Abstract: An apparatus includes a plurality of interconnect structures over a substrate, a dielectric layer formed over a top metal line of the plurality of interconnect structures, a first barrier layer on a bottom and sidewalls of an opening in the dielectric layer, wherein the first barrier layer is formed of a first material and has a first thickness, a second barrier layer over the first barrier layer, wherein the second barrier layer is formed of a second material different from the first material and has a second thickness and a pad over the second barrier layer, wherein the pad is formed of a third material.

Abstract: Methods for forming interconnects in microfeature workpieces, and microfeature workpieces having such interconnects are disclosed herein. The microfeature workpieces may have a terminal and a substrate with a first side carrying the terminal and a second side opposite the first side. In one embodiment, a method includes (a) constructing an electrically conductive interconnect extending from the terminal to at least an intermediate depth in the substrate with the interconnect electrically connected to the terminal, and (b) removing material from the second side of the substrate so that a portion of the interconnect projects from the substrate.

Abstract: An integrated circuit packaging is described and includes a plurality of electrical circuits developed using a first patterned conductive layer on a base, wherein the electrical circuit is formed by using a masking material, and a stud conductive layer disposed on at least one side of the first patterned conductive layer developed by a second layer photo-resist material on the masking material, in which the second layer photo-resist material includes a first line layer with a smaller exposed area than the surface of the conductive layer disposed on one side of the first patterned conductive layer and a second line layer with a larger exposed area than the first line layer disposed on the first layer, such that the exposed area forms an “I” shaped connection of the conductive layer and the stud conductive layer.

Abstract: An integrated circuit package and manufacturing method thereof are described. The integrated circuit package includes pin up conductive plating to form an interconnect, where an opening on a patterned fifth layer photo-resist material located at bottom portion of a base developed for etching selectively the base to form at least an internal opening and at least a positioning opening, wherein the internal opening corresponds with an inside area of a first patterned conductive layer, and the positioning opening corresponds with an outside area of the first patterned conductive layer.

Abstract: A method for fabricating a semiconductor device includes forming first gate stacks on a first region of a substrate to be spaced apart by a first distance, forming second gate stacks on a second region of the substrate to be spaced apart by a second distance greater than the first distance, forming a first blocking film along the first gate stacks and the substrate, a thickness of the first blocking film between the first gate stacks being a first thickness, forming a second blocking film along the second gate stacks and the substrate, a thickness of the second blocking film between the second gate stacks being a second thickness different from the first thickness, and removing the first blocking film, the second blocking film, and the substrate to form a first recess between the first gate stacks and a second recess between the second gate stacks.

Abstract: The present disclosure relates to a method of forming an integrated chip having middle-of-the-line (MOL) structures arranged at an irregular pitch, and an associated method of formation. In some embodiments, the integrated chip has a well region with a plurality of source/drain regions. A plurality of gate structures are arranged over the well region at a regular pitch. A plurality of middle-of-the-line (MOL) structures are laterally interleaved between some of the plurality of gate structures and are arranged over the well region at an irregular pitch having a first pitch that is larger than the regular pitch. Since the MOL structures have an irregular pitch with a first pitch that is larger than the regular pitch, one or more of the plurality of gate structures are spaced apart from a closest gate or MOL structure by a space that reduces parasitic capacitance.

Abstract: Semiconductor structures and methods of forming such structures are disclosed. In an embodiment, the semiconductor structure comprises a substrate, a dielectric layer, and a plurality of gates, including a first gate and a pair of adjacent gates. The method comprises forming gate caps on the adjacent gates, including etching portions of the gate electrodes in the adjacent gates to recess the gate electrodes therein, and forming the caps above the recessed gate electrodes. Conductive metal trenches are formed in the dielectric layer, on the sides of the first gate; and after forming the trenches, a contact is formed over the gate electrode of the first gate and over and on one of the conductive trenches. In embodiments, the contact is a gate contact, and in other embodiments, the contact is a non-gate contact.

