Abstract: Embodiments of the invention include device packages and methods of forming such packages. In an embodiment, the method of forming a device package may comprise forming a reinforcement layer over a substrate. One or more openings may be formed through the reinforcement layer. In an embodiment, a device die may be placed into one of the openings. The device die may be bonded to the substrate by reflowing one or more solder bumps positioned between the device die and the substrate. Embodiments of the invention may include a molded reinforcement layer. Alternative embodiments include a reinforcement layer that is adhered to the surface of the substrate with an adhesive layer.

Abstract: Embodiments include semiconductor packages and method of forming the semiconductor packages. A semiconductor package includes a plurality of conductive layers over a package substrate. The conductive layers include a first conductive layer and first-level interconnects (FLIs) in the package substrate. The semiconductor package also includes a solder resist that surrounds the FLIs, where the solder resist has a top surface that is substantially coplanar to top surfaces of the FLIs, a bridge coupled directly to the first conductive layer with solder balls, where the first conductive layer is coupled to the FLIs, and a dielectric over the conductive layers, the bridge, and the solder resist of the package substrate. The bridge may be an embedded multi-die interconnect bridge (EMIB). The first conductive layer may include first conductive pads and second conductive pads. The FLIs may include first conductive vias, second conductive vias, diffusion layers, and third conductive pads.

Abstract: An embedded multi-die interconnect bridge (EMIB) is fabricated on a substrate using photolithographic techniques, and the EMIB is separated from the substrate and placed on the penultimate layer of an integrated-circuit package substrate, below the top solder-resist layer. A low Z-height of the EMIB, allows for useful trace and via real estate below the EMIB, to be employed in the package substrate.

Abstract: Embodiments of a system and methods for localized high density substrate routing are generally described herein. In one or more embodiments an apparatus includes a medium, first and second circuitry elements, an interconnect element, and a dielectric layer. The medium can include low density routing therein. The interconnect element can be embedded in the medium, and can include a plurality of electrically conductive members therein, the electrically conductive member can be electrically coupled to the first circuitry element and the second circuitry element. The interconnect element can include high density routing therein. The dielectric layer can be over the interconnect die, the dielectric layer including the first and second circuitry elements passing therethrough.

Abstract: A glass substrate houses an embedded multi-die interconnect bridge that is part of a semiconductor device package. Through-glass vias communicate to a surface for mounting on a semiconductor package substrate.

Abstract: Embodiments disclosed herein include electronic packages and methods of forming such electronic packages. In an embodiment, the electronic package comprises a base substrate. The base substrate may have a plurality of through substrate vias. In an embodiment, a first die is over the base substrate. In an embodiment a first cavity is disposed into the base substrate. In an embodiment, the first cavity is at least partially within a footprint of the first die. In an embodiment, a first component is in the first cavity.

Abstract: IC packages including a heat spreading material comprising crystalline carbon. The heat spreading material may be applied directly to an IC die surface, for example at a die prep stage, prior to an application or build-up of packaging material, so that the high thermal conductivity may best mitigate any hot spots that develop at the IC die surface during operation. The heat spreading material may be applied to surface of the IC die.

Abstract: IC package including a material preform comprising graphite. The material preform may have a thermal conductivity higher than that of other materials in the package and may therefore mitigate the formation of hot spots within an IC die during device operation. The preform may have high electrical conductivity suitable for EMI shielding. The preform may comprise a graphite sheet that can be adhered to a package assembly with an electrically conductive adhesive, applied, for example over an IC die surface and a surrounding package dielectric material. Electrical interconnects of the package may be coupled to the graphite sheet as an EMI shield. The package preform may be grounded to a reference potential through electrical interconnects of the package, which may be further coupled to a system-level ground plane. System-level thermal solutions may interface with the package-level graphite sheet.

Abstract: Ultra-thin, hyper-density semiconductor packages and techniques of forming such packages are described. An exemplary semiconductor package is formed with one or more of: (i) metal pillars having an ultra fine pitch (e.g., a pitch that is greater than or equal to 150 ?m, etc.); (ii) a large die to-package ratio (e.g., a ratio that is equal to or greater than 0.85, etc.); and (iii) a thin pitch translation interposer. Another exemplary semiconductor package is formed using coreless substrate technology, die back metallization, and low temperature solder technology for ball grid array (BGA) metallurgy. Other embodiments are described.

