Abstract: A flexible packaging architecture is described that is suitable for curved package shapes. In one example a package has a first die, a first mold compound layer over the first die, a wiring layer over the first mold compound layer, a second die over the wiring layer and electrically coupled to the wiring layer, and a second mold compound layer over the second die.

Abstract: Embodiments of the present disclosure provide a semiconductor package configured to provide for a disposition of one or more package components on a substrate within a footprint of a package die. In embodiments, the package may include a package substrate having a first side and a second side opposite the first side. An area of the first side of the package substrate within which a die is to be disposed may form a footprint of the die on the substrate. The package may further include a voltage reference plane coupled with the second side of the package substrate. At least a portion of the voltage reference plane may be disposed within the die footprint, to provide a reference voltage to components to be disposed within the footprint on the second side of the substrate, and to shield these components from electromagnetic interference. Other embodiments may be described and/or claimed.

Abstract: Ring-in-ring stiffeners on a semiconductor package substrate includes a passive device that is seated across the ring stiffeners. The ring-in-ring stiffeners are also electrically coupled to traces in the semiconductor package substrate through electrically conductive adhesive that bonds a given ring stiffener to the semiconductor package substrate. The passive device is embedded between the two ring stiffeners to create a smaller X-Y footprint as well as a lower Z-direction profile.

Abstract: A system in package device includes an overpass die on a package substrate and the overpass die includes a recess on the back side in order to straddle a landed die also on the package substrate. The recess is bounded by at least two overpass walls. Communication between the dice is done with a through-silicon via and communication between the overpass die and the package substrate is also done with a through-silicon via.

Abstract: An electrical interconnect for an electronic package. The electrical interconnect includes a first dielectric layer; a second dielectric layer; a signal conductor positioned between the first dielectric layer and the second dielectric layer; and a conductive reference layer mounted on the first dielectric layer, and wherein the conductive reference layer does not cover the signal conductor. The conductive reference layer may be a first conductive reference layer and the electrical interconnect further comprises a second conductive reference layer mounted on the second dielectric layer. The second conductive reference layer does not cover the signal conductor. In addition, the signal conductor may be a first signal conductor and the electrical interconnect may further include a second signal conductor between the first dielectric layer and the second dielectric layer. The first and second signal conductors may form a differential pair of conductors.

Abstract: A self-equalizing interconnect in a connector is installed in a microelectronic device. The self-equalizing interconnect is formed of a plurality of electrically conductive layers under conditions to offset skin-effect losses with respect to frequency change during operation. Each successive layer is configured to with the next highest electrical conductivity and subsequent electrically conductive films gradually decrease in electrical conductivity. In an embodiment, thickness of the conductive film adjacent the reference plain is configured thinnest and subsequent films are added and are seriatim gradually thicker. The highest electrically conductive film is configured closest to a reference plane in the connector, and the lowest electrically conductive film is farthest from the reference plane.

Abstract: Embodiments are generally directed to a mutual inductance suppressor for crosstalk immunity enhancement. An embodiment of a printed circuit board includes a first signal trace and a second signal trace on a first layer, wherein the first signal trace and second signal trace are non-intersecting; a second layer below the first layer, the second layer including a voltage reference plane; and a mutual inductance suppressor in the voltage reference plane, the mutual inductance suppressor including a serpentine portion of the voltage reference plane between the first signal trace and the second signal trace.

Abstract: A system in package device includes a landed first die disposed on a package substrate. The landed first die includes a notch that is contoured and that opens the backside surface of the die to a ledge. A stacked die is mounted at the ledge and the two dice are each contacted by a through-silicon via (TSV). The system in package device also includes a landed subsequent die on the package substrate and a contoured notch in the landed subsequent die and the notch in the first die form a composite contoured recess into which the stacked die is seated.

Abstract: Embodiments are generally directed to 3D high-inductive ground plane for crosstalk reduction. An embodiment of a printed circuit board includes a first signal trace and a second signal trace on a first layer, wherein the first signal trace and second signal trace are non-intersecting; a second layer below the first layer; a third layer below the second layer; and a three-dimensional (3D) ground plane, the 3D ground plane including a first plurality of segments on the third layer, a second plurality of segments on the second layer, and a plurality of metal vias to connect the first plurality of segments and the second plurality of segments in the ground plane.