Abstract: One or more embodiments are directed to semiconductor packages that include conductive test pads that are electrically coupled to, but distinct from, the leads of the package. In one embodiment the test pads are located on the plastic packaging material, such as encapsulation material, of the package and are electrically coupled to the leads of the package by traces. The traces may also be located on the packaging material and portions of the leads. In one embodiment, all of the test pads are located on a single surface of the packaging material of the package, which may allow for ease of electrical testing of the package.

Abstract: A die edge crack and delamination detection device includes a semiconductor device including an IC active area surrounded by at least one mechanical protection barrier (MPB); one or more metallization layers stacked on the IC active area; a plurality of passive electronic devices placed within the metallization layers at respective predetermined distances from the MPB; and a detection circuit having circuitry. The circuitry is configured to determine a specific metallization layer in which a crack or a delamination is encroaching from an edge of the semiconductor device, determine a lateral distance of a lead end of the crack or the delamination from the MPB, and determine a rate of approach of the crack or the delamination encroaching towards the MPB, via a nominal change in an electrical measurement of at least one of the passive electronic devices.

Abstract: An electronic component containing package includes a substrate including a placement region for placing an electronic component in an upper face thereof; a frame disposed on the upper face of the substrate surrounding the placement region, and including a penetration part opening; and an input/output member disposed in the frame closing the penetration part, including a plurality of wiring conductors which extend inward and outward of the frame and are electrically connected to the electronic component. The input/output member includes via conductors which are connected to the wiring conductors and embedded at sites overlapping with the wiring conductors within a region surrounded by the frame in the input/output member, and a ground layer disposed in a surrounding of lower ends of the via conductors being spaced from the via conductors. Improved high frequency characteristics can be achieved.

Abstract: An air cavity package includes a dielectric frame that is formed from an alumina ceramic, a polyimide, or a semi-crystalline thermoplastic. The dielectric frame is joined to a flange using a high temperature silicone adhesive. Leads may be bonded to the dielectric frame using a high temperature organic adhesive, a direct bond, or by brazing.

Abstract: An electronic circuit module includes a circuit board, electronic components, an embedding layer, and a conductive film. The circuit board has a first principal surface, a second principal surface and a side surface, and includes a pattern conductor and a via conductor. The conductive film is connected to a conduction path to a ground electrode. The side surface includes a first region, a second region having a longer circumferential length than the first region, and a connection region connecting the first region and the second regions. The conductive film is formed on a region including at least part of each of an outer surface of the embedding layer, the first region, and the connection region. The conductive film formed on at least part of the connection region is connected to an exposed portion in the connection region of the via conductor included in the conduction path to the ground electrode.

Abstract: A molded package includes an IC chip mounted on a first surface of a lead frame, and a molded resin encapsulating the lead frame together with the IC chip. The molded resin has a second surface-side opening portion that is formed to expose a chip correspondence portion of a second surface of the lead frame corresponding to the IC chip. A filler material is filled in the second surface-side opening portion. The filler material has a thermal conductivity equal to or greater than that of the molded resin and is softer than the molded resin. The chip correspondence portion has a rough surface with fine splits so as to increase a contact area with the filler material, and the filler material is in contact with the external member.

Abstract: A method includes forming a polymer layer covering a metal via in a wafer, grooving the wafer to form a trench, wherein the trench extends from a top surface of the polymer layer into the wafer, and performing a die-saw on the wafer to separate the wafer into a plurality of device dies. A kerf passes through the trench. One of the device dies is placed over a carrier. An encapsulating material is dispensed over and around the device die. The method further includes pressing and curing the encapsulating material. After the encapsulating material is cured, a sidewall of the polymer layer is tilted. A planarization is performed on the encapsulating material until the polymer layer and the metal via are exposed. A redistribution line is formed over and electrically coupled to the metal via.

