Abstract: Disclosed herein is a multi-planar circuit board, as well as related structures and methods. In an embodiment, a circuit board may include a first surface, a first section having the first surface in a first plane, a second section having the first surface in a second plane, and a third section connecting the first and second sections, where the third section defines a gradient between the first and second planes, and where all sections are sections within a contiguous board. In another embodiment, circuit board may further include a first component having a first thickness coupled on the first face of the first section, and a second component having a second thickness, greater than the first component, coupled on the first face of the second section, where the second section is in a lower plane, and where the overall thickness is the circuit board thickness plus the second thickness.

Abstract: According to the present disclosure, a laptop may be provided with a compartment including a moveable segment, an expandable heat exchanger with a movable section, and an expandable fan unit. The release of the movable segment of the compartment from a lower portion of the compartment produces an opening in the compartment and the movable section of the expandable heat exchanger is extended downward, and the expandable fan unit is lowered when the movable segment of the compartment is released.

Abstract: A capacitor loop substrate assembly may include a substrate with a loop shape, one or more capacitors or other electronic components on the substrate, and an opening in the substrate to allow the capacitor loop substrate assembly to be coupled to an integrated circuit package, such as a package including a die. Interconnects and/or contacts for interconnects may be formed in an integrated circuit package to couple the capacitor loop substrate assembly to the integrated circuit package.

Abstract: Techniques for power tunnels on circuit boards are disclosed. A power tunnel may be created in a circuit board by drilling through non-conductive layers to a conductive trace and then filling in the hole with a conductor. A power tunnel can have a high cross-sectional area and can carry a larger amount of current than an equivalent-width trace, reducing the area on a circuit board required to carry that amount of current.

Abstract: A capacitor loop substrate assembly may include a substrate with a loop shape, one or more capacitors or other electronic components on the substrate, and an opening in the substrate to allow the capacitor loop substrate assembly to be coupled to an integrated circuit package, such as a package including a die. Interconnects and/or contacts for interconnects may be formed in an integrated circuit package to couple the capacitor loop substrate assembly to the integrated circuit package.

Abstract: Embodiments described herein may be related to apparatuses, processes, and techniques related to a shielding layer to be inserted under an inductor footprint to mitigate the impact of electromagnetic interference (EMI) onto electrical traces beneath the shielding layer and under the inductor footprint. In embodiments, the electrical traces may be high-speed input/output (HSIO) traces that may be particularly susceptible to data corruption given the level of EMI. In embodiments, the shielding layer may be a high density metallization shield within dielectric stack-up layers. In embodiments, these layers may use unique via patterns or shaped metal preform shields to enable routing under an inductor at a higher layer of the PCB. Other embodiments may be described and/or claimed.

Abstract: Semiconductor packages and a method of forming a semiconductor package are described. The semiconductor package has a foundation layer mounted on a motherboard. The semiconductor package also includes a hole in motherboard (HiMB) that is formed in the motherboard. The semiconductor package has one or more capacitors mounted on an electrical shield. The electrical shield may be embedded in the HiMB of the motherboard. Accordingly, the semiconductor package has capacitors vertically embedded between the electrical shield and the HiMB of the motherboard. The semiconductor package may also have one or more HiMB sidewalls formed on the HiMB, where each of the one or more HiMB sidewalls includes at least one or more plated through holes (PTHs) with an exposed layer. The PTHs may be electrically coupled to the capacitors as the capacitors are vertically embedded between the electrical shield sidewalls and the HiMB sidewalls (i.e., three-dimensional (3D) capacitors).

Abstract: An electronic device may include a chassis. The electronic device may include a first electronic component that may include a first substrate and a first interconnect. The electronic device may include a second electronic component that may include a second substrate and a second interconnect. The second substrate may be physically separated from the first substrate. An electrical trace may be coupled to the chassis of the electronic device. The electrical trace may be sized and shaped to interface with the first interconnect of the first electronic component. The electrical trace may be sized and shaped to interface with the second interconnect of the second electronic component. The first electronic component and the second electronic component may be in electrical communication through the electrical trace coupled to the chassis of the electronic device.

Abstract: A folded circuit board includes a first circuit board and a second circuit board. The first circuit board and second circuit board are coupled together through a flexible interconnect. One or more folding guides are coupled to one of the first circuit board or second circuit board. The one or more folding guides extend beyond a first edge of the one of the first circuit board or second circuit board. The one or more folding guides include a curved sidewall configured to guide the flexible interconnect when the first circuit board is folded over the second circuit board. In one embodiment, the one or more folding guides are grounded to reduce EMI emissions.

Abstract: An electronic device and associated methods are disclosed. In one example, the electronic device includes a first rigid substrate, a second rigid substrate, a flexible substrate comprising a first portion attached to the first rigid substrate, a second portion attached to the second rigid substrate, a middle portion connecting the first portion to the second portion, wherein the middle portion is bent, and metallic traces therethrough, and a component forming a direct interface with the middle portion of the flexible substrate, the component electrically coupled to the metallic traces. In selected examples, the device further includes a casing.

