulating layer such that the contact area and the insulating layer include coplanar exposed surfaces and the contact area is electrically connected with the electrically conductive layer and includes an extension which is greater than the extension of the electrically conductive layer along a direction parallel to the main surface of the semiconductor chip.

Abstract: In this manufacturing method of a semiconductor device, a metal plate having a plurality of projection electrodes in each of a plurality of semiconductor device formation areas is prepared. Next, the projection electrodes of each of the semiconductor formation areas are aligned corresponding to external connection electrodes of each semiconductor construction, and each semiconductor construction is separately arranged on the projection electrodes in the semiconductor device formation areas. Next, an insulating layer formation sheet is arranged on the metal plate, and the metal plate and the insulating layer formation sheet are joined by heat pressing. Then, the metal plate is patterned and a plurality of upper layer wirings that connect to the projection electrodes is formed.

Abstract: A multilayer printed circuit board includes an interior interconnect layer, and a semiconductor package including a flexible interconnect structure whose distal end is a free end, wherein the flexible interconnect structure and the interior interconnect layer are electrically connected to each other.

Abstract: A backside mold configuration (BSMC) process for manufacturing packaged integrated circuits includes applying a mold compound to a side of a packaging substrate opposite an attached die. The mold compound is deposited on a dielectric (such as photo resist). The mold compound and dielectric are patterned after coupling a die to the packaging substrate to expose a contact pad of the packaging substrate. After patterning the mold compound and dielectric, a packaging connection is coupled to contact pads through the mold compound and dielectric. The mold compound surrounding the packaging connection reduces warpage of the packaging substrate during processing. Additionally, patterning the dielectric after attaching the die improves reliability of the packaging connection.

Abstract: A semiconductor device has a plurality of similar sized semiconductor die each with a plurality of bond pads formed over a surface of the semiconductor die. An insulating layer is formed around a periphery of each semiconductor die. A plurality of conductive THVs is formed through the insulating layer. A plurality of conductive traces is formed over the surface of the semiconductor die electrically connected between the bond pads and conductive THVs. The semiconductor die are stacked to electrically connect the conductive THVs between adjacent semiconductor die. The stacked semiconductor die are mounted within an integrated cavity of a substrate or leadframe structure. An encapsulant is deposited over the substrate or leadframe structure and the semiconductor die. A thermally conductive lid is formed over a surface of the substrate or leadframe structure. The stacked semiconductor die are attached to the thermally conductive lid.

Abstract: A method of fabricating a leadframe-based semiconductor package, and a semiconductor package formed thereby, are disclosed. In embodiments, a semiconductor die having die bond pads along two adjacent edges may be electrically coupled to four sides of a four-sided leadframe. Embodiments relate to lead and no-lead type leadframe.

Abstract: A method of fabricating a packaging structure includes cutting a panel of packaging substrate into a plurality of packaging substrate blocks each having a plurality of packaging substrate units; mounting and packaging a semiconductor chip on each of the packaging substrate unit to form package blocks each having multiple packaging structure units; and cutting package blocks to form a plurality of package units. In the method, the alignment difference between the packaging structure units in each package block is minimized by appropriately cutting and forming substrate blocks to achieve higher precision and better yield, and also packaging of semiconductor chips can be performed on all package units in the substrate blocks, thereby integrating fabrication with packaging at one time to improve production efficiency and reduce the overall costs as a result.

Abstract: Disclosed herein are a substrate for a semiconductor package and a manufacturing method thereof. The substrate for the semiconductor package, which has a single-sided substrate structure including circuit patterns having a connection pad formed on only an electronic component mounting surface, can directly connect a connection pad on the top of the substrate to external connection terminals on the bottom of the substrate through a connection via formed of a metal plating layer formed in an inner wall of the via hole and a conductive metal paste filled in the via hole.

Abstract: A wiring substrate is provided, including an insulating resin layer which is provided on both surfaces of a sheet-like fibrous body and with which the sheet-like fibrous body is impregnated, and a through wiring provided in a region surrounded by the insulating resin layer. The through wiring is formed using a conductive material, the conductive material is exposed on both surfaces of the insulating resin layer, the sheet-like fibrous body is positioned in the conductive material, and the sheet-like fibrous body is impregnated with the conductive material. A manufacturing method of the wiring substrate is also provided.