Abstract: An electronic device includes a supporting substrate having a front mounting face and an electrical connection network. An integrated circuit chip is mounted to the mounting face and is electrically connected to the electrical connection network. A primary encapsulation block embeds the integrated circuit chip and extends above and around the integrated circuit chip on the mounting face of the supporting substrate. An opening is provided in the primary encapsulation block to at least partially uncover an electrical contact. An additional wire made from an electrically conductive material has an end that is electrically connected to the electrical contact. An additional encapsulation block above the primary encapsulation block embeds the additional wire.

Abstract: Provided is a bonded substrate mainly for mounting a power semiconductor in which the reliability to a thermal cycle has been enhanced as compared with a conventional one. In a bonded substrate in which a copper plate is bonded to one or both main surface(s) of a nitride ceramic substrate, a bonding layer consisting of TiN intervenes between the nitride ceramic substrate and the copper plate and is adjacent at least to the copper plate, and an Ag distribution region in which Ag atoms are distributed is set to be present in the copper plate. Preferably, an Ag-rich phase is set to be present discretely at an interface between the bonding layer and the copper plate.

Abstract: A three-dimensional integrated circuit includes two or more stacks of one or more active layers; a gas-cooling layer separating the two or more stacks and a wireless interconnect between the two or more stacks enabling communication between the two or more stacks and system including a gas-cooled three-dimensional integrated circuit having wireless data interconnects is disclosed.

Abstract: A mechanically-stable and thermally-conductive interface device between a semiconductor die and a package for the die, and related method of fabrication, comprising: a semiconductor die; a package for the die; a surface area-enhancing pattern on the package and/or the die; and die attach materials between the die and the package, the die attach materials attaching the die to the package through an interface provided by the die attach materials; wherein: an effective bonding area between the die attach materials and the package and/or the die is greater with the pattern than without the pattern; and the increase of the effective bonding area simultaneously increases the surface area for thermal transport between the package and/or the die, and the die attach materials; and increases the surface area for stably attaching the at least one of the package and the die to the die attach materials.

Abstract: The disclosed embodiments of electronic packages include electrical contact pad features present on all sides of the package that facilitate simple and low cost electrical connections to the package made through a mechanical contacting scheme. In an embodiment, an electronic package comprises: a metal leadframe having a first leadframe portion having a first thickness and a second leadframe portion having a second thickness that is less than the first thickness, the second leadframe portion defining electrical contact pads; a silicon die attached to the second leadframe portion and overlying a space formed in the leadframe by the first and second leadframe portions; and wirebonds coupling the silicon die to the electrical contact pads. A method of fabricating the electronic package is also disclosed.

Abstract: Electronic power device comprising: an active layer comprising several lateral and/or semi-lateral components for which the electrodes are located on a front face of the active layer; an interconnection structure comprising several conducting portions to which component electrodes are connected, and located in contact with these electrodes extending parallel to the active layer; a support comprising a front face on which electrically conducting tracks are located, and in which: the interconnection structure is located between the active layer and the support, the conducting portions being placed in contact with the conducting tracks, or the active layer is placed between the interconnection structure and the support, the conducting portions comprising parts extending next to the active layer and connected to the conducting tracks.

Abstract: A double-facing cooling-type power module has coolers on both sides. The power module includes: a first switch having the coolers on both sides; a second switch disposed independently from the first switch and having the coolers on both sides; and a common electrode coupled to both the first switch and the second switch.

Abstract: In an SOP1 having a semiconductor chip and another semiconductor chip, in wire coupling between the chips, a withstand voltage can be secured by setting an inter-wire distance between a wire in a first wire group that is closest to a second wire group and a wire in the second wire group that is closest to the first wire group to be larger than an inter-wire distance between any wires in the first wire group and the second wire group, which makes it possible to attain improvement of reliability of the SOP1.

