A connector assembly includes multiple terminals. Each terminal includes a conductive portion. The terminals include first and second high speed signal terminals and a low speed signal terminal. The conductive portions of the first and second high speed signal terminals and the low speed signal terminal are correspondingly defined as first, second and third conductive portions. An adapter board is located above a circuit board to be conductively connected to a cable directly or indirectly. The adapter board includes first and second signal circuit layers located at different heights. The first signal circuit layer includes a first high speed signal circuit conductively connecting the first conductive portion and a conductive wire of the cable. The second signal circuit layer includes a second high speed signal circuit conductively connecting the second conductive portion and another conductive wire of the cable. The third conductive portion is conductively connected to the circuit board.

An electric component includes: a semiconductor component including a heat radiating portion, a semiconductor element, a lead terminal, and a coating resin coating a part of each of the above; a wiring board including a first mounting portion, a second mounting portion, and an insulating substrate; a first solder connecting the first mounting portion and the heat radiating portion; and a second solder connecting the second mounting portion and the lead terminal. The first solder includes (a) a solder connecting portion connecting the heat radiating portion and the first mounting portion and (b) a flux provided around the solder connecting portion, and a third space which is provided as a space after excluding a second space that is an overlap of the heat radiating portion and the first mounting portion from a first space.

A flexible printed circuit board including an electronic component includes a flexible printed circuit board, an electronic component, a cover, and a restricting portion. The printed circuit board including an electrically conductive line. The electronic component is mounted on the flexible printed circuit board and joined to the electrically conductive line. The cover covers a joint between the electronic component and the electrically conductive line. The restricting portion is along an outer edge of the cover. The flexible printed circuit board includes a groove along the outer edge of the cover. The groove is defined by opposed groove side surfaces. One of the opposed groove side surfaces farther from the electronic component is defined as the restricting portion.

The present disclosure generally relates to a scalable computer circuit board having a first power level semiconductor package coupled to at least one base-level voltage regulator module, which is coupled to a plurality of connection receptacles that are configured for connecting with a voltage regulator module positioned on a second level, as a standardized base unit. To scale the base unit, a second power level semiconductor package may be exchanged for the first power level semiconductor package in conjunction with one or more voltage regulator module board being positioned over a corresponding number of base-level voltage regulator modules and coupled to their plurality of connection receptacles.

An electrical connector assembly includes a carrier having an upper surface and a lower surface. The carrier includes a plurality of contact openings therethrough. The electrical connector assembly includes contacts coupled to the carrier and passing through the corresponding contact openings. Each contact has a conductive polymer column extending between an upper mating interface and a lower mating interface. The conductive polymer column includes an inner core manufactured from a first material and an outer shell manufactured from a second material. The second material has a higher electrical conductivity than the first material. The first material has a lower compression set than the second material.

Devices and methods are described for reducing etching due to galvanic effect within a printed circuit board that may be used, for example, in a data storage device, such as a card-type data storage device. Specifically, a contact trace is coupled to a contact finger that has a substantially larger surface area than the contact trance, and that is configured to couple the data storage device to a host device. The contact trace is electrically isolated from the rest of the circuitry during a fabrication process. The contact finger and an exposed portion of the contact trace are plated with a common material to reduce galvanic etching of the contact trace during fabrication. The contact trace is then connected to an impedance trace though at least one of a component and a bond wire.

An electrical apparatus is provided with a power semiconductor module, at least one capacitor, a circuit carrier, and a first heat sink. The power semiconductor module and the circuit carrier are arranged on the first heat sink. The electrical apparatus comprises a second heat sink arranged on the power semiconductor module and connected to the first heat sink.

An electronic device includes an interposer substrate including a substrate body that includes a first principal surface and a second principal surface, a first surface terminal electrode that is provided on the first principal surface and includes a terminal electrode for heat dissipation and a terminal electrode for external connection, a second surface terminal electrode that is provided on the second principal surface, a conductor for signal transmission that is provided on the substrate body and connects the terminal electrode for external connection and the second surface terminal electrode, and a conductor for heat conduction that is provided on the substrate body and connects the terminal electrode for external connection or the second surface terminal electrode to the terminal electrode for heat dissipation.

The present disclosure provides a semiconductor module comprising a semiconductor device removably pressed-fit in a cavity formed in a printed circuit board and methods for manufacturing the same. The semiconductor device and the cavity of the printed circuit board can cooperate with each other and act as an electrical plug and an electrical socket respectively. Soldering the semiconductor device on the printed circuit board can be avoided. Therefore, the packaging process can be more flexible and reliability issues with solder joints can be eliminated. Moreover, heatsink can be mounted on top and/or bottom of the semiconductor device after being received in the cavity of the printed circuit board. Thermal dissipation efficiency can be greatly enhanced.

The present disclosure includes an adjustable circuit board assembly including a circuit board, a header connected to the circuit board, and a matrix connector. The header may be configured for connection with the circuit board via a connection matrix and the matrix connector. A method of manufacturing a circuit board assembly may include providing a circuit board, providing a terminal header having a plurality of terminals, providing a connection matrix to at least one of the circuit board and the terminal header, providing a matrix connector, connecting the terminal header with the circuit board via the matrix connector and the connection matrix, and connecting the plurality of terminals to the circuit board.