A module includes a substrate having a first surface, components as one or more components mounted on the first surface, a resin film covering the one or more components along a shape of the one or more components and covering part of the first surface, a first shield film formed to overlap the resin film, and a first sealing resin as a sealing resin disposed to cover the first surface, the one or more components, and the first shield film. A stack including the resin film and the first shield film has a first opening. A first columnar conductor is disposed to be electrically connected to the first surface through the first sealing resin and the first opening. The first shield film is electrically connected to the first columnar conductor in the first opening.

A module includes: a substrate having a first surface; a first component mounted on the first surface; a resin film that covers the first component along a shape of the first component, and also covers a part of the first surface; a conductor film that covers at least a part of the resin film along the shape of the first component, and covers at least a part of a portion in which the resin film covers the part of the first surface; and a conductor structure disposed to extend over a part of the resin film. The conductor structure includes a first end portion, a second end portion, and an intermediate portion. The first end portion and the second end portion are connected to the first surface. The intermediate portion is in contact with the conductor film.

Various embodiments of the disclosure relate to a printed circuit for transmitting a signal in a high-frequency band and an electronic device including the same. The printed circuit board may include a flexible circuit board configured to transmit a signal in a high-frequency band, and the flexible circuit board may include: first multiple layers including a power line configured to transmit power; and second multiple layers stacked in a first direction of the first multiple layers and including a first signal line and a second signal line configured to transmit a signal in the high-frequency band. The first multiple layers may include a first punched region in which at least a portion overlapping the first signal line and the second signal line is removed, the second multiple layers may include a second punched region in which at least a portion overlapping the power line is removed, and at least a portion of the second punched region and the first punched region overlap each other forming a slit penetrating the flexible circuit board in the first direction.

A circuit member joint structure includes a first circuit member including a first main surface on which a first mounting electrode is provided, a second circuit member including a second main surface on which a second mounting electrode is provided, a conductive joining material with which the first mounting electrode and the second mounting electrode are joined to each other, and an insulating joining material with which an end portion of the first circuit member and an end portion of the second circuit member are joined to each other. The first circuit member includes a first recess on the first main surface and spaced away from the first mounting electrode, and at least a portion of the insulating joining material is disposed in the first recess.

A circuit board may include a first signal via electrically coupled to multiple layers of the circuit board, a second signal via electrically coupled to multiple layers of the circuit board, and a pair of ground vias configured to provide electrical shielding between the first signal via and the second signal via, the pair of ground vias comprising a first ground via electrically coupled to a ground or power plane of the circuit board and a second ground via electrically coupled to the ground or power plane of the circuit board. The first signal via, the first ground via, and the second ground via may be arranged such that they form an angle of approximately 50 degrees having a vertex at the first signal via, a first ray extending from the first signal via through the first ground via and a second ray extending from the first signal via through the second ground via.

Disclosed is a portable communication device including a housing, a first printed circuit board (PCB) disposed in the housing, a wireless communication circuit mounted on the first PCB, and a second PCB including a connection part connected with the first PCB, a first PCB portion extended from the connection part and having greater flexibility than the connection part, a second PCB portion extended from the first PCB portion and having less flexibility than the first PCB portion, a third PCB portion extended from the second PCB portion and having greater flexibility than the second PCB portion, a fourth PCB portion extended from the third PCB portion and having less flexibility than the first PCB portion, a signal line extended to the connection part along the first, second, third, and fourth PCB portions, and vias arranged in at least a partial area of the second PCB portion or the fourth PCB portion, wherein a portion of the signal line is located between some of the vias.

A connector port module and a method of manufacturing the same. The connector port module includes a circuit board, with a connector having a plurality of connector pads formed on the circuit board configured to electrically connect to a mating connector. At least one via hole is formed in the circuit board for reinforcing the physical integrity and the heat diffusivity of the circuit board. The connector port module is capable of supporting Universal Serial Bus (USB) (e.g. USB-C) and Thunderbolt 3 connectors. The method includes: providing a circuit board; forming a plurality of connector pads on the circuit board configured to electrically connect to a mating connector; and forming at least one via hole for reinforcing physical integrity of the circuit board.

An electronic device including a housing; a printed circuit board (PCB) in the housing, wherein the PCB includes a plurality of layers with one or more conductive and insulation layers; a first electrical component formed as at least a part of or in the housing; a second electrical component above or near the PCB in the housing, wherein the first and second electrical components are separated; and at least one electrical path extending from the first electrical component to the second electrical component, wherein at least a portion of the electrical path runs on or inside the PCB, wherein the PCB includes a region including a pattern of conductive vias, wherein each of the vias extends through at least part of the plurality of layers to contact at least one of the one or more conductive layers, and wherein the electrical path runs through the region without contacting the vias.

An electrical contact pad for electrically contacting a connector includes first, second and third regions. The first region is connected to a trace. The second region is adjacent to the first region and has a width less than the first region. The third region is adjacent to the second region and has a width that is greater than the second region. The third region is sized to make contact with a connector. Having the width of the second region be smaller than the width of the first and third regions increases an impedance of the electrical contact pad.

A planar multi-layer assembly method fabricates a dual frequency, dual polarization phased-array antenna. A plurality of vias make up an array of double-walled wells which are connected to a ground plane. A shorted annular ring patch antenna (SARPA) is deposited at the top of each double-walled well. Fabricated coaxially and parallel to each SARPA, is an array of circular patch antennas (CPA). The inner wall of each double-walled well improves isolation of the CPA signals from the SARPA signals. Each SARPA of the array is connected to a pair of first frequency band signal vias and the CPA is coupled to a pair of second frequency band signal vias. Within each frequency band, a plurality of signal phases enable steerable polarized antenna beams.