Abstract: A system-in-package includes a package substrate that at least partially surrounds an embedded radio-frequency integrated circuit chip and a processor chip mated to a redistribution layer. A wide-band phased-array antenna module is mated to the package substrate with direct interconnects from the radio-frequency integrated circuit chip to antenna patches within the antenna module. Additionally, fan-out antenna pads are also coupled to the radio-frequency integrated circuit chip.

Abstract: A stiffener includes a through-stiffener interconnect that couples a semiconductor package substrate to a package-on-package device. The through-stiffener interconnect is insulated by a through-stiffener dielectric within a through-stiffener contact corridor. A semiconductive die is coupled to the semiconductor package substrate and to the package-on-package device.

Abstract: Semiconductor package assemblies and semiconductor packages incorporating an impedance-boosting channel between a transmitter die and a receiver die are described. In an example, a semiconductor package includes a package substrate incorporating the impedance-boosting channel having a first arc segment connected to the transmitter die and a second arc segment connected to the receiver die. The arc segments extend around respective vertical axes passing through a transmitter die electrical bump and a receiver die electrical bump, respectively. Accordingly, the arc segments introduce an inductive circuitry to increase signal integrity of an electrical signal sent from the transmitter die to the receiver die.

Abstract: A microelectronic device package including multiple layers of stacked die. Multiple die layers in the package can include two or more die. At least two die in a first layer will be laterally spaced from one another to define a first gap extending in a first direction; and at least two die in a second layer will be laterally spaced from one another to define a second gap extending in a second direction that is angularly offset from the first direction. The first and second directions can be perpendicular to one another.

Abstract: Embodiments are generally directed to an apparatus utilizing computer on package construction. An embodiment of a computer includes a substrate; one or more semiconductor devices, the one or more semiconductor devices being direct chip attached to the substrate, the one or more semiconductor devices including a central processing unit (CPU); and one or more additional components installed on the substrate, wherein the computer excludes I/O components.

Abstract: A fold in a semiconductor package substrate includes an embedded device that includes orthogonal electrical coupling through the package substrate by a bond-pad via that is configured to couple to a semiconductive device that is mounted on the semiconductor package substrate. The semiconductive device is coupled to the embedded device with the orthogonal electrical coupling.

Abstract: Semiconductor packages including a lateral interconnect having an arc segment to increase self-inductance of a signal line is described. In an example, the lateral interconnect includes a circular segment extending around an interconnect pad. The circular segment may extend around a vertical axis of a vertical interconnect to introduce an inductive circuitry to compensate for an impedance mismatch of the vertical interconnect.

Abstract: A semiconductor package apparatus includes a passive device that is embedded in a bottom package stiffener, and a top stiffener is stacked above the bottom package stiffener. Electrical connection through the passive device is accomplished through the stiffeners to a semiconductor die that is seated upon an infield region of the semiconductor package substrate.

Abstract: Ring-in-ring stiffeners on a semiconductor package substrate includes a passive device that is seated across the ring stiffeners. The ring-in-ring stiffeners are also electrically coupled to traces in the semiconductor package substrate through electrically conductive adhesive that bonds a given ring stiffener to the semiconductor package substrate. The passive device is embedded between the two ring stiffeners to create a smaller X-Y footprint as well as a lower Z-direction profile.

Abstract: Particular embodiments described herein provide for an electronic device, such as a notebook computer or laptop, which includes a circuit board coupled to a plurality of electronic components (which includes any type of components, elements, circuitry, etc.). One particular example implementation of the electronic device may include a low profile hinge design that includes a micro-hinge. The micro-hinge can couple a first element to a second element and can include a first attachment that couples to the first element, a second attachment that couples to the second element, and a plurality of linkages that couples the first attachment to the second attachment. The low profile hinge can further include a plurality of micro-hinges and a plurality of support rods.

Abstract: Techniques and mechanisms for mitigating the effect of signal noise on communication via an interconnect. In an embodiment, a substrate includes an interconnect and a conductor which has a hole formed therein. Portions of the interconnect variously extend over a side of the conductor, wherein another recess portion of the interconnect extends from a plane which includes the side, and further extends at least partially into the hole. The configuration of the recess portion extending within the hole may contribute to an impedance which dampens a transmitter slew rate of the communication. In an embodiment, a total distance along a path formed by the interconnect is equal to or less than 5.5 inches.