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.

A printed circuit board is housed in a connector. A temperature sensor is mounted on the printed circuit board between two connection pads located on one of the faces of the printed circuit board. A contact housed in the connector is placed in thermal continuity with two thermal conduction lands, one of which is arranged on the same face of the printed circuit board as the connection pads and the other of which is arranged beneath the temperature sensor. Each of the connection pads is connected to a temperature measurement circuit.

A switching power supply is mounted on a printed circuit board. A first wiring layer of the printed circuit board includes a DC line through which a DC voltage is supplied, and a first ground region and a second ground region formed at a distance from the DC line and with the DC line interposed between them. A lower-layer ground region is formed in a second wiring layer. An insulating layer includes multiple first through holes provided along one side of the first ground region so as to electrically connect the first ground region and the lower-layer ground region, and multiple second through holes provided along one side of the second ground region so as to electrically connect the second ground region and the lower-layer ground region.

A multiple-damascene structure is located below a semiconductor device footprint on a printed wiring board, where the structure includes multiple recesses that containing useful devices coupled to a semiconductive device.

Electronic device fastening systems that enable one or more electronic devices to be reliably and quickly secured on a host board and electronic systems made of the same. In a specific exemplary embodiment, a retainer clip spans across the width of one or more electronic devices, engages with the board and snaps into place. The clip includes one or retaining posts such that when the clip engages the board, the one or more retaining posts align and engage with a predefined mounting feature of a corresponding one of the one or more electronic devices, thereby securing the electronic device in place to restrict horizontal, lateral, and vertical movement of the electronic device.

A package carrier includes a substrate, at least one interposer disposed in at least one opening of the substrate, a conductive structure layer, a first build-up structure, and a second build-up structure. The interposer includes a glass substrate, at least one conductive via, at least one first pad, and at least one second pad. The conductive via passes through the glass substrate, and the first and the second pads are disposed respectively on an upper surface and a lower surface of the glass substrate opposite to each other and are connected to opposite ends of the conductive via. The conductive structure layer is disposed on the substrate and is structurally and electrically connected to the first and the second pads. The first and the second build-up structures are disposed respectively on the first and the second surfaces of the substrate and are electrically connected to the conductive structure layer.

A component carrier includes a stack having at least one electrically conductive layer structure and/or at least one electrically insulating layer structure. A component is embedded in the stack. A first thermally conductive block is located above and thermally connected with the component, and a second thermally conductive block is located below and thermally coupled with the component. Heat generated by the component during operation is removed via at least one of the first thermally conductive block and the second thermally conductive block.

A circuit connection module include a board, an electronic component mounted on the board, and an electrically conductive member connected to the electronic component so as to be thermally conductive. The electronic component includes a heat dissipation portion exposed on an outer surface of the electronic component. The electrically conductive member includes a plate-shaped portion connected to the heat dissipation portion so as to be thermally conductive, and a terminal portion in which one end is connected to the plate-shaped portion so as to be thermally conductive and electrically conductive and the other end is in contact with a mating terminal.

A component carrier includes a stack with at least one electrically insulating layer structure, a structured electrically conductive layer assembled to the stack, where a part of the structured electrically conductive layer is configured as an inductive element, and a magnetic matrix embedded in the stack. The magnetic matrix at least partially surrounds the inductive element. Further, a manufacturing method is described.

A method of manufacturing an item inventory apparatus including an item storage area and a plurality of sensors located within the item storage area may include the steps of: selecting one or more preconfigured boards, each of the one or more preconfigured boards having a plurality of predefined sensor placement locations, providing at least one storage material having a plurality of storage locations for a plurality of items, locating the plurality of sensors at least at some of the plurality of predefined sensor placement locations, and fitting the one or more preconfigured boards with the located plurality of sensors and the storage material to the item storage area. A related system and apparatus are also disclosed.