Abstract: Embodiments disclosed include computer automated systems and methods for aggregating data from a plurality of data sources, such as proxy devices, legacy protocols, devices, applications, machines, sensors, things across locations and user types, or device clouds among devices and applications. The aggregated data is then normalized, and the normalized data is analyzed. The analyzing is based on a correlated event or events, a correlated condition or conditions, and a correlated trend or trends across the plurality of data sources. And based on the analyzed data, relevant aggregated and normalized data is combined and displayed in a display compatible format. Additionally, user needs are determined based on the analyzed aggregated, normalized data. The user need comprises a need for an item or items comprising at least one of a service, a product, and an upgrade of hardware or software components.

Abstract: Apparatus for touch scrolling, the apparatus comprising a scrolling activator for scrolling activation by a finger of a user, the scrolling activator comprising a first end zone adjacent a first end of the scrolling activator for fast scrolling in a first scrolling direction, a second end zone adjacent a second end of the scrolling activator for fast scrolling in a second scrolling direction, and a normal zone for normal scrolling.

Abstract: A flexible film interposer for stacking a flip chip semiconductor die onto a second (bottom) semiconductor die, semiconductor devices and stacked die assemblies that incorporate the flexible film interposer, and methods of fabricating the devices and assemblies are provided. The incorporation of the flexible film interposer achieves densely packaged semiconductor devices, without the need for a redistribution layer (RDL).

Abstract: Various embodiments of an interposer for mounting a semiconductor die, as well as methods for forming the interposer, are disclosed. The interposer includes flexible solder pad elements that are formed from a core material of the interposer, such that the interposer may absorb thermally induced stresses and conform to warped or uneven surfaces. Embodiments of electronic device packages including a semiconductor die mounted to and electrically connected to the interposer, as well as methods for forming the electronic device packages, are also disclosed. In one electronic device package, the semiconductor die is electrically connected to the interposer with wire bonds attached to a routing layer of the interposer. In another electronic device package, the semiconductor die is electrically connected to the interposer by bonding the semiconductor die to the flexible solder pad elements of the interposer in a flip-chip configuration.

Abstract: Apparatus and methods relating to semiconductor assemblies. A semiconductor assembly includes an interposer which may be constructed from a flexible material, such as a polyimide tape. A pattern of conductive traces disposed on a first surface of the interposer is in electrical communication with a semiconductor die attached to the first surface. Interconnect recesses accessible on the opposite second surface expose one or more conductive traces. A conductive element, such as a solder ball, disposed substantially within the interconnect recess allows the assembly to be mounted on a substrate or a similar assembly. By substantially containing the conductive element within the interconnect recess, the height of the completed assembly is reduced. Assemblies may be stacked to form multidie assemblies. Interconnect structures, such as connection pads, or enlarged traces upon the first surface are employed to connect stacked assemblies.

Abstract: Packaging and encapsulation methods include use of a tape substrate with a mold gate that includes an aperture and a support element that extends over at least a portion of the aperture. The tape substrate may be part of a strip. A semiconductor device is secured and electrically connected to the tape substrate. The resulting assembly is placed into a cavity of a mold, and encapsulant is introduced into the cavity through the mold gate of the tape substrate. Once the encapsulant has sufficiently hardened, the package assembly may be removed from the mold, and a sprue of residual encapsulant removed therefrom. If the package assembly is carried by a strip that carries other package assemblies, it may be removed from the strip.

Abstract: A circuit package is formed using a leadframe. The leadframe is formed or etched to align a plurality of bond pad structures above a reference plane while supporting leadframe fingers are positioned below the reference plane. Jumper wires are wirebonded between terminals on the die and the bond pads to form a package subassembly. The subassembly is encapsulated and then background to remove the leadframe fingers and surrounding frame. The bond pads which remain embedded in the encapsulation material are exposed on the lower surface of the package for connection to further conductors.