Abstract: Disclosed is an adapter panel and a method of manufacturing the same comprising a panel body having a first surface and an opposing second surface, wherein a through-hole in a frustrum shape is formed through the panel body and filled by a conical electrical conductor between the first and second surface. The conical electrical conductor has a plane end flush with the first surface and a tip end protruding from the second surface. The panel body further comprises a wiring structure on the first surface electrically connected to the plane end of the conical electrical conductor. Bonding to a dielectric plate can be achieved by directly inserting the tip end of the conical electrical conductor into a solder ball.

Abstract: A semiconductor device includes a substrate, a plurality of first conductive patterns disposed on the substrate and a plurality of second conductive patterns disposed on the first conductive patterns. Respective air gaps are disposed between adjacent ones of the first conductive patterns overlying a first region of the substrate, while adjacent ones of the first conductive patterns overlying a second region of the substrate do not have air gaps disposed therebetween. The air gaps may include first air gaps, and the device may further include second air gaps disposed between adjacent ones of the second conductive patterns in the second region. Adjacent ones of the second conductive patterns overlying a second region of the substrate may not have air gaps disposed therebetween.

Abstract: A multilayer electrical component is disclosed, wherein the multilayer electrical component comprises: a plurality of magnetic layers stacked over one another, wherein each magnetic layer is made of a first magnetic material, and wherein for each magnetic layer, a trench is formed in the magnetic layer, the bottom surface of the trench being located higher than the bottom surface of the magnetic layer; a second material that is different from the first material is disposed in the trench in the magnetic layer; and a conductive layer is disposed over the trench for forming a conductive element of the electrical component.

Abstract: A method for fabricating semiconductor device is disclosed. The method includes the steps of: providing a substrate; forming a gate structure on the substrate; forming an epitaxial layer adjacent to the gate structure; forming an interlayer dielectric (ILD) layer on the gate structure; forming a first contact hole in the ILD layer adjacent to the gate structure; and forming a cap layer in the recess, in which a top surface of the cap layer is even with or lower than a top surface of the substrate.

Abstract: An integrated fan-out package including an integrated circuit, an insulating encapsulation, and a redistribution circuit structure is provided. The integrated circuit includes an active surface, a plurality of sidewalls connected to the active surface, and a plurality of pads distributed on the active surface. The insulating encapsulation encapsulates the active surface and the sidewalls of the integrated circuit. The insulating encapsulation includes a plurality of first contact openings and a plurality of through holes, and the pads are exposed by the first contact openings. The redistribution circuit structure includes a redistribution conductive layer, wherein the redistribution conductive layer is disposed on the insulating encapsulation and is distributed in the first contact openings and the through holes. The redistribution conductive layer is electrically connected to the pads through the first contact openings. A method of fabricating the integrated fan-out package is also provided.

Abstract: A method of manufacturing an integrated circuit includes the following steps. A substrate including a plurality of exposure fields is provided, and each of the exposure fields includes a target portion and a set of overlay marks. The substrate is exposed to form a first layer lithography pattern on the target portion for the respective exposure field by an exposure system. The overlay of the first layer lithography pattern and the target portion is measured by the set of overlay marks of each exposure field to obtain first overlay data for the respective exposure field by a measuring system. The first overlay data is fed to form a second layer lithography pattern.

Abstract: Structures that include an identification marking and fabrication methods for such structures. A chip is formed within a usable area of a wafer, and a marking region is formed on the wafer. The marking region is comprised of a conductor used to form a last metal layer of an interconnect structure for the chip. The identification marking is formed in the conductor of the marking region. After the identification marking is formed, a dielectric layer is deposited on the marking region. The dielectric layer on the marking region is planarized.

Abstract: A method for suppressing material warpage by means of a pressure difference comprises the following steps: a. preparing a plurality of carrier boards; b. preparing a plurality of carrier board pressing devices having an upper surface and a lower surface on which at least one air bag is provided; c. adjusting the processing chamber to be a working temperature and a working pressure, so that the carrier boards and the carrier board pressing devices placed therein are surrounded by the working temperature and the working pressure; d. effectively suppressing warpage of the carrier board by using a pressure difference between a first predetermined pressure in the air bag and the working pressure of the processing chamber. Thereby, production quality of carrier board is significantly improved, as well as the cost for production of which is effectively reduced.

