A through connector device is disclosed. The device may include a coaxial cable receiver portion defined by one or more surfaces, the coaxial cable receiver portion configured to couple to a center conductor portion of a coaxial cable, the center conductor portion of the coaxial cable protruding above a dielectric material of the coaxial cable. The device may include a beam lead positioned adjacent to the coaxial cable receiver portion. The device may include a planar transmission line contact pad configured to make electrical contact with a planar transmission line of a printed circuit board. The device may include a step configured to electrically and mechanically couple the beam lead to the planar transmission line contact pad, the step configured to create a gap between a bottom surface of the beam lead and a top surface of an outer conductor portion of the coaxial cable.

A rotary encoder is incorporated in an annular space formed between a hollow rotating shaft and an encoder case. The rotary encoder has an annular printed wiring substrate, a plurality of mounting substrates that are outward from the printed wiring substrate in the radial direction and are arranged in the circumferential direction, and inter-substrate wiring cables bridged between the printed wiring substrate and each of the mounting substrates in the radial direction. Power supply to the mounting substrates and signal transmission and reception between the mounting substrates can be accomplished without routing around the wiring cables. It is possible to achieve a rotary encoder that is suitable for being incorporated in a narrow annular space.

Embodiments presented in this disclosure generally relate to techniques for interconnecting integrated circuits. More specifically, embodiments disclosed herein provide a back mounted interposer (BMI) to facilitate interconnecting of integrated circuits. One example apparatus includes an integrated circuit, an interposer, and a circuit board, at least a portion of the circuit board being disposed between the integrated circuit and the interposer, where the circuit board is configured to provide electrical connection between the interposer and the integrated circuit via connection elements on a first surface of the interposer. The apparatus also includes an interface on a second surface of the interposer, the interface being configured to provide signals from the integrated circuit to an electrical component.

In an electrical device, a model series of electrical devices, and a production method, in particular for a converter, having a circuit board including circuit traces, the circuit board has two similar and/or identical contact area arrays, the contact area arrays in particular transitioning into each other through rotation and/or displacement. A first contact area array of the contact area arrays is fitted with a first power module, and the second contact area array is able to be fitted with a second power module, e.g., so that a respective electric motor is able to be supplied from the respective power module.

An electronic circuit module includes: a substrate on which a wiring pattern having an electrode portion is formed; a cable having an external insulator and a conductor portion, at least a distal end side of the external insulator being removed to expose a conductor, an exposed portion of the conductor being defined as the conductor portion; and an electronic component having terminals at least on two opposed faces of the electronic component. At least one of the terminals of the electronic component is directly connected to the conductor portion, and is configured to be electrically connected to the electrode portion through the conductor portion.

A communication system includes a circuit board assembly including a mating circuit board having a mating edge and a plurality of mating pads at the mating edge, the circuit board assembly having an electrical component electrically coupled to the mating circuit board. The communication system includes a cable receptacle connector removably coupled to the mating edge of the mating circuit board. The cable receptacle connector includes a connector housing having a connector cavity and a card slot. A cable extends from the connector housing. The cable receptacle connector includes signal contacts each having a mating end mated with the corresponding mating pads and a terminating end electrically connected to a cable conductor of the cable.

An electrical device heat dissipation structure includes an air blowing device, a casing, and a mating connector. The casing is disposed with at least one air outlet, an electrical connector and a power supply. The power supply provides power to the air blowing device. The mating connector has a chip. The mating connector is electrically connected with the electrical connector. The air blowing device is configured to blow air to the mating connector through the at least one air outlet, so as to improve dissipation of heat generated by the chip at work, and to reduce a temperature of the mating connector.

A heat sink assembly includes a casing having an opening, a main board accommodated in the casing, a heat sink mounted on the main board, an electrical connector mounted on the main board and exposed in the opening, a mating connector located outside the casing and connected to the electrical connector through the opening in a plugging manner, and a heat conductor, disposed inside the casing. The mating connector has a chip that is electrically connected to the electrical connector. One end of the heat conductor is connected to the heat sink, and the other end of the heat conductor is thermally connected to the electrical connector or the mating connector, so that heat generated by the chip during working can be transferred to the heat sink through the heat conductor, thereby reducing a temperature of the mating connector.

The present disclosure relates to an electronic device (10) comprising at least one electrically conductive structure (11) with a tubular shape having outer and inner surfaces (11c, 11d) covered by an insulating layer (12), and one or more integrated circuits (13) positioned within the electrically conductive structure (11).

A cable assembly, a signal transmission structure, and an electronic device are provided. The signal transmission structure includes a circuit board (2), a chip (1), and a cable assembly (3). The chip (1) is assembled on one side of the circuit board (2), and the cable assembly (3) is assembled on the other side of the circuit board (2). The cable assembly (3) includes a cable (31), and the circuit board (2) includes a plurality of conductive holes (22). The chip (1) is electrically connected to the cable (31) of the cable assembly (3) by using the conductive hole (22), to transmit a signal of the chip (1) by using the cable (31). In this technical solution, wires do not need to be disposed in a large area inside the circuit board (2).