Abstract: An electronic device includes a substrate provided with a passing opening and a MEMS device including an active surface wherein a portion of the MEMS device is integrated sensitive to chemical/physical variations of a fluid. The active surface of the MEMS device faces the substrate and is spaced therefrom, the sensitive portion being aligned to the opening. A protective package incorporates at least partially the MEMS device and the substrate, leaving at least the sensitive portion of the MEMS device, and the opening of the substrate exposed. A barrier element is positioned in an area which surrounds the sensitive portion to realize a protection structure for the MEMS device, so that the sensitive portion is free.

Abstract: A semiconductor memory module having a reverse mounted chip resistor, and a method of fabricating the same are provided. By reverse mounting the chip resistor on the semiconductor memory module, the resistive material is protected, thereby preventing open circuits caused by damage to the resistive material. Also, a chip-resistor connection pad of a module substrate is formed to extend higher from the module substrate than other connection pads connected to other elements. Thus, the resistive material of the chip resistor does not contact the module substrate, thereby preventing poor alignment and defective connections.

Abstract: A semiconductor method comprises a method for making a device comprising: a base; a semiconductor chip provided on the base which includes a first main surface 20a on which a plurality of electrode pads is provided, a surface protecting film provided on the first main surface, a second main surface which opposes the first main surface, and a plurality of side surfaces between the surface of the surface protecting film and the second main surface; an insulating extension portion formed so as to surround the side surfaces of the semiconductor chip; a plurality of wiring patterns electrically connected to the electrode pads, respectively and extended from the electrode pads to the surface of the extension portion; a sealing portion formed on the wiring patterns such that a part of each of the wiring patterns is exposed; and a plurality of external terminals provided on the wiring patterns in a region including the upper side of the extension portion.

Abstract: Heat sink structures employing carbon nanotube or nanowire arrays to reduce the thermal interface resistance between an integrated circuit chip and the heat sink are disclosed. Carbon nanotube arrays are combined with a thermally conductive metal filler disposed between the nanotubes. This structure produces a thermal interface with high axial and lateral thermal conductivities.

Abstract: A mounted body (100) of the present invention includes: a semiconductor element (10) having a surface (10a) on which element electrodes (12) are formed and a rear surface (10b) opposing the surface (10a); and a mounting board (30) on which wiring patterns (35) each having an electrode terminal (32) are formed. The rear surface (10b) of the semiconductor element (10) is in contact with the mounting board (30), and the element electrodes (12) of the semiconductor element (10) are connected electrically to the electrode terminals (32) of the wiring pattern (35) formed on the mounting board (30) via solder connectors (20) formed of solder particles assembled into a bridge shape. With this configuration, fine pitch connection between the element electrodes of the semiconductor element and the electrode terminals of the mounting board becomes possible.

Abstract: A method of laying out traces for connection of bond pads of a semiconductor chip to a printed wiring board or the like and the layout. There is provided a substrate having top and bottom surfaces with a plurality of rows and columns of vias extending therethrough from the top surface to the bottom surface and having a solder ball secured at the bottom surface to each via. A plurality of pairs of traces is provided on the top surface, each trace of each pair of traces extending to a different one of the vias and extending to vias on a plurality of the rows and columns, each of the traces of each pair being spaced from the other trace by a ball pitch, being maximized for identity in length and being maximized for parallelism and spacing. Each of the traces of a pair is preferably be further maximized for identity in cross-sectional geometry. A differential signal pair is preferably applied to at least one of a pair of traces.

Abstract: A leadframe having a die thereon connects a high current conductive area on the die to a leadframe contact using a copper clip that include a structural portion that is received within a recess-like “tub” that is formed in the leadframe contact which tub is shaped to conform to the geometric shape of the clip. In the preferred embodiment, a leadframe structure fabricated by etching includes at least one contact that is a halfetch recess or “tub” that receives one end of the clip structure and is retained in the tub by an adhesive. The end of the clip that is received in the tub is held in place during subsequent handling until the clip and leadframe undergo solder reflow to effect an electrical connection sufficient to handle the current load and also effect a reliable mechanical connection.

Abstract: A method for producing a multi-layer thick-film RF package includes forming conductive layer(s) including one or more source portions, one or more gate portions, and/or one or more drain portions on a ceramic substrate. The conductive layer(s) and the ceramic substrate are fired or otherwise heated in a furnace until sintered. Thereafter, a dielectric pattern is formed on the conductive layer(s) and fired or otherwise heated in the furnace until sintered. Then, a conductive bridge is formed on the dielectric pattern, over the one or more drain portions and between the one or more source portions, which is then fired until sintered in the furnace. As a result, a monolithic, single-piece, sintered, high-frequency RF power transistor package having circuit features including a highly conductive and low capacitive bridge is produced.

