A memory module mounting apparatus for coupling a memory module to a processor of an information handling system includes a z-axis compression connector and a compression connector mount. The z-axis compression connector has first compression contacts on a first surface of the compression connector and second compression contacts on a second surface of the compression connector. The first compression contacts couple the compression connector to the processor. The compression connector mount has contact pads on a first surface of the compression connector mount. The first contact pads couple the compression connector mount to the first compression contacts, and have contact elements configured to couple the contact pads to the memory module.

Disclosure provides an adapter board and a method for making the adapter board, which includes providing a mold in which a plurality of first fixing plates and second fixing plates are provided, providing a plurality of wires sequentially passed through the plurality of first fixing plates and the second fixing plate, injecting a non-conductive material into the cavity to form a body, and cutting the body along both sides of the first fixing plates and the second fixing plates to obtain a plurality of board bodies. The first fixing plates are provided with a plurality of first fixing holes, and the second fixing plates are provided with a plurality of second fixing holes. The board body includes a first surface and a second surface. A plurality of first connection pads are formed on the first surface, and a plurality of second connection pads are formed on the second surface.

Semiconductor assemblies including thermal management configurations for reducing heat transfer between overlapping devices and associated systems and methods are disclosed herein. A semiconductor assembly may comprise a first device and a second device with a thermally conductive layer, a thermal-insulator interposer, or a combination thereof disposed between the first and second devices. The thermally conductive layer and/or the thermal-insulator interposer may be configured to reduce heat transfer between the first and second devices.

An interposer includes a housing having a plurality of through-holes penetrating a first surface and a second surface and a signal contact pair composed of a pair of signal contacts. Each of the signal contacts includes a base portion press-fitted in one of the through-holes, a first contact beam extending from the base portion beyond the first surface, and a second contact beam extending from the base portion beyond the second surface. The pair of signal contacts are positioned adjacently to each other widthwise and are each asymmetrical with respect to a width direction. The signal contact pair has a plane-symmetrical shape with respect to the width direction.

Panels of LED arrays and LED lighting systems are described. A panel includes a substrate having a top and a bottom surface. Multiple backplanes are embedded in the substrate, each having a top and a bottom surface. Multiple first electrically conductive structures extend at least from the top surface of each of the backplanes to the top surface of the substrate. Each of multiple LED arrays is electrically coupled to at least some of the first conductive structures. Multiple second conductive structures extend from each of the backplanes to at least the bottom surface of the substrate. At least some of the second electrically conductive structures are coupled to at least some of the first electrically conductive structures via the backplane. A thermal conductive structure is in contact with the bottom surface of each of the backplanes and extends to at least the bottom surface of the substrate.

A device comprising a first package and a second package coupled to the first package through a first plurality of solder interconnects. The first package includes a first substrate comprising at least one first dielectric layer and a first plurality of interconnects, and a first integrated device coupled to the first substrate. The second package includes a second substrate comprising at least one second dielectric layer and a second plurality of interconnects, a second integrated device coupled to a first surface of the second substrate, a third integrated device coupled to the first surface of the second substrate through a second plurality of solder interconnects and a first plurality of channel interconnects coupled to the first surface of the second substrate, wherein the first plurality of channel interconnects is located between solder interconnects from the second plurality of solder interconnects.

A coaxial interposer may shield certain signals (e.g., noisy signals, high speed signals, radio frequency (RF) signals) transmitted through an electronic device. The coaxial interposer may include a coaxial via that includes an outer barrel of non-conductive material and an inner barrel of non-conductive material separated by a conductive barrel. Further, the outer barrel of non-conductive material may be enclosed by an outer metal coating. The coaxial via serves to internally shield each signals transmitted between layers of a printed circuit board (PCB) within the electronic device.

A device includes comprising first and second printed circuit boards. Walls couple the first and second printed circuit boards to each other and define a first cavity between the first and second printed circuit boards. Electric conductors associated with the walls electrically connect the the first and second printed circuit boards. An integrated circuit chip is mounted to a first surface of the first integrated circuit board in the first cavity. The integrated circuit chip is electrically connected to conductive tracks of the first surface of the first printed circuit board. Surface-mounted components are mounted on top of and in contact with conductive tracks of a first surface of the second printed circuit board. The first surfaces of the first and second printed circuit boards are arranged facing towards each other. The first and second printed circuit boards may form rigid components of a flex-rigid type printed circuit board.

Methods of manufacture are described. A method includes forming a first cavity in a substrate and placing a backplane in the first cavity. At least one layer of dielectric material is formed over the substrate and the backplane. A second cavity is formed in the at least one layer of the dielectric material to expose at least a portion of a surface of the backplane. A heat conductive material is placed in the second cavity and in contact with the at least the portion of the surface of the backplane.

An electronic device includes a printed circuit board (PCB) that supports an integrated circuit (IC) chip. The device also includes a lid over the IC chip. A thermal interface material (TIM) is configured to transfer thermal energy from the IC chip to the lid. A heat spreader forms a cavity in communication with the lid. The heat spreader is at least partially filled with a liquid that is configured to change phases during operation of the IC chip.