Abstract: Microfeature workpiece substrates having through-substrate vias, and associated methods of formation are disclosed. A method in accordance with one embodiment for forming a support substrate for carrying microfeature dies includes exposing a support substrate to an electrolyte, with the support substrate having a first side with a first conductive layer, a second side opposite the first side with a second conductive layer, and a conductive path extending through the support substrate from the first conductive layer to the second conductive layer. The method can further include forming a bond pad at a bond site of the first conductive layer by disposing at least one conductive bond pad material at the bond site, wherein disposing the at least one conductive bond pad material can include passing an electrical current between the first and second conductive layers via the conductive path, while the substrate is exposed to the electrolyte.

Abstract: Microelectronic devices, associated assemblies, and associated methods are disclosed herein. For example, certain aspects of the invention are directed toward a microelectronic device that includes a microfeature workpiece having a side and an aperture in the side. The device can further include a workpiece contact having a surface. At least a portion of the surface of the workpiece contact can be accessible through the aperture and through a passageway extending between the aperture and the surface. Other aspects of the invention are directed toward a microelectronic support device that includes a support member having a side carrying a support contact that can be connectable to a workpiece contact of a microfeature workpiece. The device can further include recessed support contact means carried by the support member. The recessed support contact means can be connectable to a second workpiece contact of the microfeature workpiece.

Abstract: A semiconductor device for dissipating heat generated by a die during operation and having a low height profile, a semiconductor die package incorporating the device, and methods of fabricating the device and package are provided. In one embodiment, the semiconductor device comprises a thick thermally conductive plane (e.g., copper plane) mounted on a thin support substrate and interfaced with a die. Thermally conductive via interconnects extending through the substrate conduct heat generated by the die from the conductive plane to conductive balls mounted on traces on the opposing side of the substrate. In another embodiment, the semiconductor devices comprises a thick thermally conductive plane (e.g., copper foil) sandwiched between insulative layers, with signal planes (e.g., traces, bonding pads) disposed on the insulative layers, a die mounted on a first signal plane, and solder balls mounted on bonding pads of a second signal plane.

Abstract: There is provided apparatus comprising a user interface for displaying a plurality of items. The apparatus is arranged: a) to receive at least one instruction, by which instruction or instructions, one or more of a plurality of items initially displayed on the user interface is or are categorized as an item or items to be hidden and the remaining one or more of the plurality of items initially displayed on the user interface is or are categorized as an item or items to be displayed; b) to receive an instruction to hide, from the user interface, the one or more items to be hidden; and c) to hide from the user interface, the one or more items to be hidden, such that the item or items categorized as items to be displayed are displayed on the user interface, and the item or items categorized as items to be hidden are not displayed on the user interface. In one preferred arrangement, the apparatus is an electronic device.

Abstract: A method and apparatus for packaging a semiconductor die with an interposer substrate. The semiconductor device assembly includes a conductively bumped semiconductor die and an interposer substrate having multiple recesses formed therein. The semiconductor die is mounted to the interposer substrate with the conductive bumps disposed in the multiple recesses so that the active surface of the semiconductor die is directly mounted to a facing surface of the interposer substrate. One or more openings may be provided in an opposing surface of the interposer substrate which extends to the multiple recesses and the bumps disposed therein and dielectric filler material introduced through the one or more openings into the recesses.

Abstract: Supports (40) of microelectronic devices (10) are provided with underfill apertures (60) which facilitate filling underfill gaps (70) with underfill material (74). The underfill aperture may have a longer first dimension (62) and a shorter second dimension (64). In some embodiments, a method of filling the underfill gap (70) employs a removable stencil (80). If so desired, a stencil (80) can be used to fill multiple underfill gaps through multiple underfill apertures in a single pass.

Abstract: A method and apparatus for increasing the integrated circuit density in a flip chip semiconductor device assembly including an interposer substrate facilitating use with various semiconductor die conductive bump arrangements. The interposer substrate includes a plurality of recesses formed in at least one of a first surface and a second surface thereof, wherein the recesses are arranged in a plurality of recess patterns. The interposer substrate also provides enhanced accessibility for test probes for electrical testing of the resulting flip chip semiconductor device assembly.

