An electronic device may include one or more radios and one or more antennas. Radio-frequency transmission lines may couple a radio to a corresponding antenna. To more efficiently form a radio-frequency transmission line, the radio-frequency transmission line may be formed from interconnected conductive traces distributed between a plurality of printed circuits. By integrating transmission line structures onto printed circuits that also serve other functions, the device can require less space to implement a radio-frequency transmission line. While one or more of these printed circuits may individually be unsuitable to implement a radio-frequency transmission line with a particular impedance, the composite impedance of these transmission line structures across the printed circuits, when properly configured, may provide a radio-frequency transmission line with the particular impedance.

According to an embodiment, an electronic device is provided. the electronic device may comprise: a housing including a conductive portion and a non-conductive portion; a first substrate; at least one electronic component disposed on the first substrate; a second substrate electrically coupled to the first substrate, the second substrate including a first surface facing a first direction and a second surface facing a second direction opposite to the first direction; at least one contact member disposed between the first surface of the second substrate and the conductive portion of the housing; and a support member disposed between the first surface of the second substrate and the non-conductive portion of the housing.

Disclosed is a flexible PCB RF cable having a ground pattern that is divided into two ground patterns, which are connected through a connection pattern arranged in an area overlapped with a signal line pattern, and thus cracks are minimized during bending. The disclosed flexible PCB RF cable comprises: a signal line pattern interposed between a first dielectric sheet and a second dielectric sheet; first and second lower ground patterns, which are mesh patterns arranged to be spaced from each other below the first dielectric sheet; a lower connection pattern connected to the first and second lower ground patterns; first and second upper ground patterns, which are mesh patterns arranged to be spaced from each other above the second dielectric sheet; and an upper connection pattern connected to the first and second ground patterns.

A die package structure and a method for fabricating the same are provided. The method includes: fixing a first die on a package base; aligning first hollow pads of a flexible printed circuit board with first pads of the first die, and fixing the flexible printed circuit board; soldering the first hollow pads to the first pads; fixing a second die on the flexible printed circuit board to overlap with the first die; folding the flexible printed circuit board, such that second hollow pads of the flexible printed circuit board are aligned with second pads of the second die, and signal test pads of the flexible printed circuit board are exposed; fixing the flexible printed circuit board on the second die; soldering the second hollow pads to the second pads; soldering metal wires to the signal test soldering pads; and soldering package pins to the metal wires.

A printed board includes a main printed board, and a flexible printed board fixed to the main printed board. The flexible printed board includes a box part formed in a box shape whose main printed board side is opened and a fixed part extended to an outer side and fixed to the main printed board. The flexible printed board is formed with a plurality of tamper detection patterns for detecting at least one of disconnection of the tamper detection pattern itself and a short circuit with other tamper detection pattern. An internal land of the tamper detection pattern is connected with the main printed board and is disposed on an inner side of the box part, an external land of the tamper detection pattern is formed in the fixed part and is fixed to and connected with the main printed board, and the external lands are insulated from each other.

A rigid-flex board is manufactured by attaching multiple self-adhesive copper foil films to a flexible circuit board through multiple build-up processes, thereby eliminating the need to pre-fabricate a rigid board and slot the rigid board. The build-up processes of the self-adhesive copper foil films allow the resulting rigid boards to be highly uniform in thickness so that thickness deviation of the rigid-flex board can be reduced.

The disclosure relates to a rigid-flexible printed circuit board and an electronic device including same. The electronic device may include: a housing; a first module disposed in one region of the housing; a second module disposed in an other region of the housing and spaced apart from the first module; and a rigid-flexible printed circuit board electrically connecting the first module and the second module, wherein the rigid-flexible printed circuit board includes: a rigid region; a flexible region coupled to the rigid region, wherein a part of the flexible region overlaps the rigid region; and a protective layer laminated on at least one of an upper end or a lower end of the flexible region to cover at least a part of a coupling portion of the rigid region and the flexible region by a designated numerical value, the coupling portion having a tensile strength equal to or greater than a designated strength based on the flexible region being bent. Various other embodiments are possible.

A metal stem includes a cylindrical portion in which an FPC inserting portion is formed, and a base standing upright from one plane of the cylindrical portion. A tubular lens cap with one open end is fixed to a peripheral portion of the one plane of the cylindrical portion, and has a lens mounted on a bottomed portion. A substrate mounted on one plane of the base includes a signal wiring layer and a ground wiring layer. An optical semiconductor element is mounted on the substrate and has a signal terminal connected to the signal wiring layer of the substrate, and a ground terminal connected to the ground wiring layer of the substrate. An FPC substrate is disposed so as to pass through the FPC inserting portion and to face the one plane of the base. The FPC substrate includes a signal wiring layer connected to the signal wiring layer of the substrate with a metal wire.

A display device includes a display panel including a pixel part to display an image, and a pad part connected to the pixel part; a first flexible circuit film coupled to the pad part and including a first alignment mark; and a second flexible circuit film coupled to the pad part, overlapping the first flexible circuit film, and including a second alignment mark aligned with the first alignment mark. The first and second alignment marks are located in an area where the first flexible circuit film overlaps the second flexible circuit film.

The present disclosure provides a flexible display module and a method for manufacturing the flexible display module. The flexible display module includes a flexible display panel, a driving chip and a circuit board. The flexible display panel includes a display region and a bonding region, and the driving chip and the circuit board are arranged at the bonding region. The circuit board includes a first flexible printed circuit and a first printed circuit board provided with an electronic element, the first printed circuit board is coupled to one end of the first flexible printed circuit, and the first flexible printed circuit includes a bonded portion coupled to the bonding region of the flexible display panel. The first flexible printed circuit is bent so that a first space is defined by the first flexible printed circuit, the first printed circuit board and the flexible display panel.