An electronic assembly and a manufacturing method thereof are provided. The electronic assembly includes a carrier substrate including a flexible structure and a circuit structure, and an electronic device disposed on the circuit structure. The flexible structure includes a first dielectric layer and a conductive pattern overlying thereon. The circuit structure includes a second dielectric layer overlying the first dielectric layer and the conductive pattern, and a circuit layer disposed on and passing through the second dielectric layer to be in contact with the conductive pattern, the first flexible structure includes a first portion embedded in the circuit structure and a second portion connected to the first portion and extending out from an edge of the circuit structure. The electronic device includes chip packages electrically coupled to the flexible structure through the circuit structure, and is sized to substantially match a size of the first portion of the circuit structure.

A display device includes a display panel including panel pads adjacent to the side surface of a display panel; connection pads disposed on the side surface of the display panel and connected to the panel pads; and a circuit board disposed on the side surface of the display panel and including lead signal lines directly bonded to the connection pads, wherein the connection pads include a first connection pad, a second connection pad disposed on the first connection pad, and a third connection pad disposed on the second connection pad, and the first connection pad is in contact with corresponding one of the panel pads, and the third connection pad is directly bonded to corresponding one of the lead signal lines.

A wiring board includes an insulating substrate including a cutout portion that opens in a main surface of the insulating substrate and a side surface of the insulating substrate, an inner surface electrode on an inner surface of the cutout portion, an external electrode on the main surface of the insulating substrate, and a connecting section where the inner surface electrode and the external electrode are connected to each other. The connecting section is thicker than the inner surface electrode and the external electrode.

A printed circuit board (PCB) structure and mounting assembly for joining two PCBs. A first PCB has a top and bottom surface faces and a peripheral end face separating the top and bottom surface. The first PCB has one or more conductive wire ends exposed at a surface of the peripheral end face; the exposed conductive wire ends forming multiple separate electrical contacts across the thickness and length of the PEF surface. A second PCB has a top surface face and one or more conductive pads exposed at the top surface at locations corresponding to locations of the multiple electrical contacts. A surface mount solder material is disposed on one or more exposed conductive pads for electrically connecting with corresponding the multiple electrical contacts. The disposed solder material stably joins the PEF surface of the first PCB to the top surface of the second PCB in a relative perpendicular orientation.

Discovered is a daughter circuit board for direct connection to another mother circuit board. The daughter circuit board has an edge electrode for conductive connection to a surface pad on the mother board. An opening in the daughter circuit board can be aligned with the surface pad on the mother circuit board. The opening can contain solder which when reflowed can establish a bond between the daughter circuit board and the surface pad on the mother circuit board.

An electronic device module includes: a substrate; at least one electronic device mounted on a first surface of the substrate; a connection portion mounted on the first surface of the substrate; and a shielding portion disposed along an external surface of the connection portion and electrically connected to a ground of the substrate through at least one connection conductor.

Provided is an electronic component mounting structure and method for mounting electronic components on the side of a printed circuit board by means of simple fabrication and enlarging the surface area for mounting electronic components. A cut face of a conductive plating layer, which is obtained by cutting along a via in which a conductive plating layer covering an inner wall face of a via hole is electrically connected to a conductive pattern layer of the printed circuit board, is exposed at a cut end face and used as a land pattern which is solder-connected to a mount connecting portion of the electronic component. The end face at which the land pattern is exposed is a surface parallel to the side of the printed circuit board, and therefore electronic components can be mounted on the end face parallel to the side.

A circuit carrier and a manufacturing method thereof are provided. The circuit carrier for coupling an electronic device includes a flexible structure and a circuit structure. The flexible structure includes a conductive pattern disposed on a surface of a first dielectric layer. The circuit structure includes a second dielectric layer overlying the surface of the first dielectric layer and a circuit layer disposed on the second dielectric layer and connected to the conductive pattern. The flexible structure is embedded in and electrically connected to the circuit structure, and a portion of the flexible structure extends out from an edge of the circuit structure to be plugged into the electronic device.

A flexible circuit board is provided. The flexible circuit board includes a first conductive layer, an adhesive layer, and a cover layer. The first conductive layer extends along a first direction. The adhesive layer is disposed on the first conductive layer and has a first side. The cover layer is disposed on the adhesive layer and has a second side. In addition, a bottom of the first side protrudes from a bottom of the second side in the first direction by a distance.

Printed circuit boards (PCBs) may include embedded lateral connectors. The embedded lateral connectors may be configured to enable components to quickly couple to or plug into a PCB, thus saving time to form connections. The embedded lateral connectors may also reduce weight and/or size by avoiding need for bulky tradition collections with conventional components (e.g., solders, external pin connectors, etc.). The connectors may include male connectors, female connectors, and/or mounting connectors. The connectors may be configured to connect multiple PCBs together, such as using a stacked configuration, which may enable reducing a volume of space needed in a housing for the PCBs.