Abstract: Various semiconductor chip thermal interface material methods and apparatus are disclosed. In one aspect, a method of establishing thermal contact between a first semiconductor chip and a heat spreader is provided. The method includes placing a thermal interface material layer containing a support structure on the first semiconductor chip. The heat spreader is positioned proximate the thermal interface material layer. The thermal interface material layer is reflowed to establish thermal contact with both the first semiconductor chip and the heat spreader.

Abstract: A microelectronic package includes a first substrate (120) having a first surface area (125) and a second substrate (130) having a second surface area (135). The first substrate includes a first set of interconnects (126) having a first pitch (127) at a first surface (121) and a second set of interconnects (128) having a second pitch (129) at a second surface (222). The second substrate is coupled to the first substrate using the second set of interconnects and includes a third set of interconnects (236) having a third pitch (237) and internal electrically conductive layers (233, 234) connected to each other with a microvia (240). The first pitch is smaller than the second pitch, the second pitch is smaller than the third pitch, and the first surface area is smaller than the second surface area.

Abstract: A chip package structure and a method of manufacturing the same are provided. The chip package structure includes a package portion and a plurality of external conductors. The package portion includes a distribution layer, a chip, a plurality internal conductors and a sealant. The distribution layer has a first surface and a second surface, and the chip is disposed on the first surface. Each internal conductor has a first terminal and a second terminal. The first terminal is disposed on the first surface. The sealant is disposed on the first surface for covering the chip and partly encapsulating the internal conductors, so that the first terminal and the second terminal of each internal conductor are exposed from the sealant. The external conductors disposed on the second surface of the distribution layer of the package portion are electrically connected to the internal conductors.

Abstract: Methods of forming a microelectronic packaging structure and associated structures formed thereby are described. Those methods may include forming a cavity in a carrier material, attaching a die in the cavity, wherein a backside of the die comprises a metal filled DBF, forming a dielectric material adjacent the die and on a bottom side of the carrier material, forming a coreless substrate by building up layers on the dielectric material, and removing the carrier material from the coreless substrate.

Abstract: A semiconductor device with a first (101) and a second (111) semiconductor chip assembled on an insulating flexible interposer (120). The interposer, preferably about 25 to 50 ?m thick, has conductive traces (121), a central planar rectangular area and on each side of the rectangle a wing bent at an angle from the central plane. The central area has metal studs (122, 123) on the top and the bottom surface, which match the terminals of the chips, further conductive vias of a pitch center-to-center about 50 ?m or less. The side wings have contact pads (130) with metallic connectors (131) on the bottom surface; the connectors may be solder balls, metal studs, or anisotropic conductive films. The second chip is adhesively attached to a substrate, whereby the interposer faces away from the substrate. The interposer side wings have a convex bending (150) downwardly along the second chip and a concave bending (151) over the substrate; the side wing connectors are attached to the matching substrate sites.

Abstract: A heat conductive plate structure includes a base metal plate having a seating portion; a coupling layer disposed above the base metal plate around the seating portion; an electric conduction layer disposed above the coupling layer around the seating portion to define a clearance therebetween; a coupling film disposed above the electric conduction layer and the seating portion to define an inner clearance in communication with the clearance of the electric conduction layer and an outer clearance surrounding the inner clearance; a non-weldable material for inserting into the inner clearance and the outer clearance in the coupling film; a heat conduction member disposed on a central portion of the coupling film; an electric conduction member disposed above the coupling film to surround the heat conduction member from an exterior thereof; and a high power element mounted above so as to be in direct contact with the heat conduction member and the electric conduction member simultaneously.

Abstract: A semiconductor device is made by disposing a plurality of semiconductor die on a carrier and creating a gap between each of the semiconductor die. A first insulating material is deposited in the gap. A portion of the first insulating material is removed. A conductive layer is formed over the semiconductor die. A conductive lining is conformally formed on the remaining portion of the first insulating material to form conductive via within the gap. The conductive vias can be tapered or vertical. The conductive via is electrically connected to a contact pad on the semiconductor die. A second insulating material is deposited in the gap over the conductive lining. A portion of the conductive via may extend outside the first and second insulating materials. The semiconductor die are singulated through the gap. The semiconductor die can be stacked and interconnected through the conductive vias.