Abstract: To address the issue of shrinking volume that can be allocated for electrical components, a system can use an interposer with a flexible portion. A first portion of the interposer can electrically connect to a top side of a motherboard. A flexible portion of the interposer, adjacent to the first portion, can wrap around an edge of the motherboard. A peripheral portion of the interposer, adjacent to the flexible portion, can electrically connect to a bottom side of the motherboard. The peripheral portion can be flexible or rigid. The interposer can define a cavity that extends through the first portion of the interposer. A chip package can electrically connect to the first portion of the interposer. The chip package can be coupled to at least one electrical component that extends into the cavity when the chip package is connected to the interposer.

Abstract: A system for board-to-board interconnect is described herein. The system includes a first printed circuit board (PCB) having a first recess along a first edge of the first PCB that exposes a first solder pad on a layer of the first PCB. The system also includes a second PCB having a second recess along a second edge of the second PCB that exposes a second solder pad on a layer of the second PCB. The second recess is complementary to the first recess to allow the first PCB to mate with the second PCB. The first solder pad is aligned with the second solder pad when the first PCB is mated with the second PCB. The system additionally includes an assembly configured to electronically couple the first solder pad with the second solder pad.

Abstract: A substrate may be included in an electronic device. The substrate may include a first layer that may include a dielectric material. The first layer may define a substrate surface. The substrate may include a second layer optionally including the dielectric material. The second layer may be coupled to the first layer. A wiring trace may be located in the substrate. A recess may extend through the substrate surface, the first layer, and may extend through the second layer. A substrate interconnect may be located within the recess. The substrate interconnect may be at least partially located below the substrate surface. The substrate interconnect may be in electrical communication with the wiring trace.

Abstract: Apparatus and method for providing an electromagnetic interference (EMI) shield for removable engagement with a printed circuit board (PCB). A shaped electrically conductive member has a substantially planar member portion with multiple lateral member edges. The sidewalls are disposed at respective lateral member edges and are substantially orthogonal to the substantially planar member portion. At least one of the sidewalls includes at least one first snap-fit latching feature to engage a respective complementary second snap-fit latching feature disposed at one or more of multiple peripheral portions of a PCB.

Abstract: To address the issue of shrinking volume that can be allocated for electrical components, a system can use an interposer with a flexible portion. A first portion of the interposer can electrically connect to a top side of a motherboard. A flexible portion of the interposer, adjacent to the first portion, can wrap around an edge of the motherboard. A peripheral portion of the interposer, adjacent to the flexible portion, can electrically connect to a bottom side of the motherboard. The peripheral portion can be flexible or rigid. The interposer can define a cavity that extends through the first portion of the interposer. A chip package can electrically connect to the first portion of the interposer. The chip package can be coupled to at least one electrical component that extends into the cavity when the chip package is connected to the interposer.

Abstract: A system for board-to-board interconnect is described herein. The system includes a first printed circuit board (PCB) having a first recess along a first edge of the first PCB that exposes a first solder pad on a layer of the first PCB. The system also includes a second PCB having a second recess along a second edge of the second PCB that exposes a second solder pad on a layer of the second PCB. The second recess is complementary to the first recess to allow the first PCB to mate with the second PCB. The first solder pad is aligned with the second solder pad when the first PCB is mated with the second PCB. The system additionally includes an assembly configured to electronically couple the first solder pad with the second solder pad.

Abstract: In embodiments, a device may include a single electromagnetic interference (EMI) shield plate that defines an enclosed area. The EMI shield plate may have an inner surface and an outer surface opposite the inner surface. The device may further include a first printed circuit board (PCB) coupled with the inner surface, wherein the first PCB is within the enclosed area. Other embodiments may be described and/or claimed.

Abstract: To address the issue of shrinking volume that can be allocated for electrical components, a system can use an interposer with a flexible portion. A first portion of the interposer can electrically connect to a top side of a motherboard. A flexible portion of the interposer, adjacent to the first portion, can wrap around an edge of the motherboard. A peripheral portion of the interposer, adjacent to the flexible portion, can electrically connect to a bottom side of the motherboard. The peripheral portion can be flexible or rigid. The interposer can define a cavity that extends through the first portion of the interposer. A chip package can electrically connect to the first portion of the interposer. The chip package can be coupled to at least one electrical component that extends into the cavity when the chip package is connected to the interposer.

Abstract: Semiconductor packages and a method of forming a semiconductor package are described. The semiconductor package has a foundation layer mounted on a motherboard. The semiconductor package also includes a hole in motherboard (HiMB) that is formed in the motherboard. The semiconductor package has one or more capacitors mounted on an electrical shield. The electrical shield may be embedded in the HiMB of the motherboard. Accordingly, the semiconductor package has capacitors vertically embedded between the electrical shield and the HiMB of the motherboard. The semiconductor package may also have one or more HiMB sidewalls formed on the HiMB, where each of the one or more HiMB sidewalls includes at least one or more plated through holes (PTHs) with an exposed layer. The PTHs may be electrically coupled to the capacitors as the capacitors are vertically embedded between the electrical shield sidewalls and the HiMB sidewalls (i.e., three-dimensional (3D) capacitors).

Abstract: Apparatus and method for providing an electromagnetic interference (EMI) shield for removable engagement with a printed circuit board (PCB). A shaped electrically conductive member has a substantially planar member portion with multiple lateral member edges. The sidewalls are disposed at respective lateral member edges and are substantially orthogonal to the substantially planar member portion. At least one of the sidewalls includes at least one first snap-fit latching feature to engage a respective complementary second snap-fit latching feature disposed at one or more of multiple peripheral portions of a PCB.