An electromagnetic wave shield film in which peeling off between a metal thin film and an adhesive layer is prevented and a printed wiring board employing the electromagnetic wave shield are provided. An electromagnetic wave shield film is formed by laminating at least a metal thin film and an adhesive layer in order, and the water vapor permeability of the electromagnetic wave shield film according to JISK7129 is 0.5 g/m.sup.2 per 24 hours or higher at a temperature of 80 degrees centigrade, a moisture of 95% RH, and a pressure difference of 1 atm.

A rigid-flex printed circuit board includes an inner circuit substrate, two adhesive sheet layers formed on the inner circuit substrate, two shielding structures, and two outer circuit layers. The inner circuit substrate is divided into a flexible area, a first and second rigid area. Each shielding structure includes a copper layer, a metal seed layer formed on the copper layer, a flexible dielectric layer formed on the metal seed layer, and a backing adhesive sheet layer formed on the flexible medium layer. The backing adhesive sheet layer is pressed on the adhesive sheet layer and the inner circuit substrate located in the flexible area. Each outer circuit layer is formed on the copper layer, located in the first rigid area and the second rigid area and electrically connected to the inner circuit substrate.

A design for printed circuit board with reduced susceptibility to common-mode noise includes a first substrate, a differential pair of signal lines with two differential transmission lines laid on the first substrate, a second substrate, a metal layer located between the first substrate and the second substrate, and a grounding layer The second substrate is located between the second substrate and the grounding layer, and a conductive structure is located in the second substrate and couples the metal layer to the grounding layer. A length of the metal layer is substantially equal to a length of each of the two differential transmission lines.

A printed circuit board is provided. The board includes a plurality of vias through the printed circuit board, each having a first section with a first width, a second section with a second width less than the first width, and a third section with a third width greater than the second width and less than the first width. The second section is located between the first section and the third section, the first and second sections are plated, and the third section lacks plating. At least one of the plurality of vias has the first width dimensioned to receive a connector pin inserted through the first face. A further at least one of the plurality of vias has the first width dimensioned to receive a further connector pin inserted through the second face. Further versions of the printed circuit board and method of making a printed circuit board are provided.

Provided is a ground member that can prevent damage to interlayer adhesion between a conductive layer and an adhesive layer of the ground member due to heating in producing a shielded printed wiring board or in mounting an electronic component on a shielded printed wiring board. The ground member of the present invention includes: a conductive layer; and an adhesive layer stacked on the conductive layer, the adhesive layer containing a binder component and hard particles, the adhesive layer having a thickness of 5 to 30 μm.

A frame includes a plurality of walls each having a first end and a second end facing away from each other along a first direction, and a plurality of spring fingers on the second end of one or more walls of the plurality of walls and extending along the first direction. First ends of the plurality of walls define an open bottom, and second ends of the plurality of walls define an open top.

A DC/DC converter includes a metal case, a power converter accommodated in the case, a substrate, and a temperature sensor mounted on a surface of the substrate. The case includes a bottom wall, a side wall extending from the bottom wall, a boss, and a coupling portion. The coupling portion couples the side wall to the boss. The coupling portion extends from the bottom wall along an axis of the boss and along a surface of the side wall. The temperature sensor is arranged to face the coupling portion.

A method for forming an electronic chip assembly. A first metal plate is coupled to a first side of a substrate to form a backing plate. A first cavity is created extending through the substrate to extend at least to the first metal plate. An electronic component is bonded to the substrate such that the electronic component is located within the first cavity. A second metal plate, having a second cavity, is disposed to a second side of the substrate, and over the first cavity such that the electronic component is encased within the first and second cavities by the first and second metal plates.

According to various aspects, exemplary embodiments are disclosed of board level shields with virtual grounding capability. In an exemplary embodiment, a board level shield includes one or more resonators configured to be operable for virtually connecting the board level shield to a ground plane or a shielding surface. Also disclosed are exemplary embodiments of methods relating to making board level shields having virtual grounding capability. Additionally, exemplary embodiments are disclosed of methods relating to providing shielding for one or more components on a substrate by using a board level shield having virtual grounding capability. Further exemplary embodiments are disclosed of methods relating to making system in package (SiP) or system on chip (SoC) shielded modules and methods relating to providing shielding for one or more components of SiP or SoC module.

The present disclosure relates to a coupler and a base station antenna. The coupler comprises: a first coupling member comprising a first substrate, and a first signal path and a first sub-path of a second signal path located on the first substrate, the first sub-path configured to be at least partially coupled with the first signal path to couple a portion of a signal in the first signal path into the second signal path; a second coupling member vertically stacked with the first coupling member, the second coupling member comprising a second substrate, and a second sub-path of the second signal path located on the second substrate; a shielding member disposed between the first substrate and the second substrate so as to shield the first coupling member and the second coupling member from one another, the shielding member being provided with a first connection through-hole; and a first connection member passing through the first connection through-hole and electrically connected between the first sub-path and the second sub-path.