Abstract: An electronic circuit component includes: an electronic component; a leadframe that forms a circuit pattern corresponding to an arrangement of the electronic component; a resin element in which a part of the leadframe is disposed by insert molding; a first lid element that covers a first surface of the resin element on which the electronic component is arranged, the first surface of the resin element including a concave land in which the electronic component is arranged; and terminal portions that are arranged on a bottom surface of the land. The terminal portions are a part of the leadframe and are electrically connected to the electronic component. A part of the first lid element that is opposed to the land includes a recess that defines a clearance between the electronic component and the first lid element.

Abstract: A semiconductor device includes a power transistor in a semiconductor substrate portion, where the semiconductor substrate portion includes a central portion and a kerf, components of the power transistor are arranged in the central portion, and the central portion has a thickness d. The semiconductor device also includes a support element disposed over a main surface of the central portion, where the support element has a smallest lateral extension t at a side adjacent to the main surface of the semiconductor substrate portion and a height h, where 0.1×h?d?4×h and 0.1×h?t?1.5×h.

Abstract: An integrated circuit including a plurality of first semiconductor strips of a first conductivity type and of second semiconductor strips of a second conductivity type arranged in alternated and contiguous fashion on a region of the second conductivity type, including for each of the first strips: a plurality of bias contacts; for each bias contact, a switch capable of applying a potential on the bias contact; two detection contacts arranged at the ends of the first strip; and a detection circuit having its activation causing the turning off of the switches and the comparison with a threshold of the resistance between the detection contacts.

Abstract: The present disclosure relates to a microelectronics package with an inductive element and a magnetically enhanced mold compound component, and a process for making the same. The disclosed microelectronics package includes a module substrate, a thinned flip-chip die with an upper surface that includes a first surface portion and a second surface portion surrounding the first surface portion, the magnetically enhanced mold compound component, and a mold compound component. The thinned flip-chip die is attached to the module substrate and includes a device layer with an inductive element embedded therein. Herein, the inductive element is underlying the first surface portion and not underlying the second surface portion. The magnetically enhanced mold compound component is formed over the first surface portion. The mold compound component is formed over the second surface portion, not over the first surface portion, and surrounding the magnetically enhanced mold compound component.

Abstract: A circuit board with a measure against high frequency noise includes: an interconnect substrate having an interconnect pattern to which an IC which is a source of high frequency noise is electrically connected; a pair of lands provided on a mounting surface of the interconnect substrate; and a chip component having a body composed of a magnetic body (i.e., ferrite) in a rectangular parallelepiped, and a pair of external electrodes provided at opposite ends of the body, the pair of external electrodes being connected to the pair of lands, the body being disposed on the interconnect pattern, as observed in a direction perpendicular to the mounting surface.

Abstract: A wafer level fan out semiconductor device and a manufacturing method thereof are provided. A first sealing part is formed on lateral surfaces of a semiconductor die. A plurality of redistribution layers are formed on surfaces of the semiconductor die and the first sealing part, and solder balls are attached to the redistribution layers. The solder balls are arrayed on the semiconductor die and the first sealing part. In addition, a second sealing part is formed on the semiconductor die, the first sealing part and lower portions of the solder balls. The solder balls are exposed to the outside through the second sealing part. Since the first sealing part and the second sealing part are formed of materials having thermal expansion coefficients which are the same as or similar to each other, warpage occurring to the wafer level fan out semiconductor device can be suppressed.

Abstract: A semiconductor device and a method of manufacturing a semiconductor device. As a non-limiting example, various aspects of this disclosure provide a semiconductor device, and a method of manufacturing thereof, that comprises a substrate including a dielectric layer, at least one conductive trace and conductive bump pad formed on one surface of the dielectric layer, and a protection layer covering the at least one conductive trace and conductive bump pad, the at least one conductive bump pad having one end exposed through the protection layer, and a semiconductor die electrically connected to the conductive bump pad of the substrate.