Abstract: Embodiments of the invention include device packages and methods of forming such packages. In an embodiment, the method of forming a device package may comprise forming a reinforcement layer over a substrate. One or more openings may be formed through the reinforcement layer. In an embodiment, a device die may be placed into one of the openings. The device die may be bonded to the substrate by reflowing one or more solder bumps positioned between the device die and the substrate. Embodiments of the invention may include a molded reinforcement layer. Alternative embodiments include a reinforcement layer that is adhered to the surface of the substrate with an adhesive layer.

Abstract: An integrated circuit package may be formed having at least one heat dissipation structure within the integrated circuit package itself. In one embodiment, the integrated circuit package may include a substrate; at least one integrated circuit device, wherein the at least one integrated circuit device is electrically attached to the substrate; a mold material on the substrate and adjacent to the at least one integrated circuit device; and at least one heat dissipation structure contacting the at least one integrated circuit, wherein the at least one heat dissipation structure is embedded either within the mold material or between the mold material and the substrate.

Abstract: Embodiments disclosed herein include electronic packages. In an embodiment, the electronic package comprises, a package substrate, an interposer on the package substrate, a first die cube and a second die cube on the interposer, wherein the interposer includes conductive traces for electrically coupling the first die cube to the second die cube, a die on the package substrate, and an embedded multi-die interconnect bridge (EMIB) in the package substrate, wherein the EMIB electrically couples the interposer to the die.

Abstract: Disclosed herein are antenna boards, antenna modules, and communication devices. For example, in some embodiments, an antenna board may include a plurality of antenna patches coupled to a dielectric material and a plurality of pedestals extending from a face of the dielectric material and at least partially embedded in the dielectric material.

Abstract: An apparatus is provided which comprises: a plurality of dielectric layers forming a substrate, a plurality of first conductive contacts on a first surface of the substrate, a cavity in the first surface of the substrate defining a second surface parallel to the first surface, a plurality of second conductive contacts on the second surface of the substrate, one or more integrated circuit die(s) coupled with the second conductive contacts, and mold material at least partially covering the one or more integrated circuit die(s) and the first conductive contacts. Other embodiments are also disclosed and claimed.

Abstract: A method of forming a planar antenna on a first substrate. An antenna feedline is formed on a peelable copper film of a carrier. A dielectric with no internal conductive layer is formed on the feedline. A planar antenna is formed on one of two parallel sides of the dielectric and a feed port is formed adjacent the other parallel side. The feedline connects the antenna with the feed port. One plane of the planar antenna is configured for perpendicular attachment to a second substrate. The feedline is connected to the planar antenna by a via through the dielectric. The peelable copper is removed and the structure is etched to produce the planar antenna on the substrate. Two planar antennas on substrates can be perpendicularly attached to another substrate to form side-firing antennas.

Abstract: Examples of an electronic package include a package assembly. The package assembly can include a substrate having a first substrate surface that includes a conductive layer attached to the first substrate surface. The package assembly includes a die communicatively coupled to the conductive layer and a contact block that includes a first contact surface on one end of the contact block, a second contact surface on an opposing side of the contact block, and a contact block wall extended therebetween. The contact block can include a conductive material. The first contact surface can be coupled to the package assembly with a joint extended partially up the contact block wall. The electronic package can further include an overmold covering portions of the substrate, conductive layer, and die. The second contact surface of the contact block can be exposed through the overmold.

Abstract: An electronic package and method includes a substrate including a plurality of pads on a major surface. An electronic component including a plurality of pads on a major surface facing the major surface of the substrate. A stud bump electrically couples one of the plurality of pads of the substrate to one of the plurality of pads of the electronic component.

Abstract: A wire-bond memory die is coupled to a system-on-chip processor where the processor is flip-chip mounted on a semiconductor package substrate, and the wire-bond memory die is also flip-chip configured through a redistribution layer that pins out to a series of pillars that contact the semiconductor package substrate. The wire-bond memory die is stacked on the processor and the redistribution layer overhangs the processor to contact the series of pillars.

Abstract: An electronic package technology is disclosed. A first active die can be mountable to and electrically coupleable to a package substrate. A second active die can be disposed on a top side of the first active die, the second active die being electrically coupleable to one or both of the first active die and the package substrate. At least one open space can be available on the top side of the first active die. At least a portion of a stiffener can substantially fill the at least one open space available on the top side of the first active die.

Abstract: An embedded multi-die interconnect bridge (EMIB) die is configured with power delivery to the center of the EMIB die and the power is distributed to two dice that are interconnected across the EMIB die.