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 package structure includes a metal layer, a composite layer of a non-conductor inorganic material and an organic material, a sealant, a chip, a circuit layer structure, and an insulating protective layer. The composite layer of the non-conductor inorganic material and the organic material is disposed on the metal layer. The sealant is bonded on the composite layer of the non-conductor inorganic material and the organic material. The chip is embedded in the sealant, and the chip has electrode pads. The circuit layer structure is formed on the sealant and the chip. The circuit layer structure includes at least one dielectric layer and at least one circuit layer. The dielectric layer has conductive blind holes. The insulating protective layer is formed on the circuit layer structure. The insulating protective layer has openings, so as to expose parts of the surface of the circuit layer structure in the openings.

Examples are disclosed herein that relate to linear magnetic actuators in camera devices. One example provides a camera device comprising an optical sensor, a lens positioned a variable distance away from the optical sensor, a linear magnetic actuator having a coil and a magnet configured for linear relative movement upon driving of current, and an actuator coupling structure. The actuator coupling structure couples the linear magnetic actuator to the lens, such that the lens moves in response to the movement of the linear actuator.

A method for producing a wiring circuit board includes a first step of preparing a wiring circuit board assembly sheet including a support sheet, a plurality of wiring circuit boards supported by the support sheet, and a joint connecting the support sheet to the plurality of wiring circuit boards, having flat-shaped one surface and the other surface facing one surface at spaced intervals thereto in a thickness direction, and having a thin portion in which the other surface is recessed toward one surface and a second step of forming a burr portion protruding toward the other side in the thickness direction and cutting the thin portion.

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.

The disclosure provides an electronic assembly that includes: a carrier element, a circuit carrier having a number of electronic components, a circuit board, which is electrically conductively connected to the circuit carrier, and a covering element for covering the circuit carrier. The covering element is arranged on one flat side of the circuit board and the carrier element is arranged on an opposite flat side of the circuit board. The circuit board is welded respectively to the carrier element and to the covering element. The disclosure further relates to a method for producing such an electronic assembly.

A medical apparatus having an application device which can be brought into contact with a patient to be treated, and a galvanic isolator which can be connected to the application device, the isolator having at least one application connector for connection to the application device and at least one supply connector for connection to a device. The isolator is configured to galvanically isolate the application connector from the supply connector. The isolator has at least one first radio unit connected to the application connector, and at least one second radio unit connected to the supply connector. The first antenna and second antenna are fixed on a carrier at a visible distance from each other. The at least one first radio unit and the at least one second radio unit are configured to transmit signals and/or data between the application connector and the supply connector.

A method of manufacturing package structure with following steps is disclosed herein. An insulating composite layer is formed on a metal layer of a carrier board. A chip packaging module including a sealant and a first chip embedded therein is disposed on the insulating composite layer, in which the first chip has a plurality of conductive pads. A first circuit layer module including a dielectric layer and a circuit layer is formed on the chip packaging module, in which the circuit layer is on the dielectric layer and electrically connected to the conductive pads through a conductive vias in the dielectric layer. A second chip is disposed on the first circuit layer module. A second circuit layer module is formed on the first circuit layer module and the second chip. A protecting layer is formed on the second circuit layer module.

A wide bandwidth circuit board arrangement includes two coplanar substrates separated by a predetermined gap, and at least one bond wire arranged across the gap and interconnecting a respective conducting microstrip line on a first side of each respective substrate. Further, the arrangement includes at least one open stub arrangement configured on the first side of each respective substrate, each open stub arrangement comprising a microstrip extending at an angle from an end of each conducting strip on each respective substrate. Finally, the arrangement includes a ground layer on a second side of each respective substrate, and a defected ground structure arranged on the second side of each respective substrate and laterally overlapping each respective open stub arrangement arranged on the first side.

An assembly comprises a circuit board structure and a plurality of connection portions. The circuit board structure has a main circuit board and a supplemental circuit board. The main circuit board is formed with an accommodating portion. The accommodating portion is recessed downward in an up-down direction from an upper surface of the main circuit board. The main circuit board has a plurality of upper main conductive portions which are formed on the upper surface of the main circuit board. The supplemental circuit board has a plurality of upper supplemental conductive portions which are formed on an upper surface of the supplemental circuit board. The supplemental circuit board is, at least in part, accommodated in the accommodating portion. Each of ones of the connection portions connects a respective one of the upper main conductive portions and a respective one of the upper supplemental conductive portions with each other.