Abstract: There is provided a Cu bonding wire having a Pd coating layer on a surface thereof, that improves bonding reliability of a ball bonded part in a high-temperature and high-humidity environment and is suitable for on-vehicle devices. The bonding wire for a semiconductor device includes a Cu alloy core material and a Pd coating layer formed on a surface of the Cu alloy core material, and the bonding wire contains In of 0.011 to 1.2% by mass and has the Pd coating layer of a thickness of 0.015 to 0.150 ?m. With this configuration, it is able to increase the bonding longevity of a ball bonded part in a high-temperature and high-humidity environment, and thus to improve the bonding reliability. When the Cu alloy core material contains one or more elements of Pt, Pd, Rh and Ni in an amount, for each element, of 0.05 to 1.2% by mass, it is able to increase the reliability of a ball bonded part in a high-temperature environment of 175° C. or more.

Abstract: A chip arrangement including a chip comprising a chip back side; a back side metallization on the chip back side, the back side metallization including a plurality of layers; a substrate comprising a surface with a metal layer; a zinc-based solder alloy configured to attach the back side metallization to the metal layer, the zinc-based solder alloy having by weight 8% to 20% aluminum, 0.5% to 20% magnesium, 0.5% to 20% gallium, and the balance zinc; wherein the metal layer is configured to provide a good wettability of the zinc-based solder alloy on the surface of the substrate. The plurality of layers may include one or more of a contact layer configured to contact a semiconductor material of the chip back side; a barrier layer; a solder reaction, and an oxidation protection layer configured to prevent oxidation of the solder reaction layer.

Abstract: A semiconductor package includes a first interposer, a second interposer, and a gap between the first interposer and the second interposer. The first interposer and the second interposer are coplanar. A first die is mounted on the first interposer and the second interposer. The first die includes first connection elements connecting the first die to the first interposer or the second interposer. A redistribution layer (RDL) structure is disposed on bottom surfaces of the first and second interposers for connecting the first interposer with the second interposer. The RDL structure includes at least one bridge trace traversing the gap to electrically connect the first interposer with the second interposer.

Abstract: A microelectronic assembly including an insulating layer having a plurality of nanoscale conductors disposed in a nanoscale pitch array therein and a pair of microelectronic elements is provided. The nanoscale conductors can form electrical interconnections between contacts of the microelectronic elements while the insulating layer can mechanically couple the microelectronic elements together.

Abstract: An electronic device and a method of making an electronic device. As non-limiting examples, various aspects of this disclosure provide various methods of manufacturing electronic devices, and electronic devices manufactured thereby, that comprise utilizing an adhesive layer to attach an upper electronic package to a lower die and/or utilizing metal pillars for electrically connecting the upper electronic package to a lower substrate, wherein the metal pillars have a smaller height above the lower substrate than the lower die.

Abstract: A method comprises depositing a first dielectric layer over a first chip comprising a plurality of first active circuits and a first connection pad, patterning the first dielectric layer to form a first opening, filling the first opening to form a connector in contact with the first connection pad, depositing a second dielectric layer over the first dielectric layer, patterning the second dielectric layer to form a second opening over the connector, filling the second opening to form a first bonding pad in contact with the connector, stacking a second chip on the first chip, wherein the second chip comprises a plurality of second active circuits and a second bonding pad and bonding the first chip and a second chip together to form a stacked semiconductor device through applying a hybrid bonding process to the first bonding pad and the second bonding pad.

Abstract: A light-emitting device including a light-emitting unit, a packaging sealant, a transparent layer, and a reflective structure is provided. The light-emitting unit has at least one epitaxial layer and two electrodes correspondingly formed on the epitaxial layer. The epitaxial layer has a top surface, a bottom surface on which the two electrodes are exposed, and a side surface connecting the bottom surface and the top surface. The packaging sealant is formed on the top surface and the side surface of the epitaxial layer. The transparent layer is disposed on the packaging sealant and located above the top surface of the epitaxial layer. The reflective structure is disposed surrounding the side surface of the epitaxial layer and formed on the packaging sealant. A manufacturing method of the above light-emitting device is further provided.

