Abstract: Embodiments may relate to a microelectronic package with an interconnect stack that includes a cavity therein. The cavity may include a dielectric material with a dielectric value less than 3.9. The microelectronic package may further include first and second conductive elements in the cavity, with the dielectric material positioned therebetween. Other embodiments may be described or claimed.

Abstract: Embodiments herein may relate to an interconnect that includes a transceiver, wherein the transceiver is configured to generate a single side band (SSB) signal for communication over a waveguide and a waveguide interconnect to communicate the SSB signal over the waveguide. In an example, an SSB operator is configured to generate the SSB signal and the SSB signal can be generated by use of a finite-impulse response filter. Other embodiments may be described and/or claimed.

Abstract: An lithographic reticle may be formed comprising a transparent substrate, a substantially opaque mask formed on the transparent substrate that defines at least one exposure window, wherein the at least one exposure window has a first end, a first filter formed on the transparent substrate within the at least one exposure window and abutting the first end thereof, and a second filter formed on the transparent substrate within the at least one exposure window and abutting the first filter, wherein an average transmissivity of the first filter is substantially one half of a transmissivity of the second filter. In another embodiment, the at least one exposure window includes a third filter abutting the second end and is adjacent the second filter. Further embodiments of the present description include interconnection structures and systems fabricated using the lithographic reticle.

Abstract: An embedded silicon bridge system including tall interconnect via pillars is part of a system in package device. The tall via pillars may span a Z-height distance to a subsequent bond pad from a bond pad that is part of an organic substrate that houses the embedded silicon bridge.

Abstract: Various embodiments disclosed relate to a semiconductor package. The present semiconductor package includes a substrate. The substrate is formed from alternating conducting layers and dielectric layers. A first active electronic component is disposed on an external surface of the substrate, and a second active electronic component is at least partially embedded within the substrate. A first interconnect region is formed from a plurality of interconnects between the first active electronic component and the second active electronic component. Between the first active electronic component and the substrate a second interconnect region is formed from a plurality of interconnects. Additionally, a third interconnect region is formed from a plurality of interconnects between the second active electronic component and the substrate.

Abstract: An embedded silicon bridge system including tall interconnect via pillars is part of a system in package device. The tall via pillars may span a Z-height distance to a subsequent bond pad from a bond pad that is part of an organic substrate that houses the embedded silicon bridge.

Abstract: A multi-chip package includes a substrate (110) having a first side (111), an opposing second side (112), and a third side (213) that extends from the first side to the second side, a first die (120) attached to the first side of the substrate and a second die (130) attached to the first side of the substrate, and a bridge (140) adjacent to the third side of the substrate and attached to the first die and to the second die. No portion of the substrate is underneath the bridge. The bridge creates a connection between the first die and the second die. Alternatively, the bridge may be disposed in a cavity (615, 915) in the substrate or between the substrate and a die layer (750). The bridge may constitute an active die and may be attached to the substrate using wirebonds (241, 841, 1141, 1541).

Abstract: An electronic interposer may be formed using organic material layers, while allowing for the fabrication of high density interconnects within the electronic interposer without the use of embedded silicon bridges. This is achieved by forming the electronic interposer in three sections, i.e. an upper section, a lower section and a middle section. The middle section may be formed between the upper section and the lower section, wherein a thickness of each layer of the middle section is thinner than a thickness of any of the layers of the upper section and the lower section, and wherein conductive routes within the middle section have a higher density than conductive routes within the upper section and the lower section.

Abstract: Technology for simplified multimode signaling includes determining first and second self ?-terms, cross coupling ?-terms, and a delay skew term. For each communication link bundled in groups, the signals can be modulated as a superposition of the signals delayed and weighted based on the first and second self ?-terms, the cross coupling ?-terms and the delay skew term.

Abstract: Various embodiments disclosed relate to a semiconductor package. The present semiconductor package includes a substrate. The substrate is formed from alternating conducting layers and dielectric layers. A first active electronic component is disposed on an external surface of the substrate, and a second active electronic component is at least partially embedded within the substrate. A first interconnect region is formed from a plurality of interconnects between the first active electronic component and the second active electronic component. Between the first active electronic component and the substrate a second interconnect region is formed from a plurality of interconnects. Additionally, a third interconnect region is formed from a plurality of interconnects between the second active electronic component and the substrate.

Abstract: There is disclosed in one example an electromagnetic wave launcher apparatus, including: an interface to an electromagnetic waveguide; a first launcher configured to launch a high-frequency electromagnetic signal onto a first cross-sectional portion of the waveguide; and a second launcher configured to launch a lower-frequency electromagnetic signal onto a second cross-sectional portion of the waveguide.

Abstract: An integrated circuit package may be formed including at least one die side integrated circuit device having an active surface electrically attached to an electronic interposer, wherein the at least one die side integrated circuit device is at least partially encased in a mold material layer and wherein a back surface of the at least one die side integrated circuit device is in substantially the same plane as an outer surface of the mold material layer. At least one stacked integrated circuit device may be electrically attached to the back surface of the at least one die side integrated circuit through an interconnection structure formed between the at least one die side integrated circuit device and the at least one stacked integrated circuit device.

