An electronic module includes at least one electronic component including a first principal surface, first and second electrodes on the first principal surface, a wiring board including a second principal surface, third and fourth electrodes on the second principal surface, and a conductive resin portion. The conductive resin portion includes at least one first conductive resin portion joining the first and third electrodes, and at least one second conductive resin portion joining the second and fourth electrodes. The electronic module further includes at least one reinforcing resin portion that is disposed between at least one first and at least one second conductive resin portions and joins the first principal surface of the electronic component with the second principal surface of the wiring board.

A first circuit board includes a positive output pin and a negative output pin of a power conversion circuit, each of which has a shape projecting from a second main surface. A second circuit board has a positive through via and a negative through via, each of which has a shape extending between a third main surface and a fourth main surface. The second main surface of the first circuit board and the third main surface of the second circuit board are physically in close contact with each other. The positive output pin is inserted through the positive through via to reach the fourth main surface. The negative output pin is inserted through the negative through via in such a manner as to reach the fourth main surface. The load receives a current supplied from the power conversion circuit through the positive output pin and the negative output pin.

An electronic device includes: a first printed circuit board (PCB) including a first plate and a first hole formed in the first plate, a second PCB including a second plate, an interposer including a third plate positioned between the first plate and the second plate, a plurality of first vias connecting the first plate and the third plate, a plurality of second vias connecting the second plate and the third plate, and a first reinforcement portion positioned in the first hole to bond the first plate and the third plate.

A component carrier includes a stack with an electrically conductive layer structure and an electrically insulating layer structure. The electrically conductive layer structure having a first plating structure and a pillar. The pillar has a seed layer portion on the first plating structure and a second plating structure on the seed layer portion. A method of manufacturing such a component carrier and an arrangement including such a component carrier are also disclosed.

A voice-controlled electronic device that includes a device housing having a longitudinal axis bisecting opposing top and bottom surfaces and a side surface extending between the top and bottom surfaces. The device can further include one or more microphones disposed within the device housing and distributed radially around the longitudinal axis; a processor configured to execute computer instructions stored in a computer-readable memory for interacting with a user and processing voice commands received by the one or more microphones and first transducer and second transducers configured to generate sound waves within different frequency ranges.

Embodiments may include inductors with embedded magnetic cores and methods of making such inductors. In an embodiment, an integrated circuit package may include an integrated circuit die with a multi-phase voltage regulator electrically coupled to the integrated circuit die. In such embodiments, the multi-phase voltage regulator may include a substrate core and a plurality of inductors. The inductors may include a conductive through-hole disposed through the substrate core and a plugging layer comprising a dielectric material surrounding the conductive through-hole. In an embodiment, a magnetic sheath is formed around the plugging layer. In an embodiment, the magnetic sheath is separated from the plated through hole by the plugging layer. Additionally, a first layer comprising a dielectric material may be disposed over a first surface of the magnetic sheath, and a second layer comprising a dielectric material may be disposed over a second surface of the magnetic sheath.

An electronic device is provided. The electronic device includes a first substrate on which a first electrical element and a first conductive structure, which is configured to surround the first electrical element, are disposed, a second substrate on which a second electrical element and a second conductive structure, which is separably connected to the first conductive structure, are disposed, and a connector which is disposed between the first substrate and the second substrate and electrically connects the first electrical element to the second electrical element.

The present disclosure provides an adapter board, a for manufacturing the same and a circuit board assembly. The adapter board includes a board body, a first component buried in the board body, a first connector located on a first surface of the board body and configured to be connected with a circuit board and a second component, a second connector located on a second surface of the board body and configured to be connected with a second component, a first conductive body and a second conductive body buried in the board body. One end of the first conductive body is connected with the first component. The other end of the first conductive body is connected with the first connector. One end of the second conductive body is connected with the first component. The other end of the second conductive body is connected with the second connector

Memory on Package (MOP) apparatus with reverse CAMM (Compression Attached Memory Module) and compression mount technology (CMT) connector(s). The MOP includes a first (MOP) substrate to which one or more CPUs, SoC, and XPUs that is operatively coupled to one or more CAMMs with a CMT connector(s) disposed between an array of CMT contact pads on the CAMM substrate and an array of CMT contact pad on the substrate. The one or more CAMMs are include multiple memory chips or packages such as LP DDR chips or DDR (S)DRAM chips/packages mounted to an underside of the CAMM substrate via signal coupling means such as a ball grid array (BGA), where the CAMM orientation is inverted such that the memory chips/packages are disposed downward, resulting in a reduced Z-height of the MOP. A MOP may include two CAMMs with a respective CMT connector disposed between the CAMM substrates and the MOP substrate.

Methods and apparatus for GDDR (Graphics Double Date Rate) memory expander using compression mount technology (CMT) connectors. A CMT connector with a dedicated pinout for GDDR-based memory is provided that enables end users and manufacturers to change the amount of GDDR memory provided with a GPU card, accelerator card, or apparatus having other form factors. Memory could also be replaced in the event of a failure. In addition, embodiments are disclosed that support a split channel concept where there could be multiple devices (e.g., GDDR modules) with dedicated signals routed to each module.