A printed circuit board (100), PCB, comprises a top surface (101), a bottom surface (107), a series of M castellated orifices (102) on at least one of the edges of the PCB, and a series of N conductive pads (103) on the top surface (101) connecting to the M orifices (102) at respective connection edges (104), wherein M and N are integers greater than 1. Each of the pads (103) on the top surface (101) is partially covered by a respective spacer (105) such that an area between the connection edge (104) and a border (106) of a remaining pad area (103) is completely covered by the spacer (105), and the connection edge (104) and the border (106) of the remaining pad area (103) have a minimum distance of D, wherein D is a positive number. A solder leaking is prevented between the pads (103) on the top surface (101) and the castellated orifices (102) by the spacers (105).

A printed circuit board including an electronic component and a method of producing the same are provided. The printed circuit board includes a multilayered substrate including an insulation layer and an inner circuit layer laminated therein, a cavity disposed in the multilayered substrate, a via disposed in the insulation layer and configured to electrically connect the inner circuit layer with another inner circuit layer, a first electronic component inserted in the cavity, and a bump pad disposed on a surface of the cavity facing the first electronic component, and the bump pad is formed by having the insulation layer and the via exposed to a lateral side of the cavity.

The present invention provides a flexible flat cable. The flexible flat cable including: a first flexible flat cable and a second flexible flat cable, wherein: an end of the first flexible flat cable is connected with a first terminal; an another end of the first flexible flat cable is provided with a plurality of first pads; an end of the second flexible flat cable is connected with a second terminal; an another end of the second flexible flat cable is provided with a plurality of second pads connected with the plurality of first pads in one-to-one correspondence. The flexible flat cable according to the exemplary embodiments of the present invention can improve versatility, reusability and repairability of the flexible flat cable.

A structure that includes a board and a connector secured to an end portion of the board. The board has a first dielectric layer, a signal pattern that is provided on the top face of the first dielectric layer, a first ground layer that is provided under the first dielectric layer and forms part of a signal transmission circuit in conjunction with the signal pattern, and a plating film formed on an end face of the end portion of the board in an area located directly under the signal pattern and includes an end face of the first ground layer. The connector has a center conductor, an outer conductor, and securing portions that secure the connector to an end portion of the board. When the connector is secured, the center conductor comes in contact with the signal pattern and the plating film comes in contact with the outer conductor.

Systems and methods described herein are provided for electrically coupling conductors within a multilayered printed circuit board (PCB) using an interconnect formed along an outer surface of one or more stripline boards making up the multilayered PCB. The multilayered PCB may include first and second stripline boards each having multiple dielectric layers. A first conductor may be formed in the first stripline between the multiple dielectric layers and a second conductor may be formed in the second stripline between the multiple dielectric layers. The interconnect may be formed over an outer surface the dielectric layers such that the interconnect extends from the first conductor to the second conductor. An electrically conductive wall may be formed over the edge or side portion of the dielectric layers to form a cavity that encloses the interconnect and the outer surface of the multilayered PCB.

A signal transmission cable as a signal transmission component includes a laminate including a first thin portion on one of the opposite ends in a first direction and a second thin portion on the other end in the first direction. A portion between the first thin portion and the second thin portion in the laminate is a main line portion. The thickness of the first and second thin portions is thinner than the thickness of the main line portion. The surface on one end in the thickness direction of the laminate defined by the main line portion and the first and second thin portions is a continuous flat surface. A connector for external connection is arranged on the surfaces of the first and second thin portions, on the sides in which each of the thin portions and the main line portion have a difference in level.

An EMI shielding structure includes a shielding pad surrounding at least one circuit component mounted on a printed circuit board and grounded to a ground pad disposed on the printed circuit board; and a shield can configured to cover the at least one circuit component, wherein a portion of the shield can is attached to the shielding pad.

An electronic device is provided that includes a PCB including a first surface, a second surface, and a side surface; an electronic component arranged on the first surface, adjacent to a portion of the side surface; a shield structure including a cap that covers the electronic component and a sidewall extending from a periphery of the cap toward the first surface of the PCB, wherein the sidewall extends in a first direction that is non-parallel to the first surface of the PCB; a first conductive structure that is formed on a portion of the side surface of the PCB; and a second conductive structure that is formed on a portion of the first surface to be connected to the first conductive structure. The sidewall contacts with the first surface of the PCB and overlaps with the second conductive structure, when viewed from above the first surface of the PCB.

A printed circuit board having an electronic component embedded is disclosed. The printed circuit board has four electrically conductive layers and three core layers formed interleavedly. By properly removing a portion of the printed circuit board, the electronic component can be exposed. It has advantages that the exposed electronic component can be a CCD, CMOS or module. When the devices mentioned are embedded in the printed circuit board, one part of them can be exposed from the printed circuit board for normal functions. The overall thickness of the printed circuit board assembly can be minimized to meet the trend of compact design of electronic products.

A signal transmission cable as a signal transmission component includes a laminate including a first thin portion on one of the opposite ends in a first direction and a second thin portion on the other end in the first direction. A portion between the first thin portion and the second thin portion in the laminate is a main line portion. The thickness of the first and second thin portions is thinner than the thickness of the main line portion. The surface on one end in the thickness direction of the laminate defined by the main line portion and the first and second thin portions is a continuous flat surface. A connector for external connection is arranged on the surfaces of the first and second thin portions, on the sides in which each of the thin portions and the main line portion have a difference in level.