Abstract: An electronic interposer may be formed comprising an upper section, a lower section and a middle section. The upper section and the lower section may each have between two and four layers, wherein each layer comprises an organic material layer and at least one conductive route comprising at least one conductive trace and at least one conductive via. The middle section may be formed between the upper section and the lower section, wherein the middle section comprises up to eight layers, wherein each layer comprises an organic material and at least one conductive route comprising at least one conductive trace and at least one conductive via, and wherein a thickness of each layer of the middle section is thinner than a thickness of any of the layers of the upper section and thinner than a thickness of any of the layers of the lower section.

Abstract: An integrated circuit package having an electronic interposer comprising an upper section, a lower section and a middle section, a die side integrated circuit device electrically attached to the upper section of the electronic interposer, a die side heat dissipation device thermally contacting the die side integrated circuit device, a land side integrated circuit device electrically attached to the lower section of the electronic interposer, and a land side heat dissipation device thermally contacting the at least one die side integrated circuit device. The upper section and the lower section may each have between two and four layers and the middle section may be formed between the upper section and the lower section, and comprises up to eight layers, wherein a thickness of each layer of the middle section is thinner than a thickness of any of the layers of the upper section and the lower section.

Abstract: An lithographic reticle may be formed comprising a transparent substrate, a substantially opaque mask formed on the transparent substrate that defines at least one exposure window, wherein the at least one exposure window has a first end, a first filter formed on the transparent substrate within the at least one exposure window and abutting the first end thereof, and a second filter formed on the transparent substrate within the at least one exposure window and abutting the first filter, wherein an average transmissivity of the first filter is substantially one half of a transmissivity of the second filter. In another embodiment, the at least one exposure window includes a third filter abutting the second end and is adjacent the second filter. Further embodiments of the present description include interconnection structures and systems fabricated using the lithographic reticle.

Abstract: An integrated circuit device assembly may be formed comprising a reconstituted wafer attached to a base substrate, wherein the base substrate provides thermal management and optical signal routes. In one embodiment, the base substrate may include a plurality of electrical interconnects for electrically coupling integrated circuit devices in the reconstituted wafer. In another embodiment, a plurality of electrical interconnects for electrically coupling integrated circuit devices in the reconstituted wafer may be formed in the reconstituted wafer itself.

Abstract: Discussed generally herein are methods and devices including or providing a high density interconnect structure. A high density interconnect structure can include a stack of alternating dielectric layers and metallization layers comprising at least three metallization layers including conductive material with low k dielectric material between the conductive material, and at least two dielectric layers including first medium k dielectric material with one or more first vias extending therethrough, the at least two dielectric layers situated between two metallization layers of the at least three metallization layers, a second medium k dielectric material directly on a top surface of the stack, a second via extending through the second medium k dielectric material, the second via electrically connected to conductive material in a metallization layer of the three or more metallization layers, and a pad over the second medium k dielectric material and electrically connected to the second via.

Abstract: A multi-chip package includes a substrate (110) having a first side (111), an opposing second side (112), and a third side (213) that extends from the first side to the second side, a first die (120) attached to the first side of the substrate and a second die (130) attached to the first side of the substrate, and a bridge (140) adjacent to the third side of the substrate and attached to the first die and to the second die. No portion of the substrate is underneath the bridge. The bridge creates a connection between the first die and the second die. Alternatively, the bridge may be disposed in a cavity (615, 915) in the substrate or between the substrate and a die layer (750). The bridge may constitute an active die and may be attached to the substrate using wirebonds (241, 841, 1141, 1541).

Abstract: Discussed generally herein are methods and devices including or providing a high density interconnect structure. A high density interconnect structure can include a stack of alternating dielectric layers and metallization layers comprising at least three metallization layers including conductive material with low k dielectric material between the conductive material, and at least two dielectric layers including first medium k dielectric material with one or more first vias extending therethrough, the at least two dielectric layers situated between two metallization layers of the at least three metallization layers, a second medium k dielectric material directly on a top surface of the stack, a second via extending through the second medium k dielectric material, the second via electrically connected to conductive material in a metallization layer of the three or more metallization layers, and a pad over the second medium k dielectric material and electrically connected to the second via.

Abstract: An optoelectronic apparatus is presented. In embodiments, the apparatus may include a package including a substrate with a first side and a second side opposite the first side, wherein the first side comprises a ball grid array (BGA) field. The apparatus may further include one or more integrated circuits (ICs) disposed on the first side of the substrate, inside the BGA field, that thermally interface with a printed circuit board (PCB), to which the package is to be coupled, one or more optical ICs coupled to the second side and communicatively coupled with the one or more ICs via interconnects provided in the substrate, wherein at least one of the optical ICs is at least partially covered by an integrated heat spreader (IHS), to provide dissipation of heat produced by the at least one optical IC.