Abstract: Various embodiments of an interposer for mounting a semiconductor die, as well as methods for forming the interposer, are disclosed. The interposer includes flexible solder pad elements that are formed from a core material of the interposer, such that the interposer may absorb thermally induced stresses and conform to warped or uneven surfaces. Embodiments of electronic device packages including a semiconductor die mounted to and electrically connected to the interposer, as well as methods for forming the electronic device packages, are also disclosed. In one electronic device package, the semiconductor die is electrically connected to the interposer with wire bonds attached to a routing layer of the interposer. In another electronic device package, the semiconductor die is electrically connected to the interposer by bonding the semiconductor die to the flexible solder pad elements of the interposer in a flip-chip configuration.

Abstract: An interposer includes a substrate, a conductive structure configured to contact the back side of a semiconductor device and contact pads. The interposer may include first and second sets of contact pads carried by the substrate. The interposer may also include conductive traces carried by the substrate to electrically connect corresponding contact pads of the first and second sets. The receptacles, which may be formed in a surface of the substrate and expose contacts of the second set, may be configured to at least partially receive conductive structures that are secured to the contact pads of the second set. Thus, the interposer may be useful in providing semiconductor device assemblies and packages of reduced height or profile. Such assemblies and packages are also described, as are multi-chip modules including such assemblies or packages.

Abstract: An interposer for assembly with a semiconductor die and methods of manufacture are disclosed. The interposer may include at least one passive element at least partially defined by at least one recess formed in at least one dielectric layer of the interposer. The at least one recess may have dimensions selected for forming the passive element with an intended magnitude of at least one electrical property. At least one recess may be formed by removing at least a portion of at least one dielectric layer of an interposer. The at least one recess may be at least partially filled with a conductive material. For instance, moving, by way of squeegee, or injection of a conductive material at least partially within the at least one recess, is disclosed. Optionally, vibration of the conductive material may be employed. A wafer-scale interposer and a system including at least one interposer are disclosed.

Abstract: Various embodiments of an interposer for mounting a semiconductor die, as well as methods for forming the interposer, are disclosed. The interposer includes flexible solder pad elements that are formed from a core material of the interposer, such that the interposer may absorb thermally induced stresses and conform to warped or uneven surfaces. Embodiments of electronic device packages including a semiconductor die mounted to and electrically connected to the interposer, as well as methods for forming the electronic device packages, are also disclosed. In one electronic device package, the semiconductor die is electrically connected to the interposer with wire bonds attached to a routing layer of the interposer. In another electronic device package, the semiconductor die is electrically connected to the interposer by bonding the semiconductor die to the flexible solder pad elements of the interposer in a flip-chip configuration.

Abstract: An interposer for assembly with a semiconductor die and methods of manufacture are disclosed. The interposer may include at least one passive element at least partially defined by at least one recess formed in at least one dielectric layer of the interposer. The at least one recess may have dimensions selected for forming the passive element with an intended magnitude of at least one electrical property. At least one recess may be formed by removing at least a portion of at least one dielectric layer of an interposer. The at least one recess may be at least partially filled with a conductive material. For instance, moving, by way of squeegee, or injection of a conductive material at least partially within the at least one recess, is disclosed. Optionally, vibration of the conductive material may be employed. A wafer-scale interposer and a system including at least one interposer are disclosed.

Abstract: Various embodiments of an interposer for mounting a semiconductor die, as well as methods for forming the interposer, are disclosed. The interposer includes flexible solder pad elements that are formed from a core material of the interposer, such that the interposer may absorb thermally induced stresses and conform to warped or uneven surfaces. Embodiments of electronic device packages including a semiconductor die mounted to and electrically connected to the interposer, as well as methods for forming the electronic device packages, are also disclosed. In one electronic device package, the semiconductor die is electrically connected to the interposer with wire bonds attached to a routing layer of the interposer. In another electronic device package, the semiconductor die is electrically connected to the interposer by bonding the semiconductor die to the flexible solder pad elements of the interposer in a flip-chip configuration.