Abstract: A light-emitting diode display apparatus including a circuit substrate, a display matrix, a driving circuit, and an interface circuit is provided. The display matrix is disposed on the circuit substrate, and has a plurality of display pixels. The driving circuit is disposed on the circuit substrate, and has at least one driver. The driver has a programmable planning area. The interface circuit is disposed on the circuit substrate, and electrically coupled to the driving circuit. The interface circuit is configured to receive input information, and transports the input information to the driving circuit.

Abstract: An optoelectronic component includes a composite body including a molded body; and an optoelectronic semiconductor chip embedded into the molded body, wherein an electrically conductive through contact extends from a top side of the composite body to an underside of the composite body through the molded body, a top side of the optoelectronic semiconductor chip is at least partly not covered by the molded body, the chip includes a first electrical contact on its top side, a first top side metallization is arranged on the top side of the composite body and electrically conductively connects the first electrical contact to the through contact, the optoelectronic component includes an upper insulation layer extending over the first top side metallization, and the optoelectronic component includes a second top side metallization arranged above the upper insulation layer and electrically insulated with respect to the first top side metallization by the upper insulation layer.

Abstract: A light emitting device includes a carrier, a plurality of light emitting diode chips and a plurality of buffer pads. Each light emitting diode chip includes a first type semiconductor layer, an active layer, a second type semiconductor layer, a via hole and a plurality of bonding pads. The via hole sequentially penetrates through the first type semiconductor layer, the active layer and a portion of the second type semiconductor layer. The first type semiconductor layer, the active layer, the second type semiconductor layer and the via hole define a epitaxial structure. The buffer pads are disposed between the carrier and the second type semiconductor layer, wherein the buffer pads is with Young's modulus of 2˜10 GPa, the second bonding pad is disposed within the via hole to contact the second type semiconductor layer, and the epitaxial structure is electrically bonded to the receiving substrate through the bonding pads.

Abstract: An integrated circuit assembly that includes a substrate; a member formed on the substrate; a first die mounted to the substrate within an opening in the member such that there is space between the first die and the member and the member surrounds the first die, and wherein the first die does not extend above an upper surface of the member; an underfill between the first the die and the substrate, wherein the underfill at least partially fills the space between the die and member; and a second die mounted to the first die and the member, wherein the second die is mounted to the member on all sides of the opening.

Abstract: A topology for memory circuits of a non-volatile memory system reduces capacitive loading. For a given channel, a single memory chip can be connected to the controller, but is in turn connected to multiple other memory devices that fan out in a tree-like structure, which can also fan back in to a single memory device. In addition to the usual circuitry, such as a memory arrays and associated peripheral circuitry, the memory chip also includes a flip-flop circuit and can function in several modes. The modes include a pass-through mode, where the main portions of the memory circuit are inactive and commands and data are passed through to other devices in the tree structure, and an active mode, where the main portions of the memory circuit are active and can receive and supply data. Reverse active and reverse pass-through modes, where data flows in the other direction, can also be used.

Abstract: A topology for memory circuits of a non-volatile memory system reduces capacitive loading. For a given channel, a single memory chip can be connected to the controller, but is in turn connected to multiple other memory devices that fan out in a tree-like structure, which can also fan back in to a single memory device. In addition to the usual circuitry, such as a memory arrays and associated peripheral circuitry, the memory chip also includes a flip-flop circuit and can function in several modes. The modes include a pass-through mode, where the main portions of the memory circuit are inactive and commands and data are passed through to other devices in the tree structure, and an active mode, where the main portions of the memory circuit are active and can receive and supply data. Reverse active and reverse pass-through modes, where data flows in the other direction, can also be used.