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 method for manufacturing a circuit board structure with a waveguide is provided. The method includes: providing a first substrate unit, a second substrate unit, a third substrate unit, and two adhesive layers, the first substrate unit including a first dielectric layer and a first conductive layer, the first conductive layer including a first shielding area and two first artificial magnetic conductor areas disposed on two sides of the first shielding area; the second substrate unit including a second dielectric layer and a second conductive layer, the second conductive layer including a second shielding area; the third substrate unit defining a first slot, and the adhesive layer defining a second slot; stacking the first substrate unit, one of the adhesive layers, the third substrate unit, another one of the adhesive layers, and the second substrate unit in that order; pressing the intermediate body.

A printed circuit board for mounting electrical components thereupon include: a first side; a second side opposite the first side; electrical connection points disposed on the surface of an exterior edge of the printed circuit board; and wherein the exterior edge of the printed circuit board is between the first side and the second side. Further a method of manufacturing a printed circuit board for mounting electrical components thereupon includes the steps of disposing interconnect structures within the printed circuit board adjacent to at least one edge of the printed circuit board; and removing material from the printed circuit board edge to expose the interconnect structures such that the exposed interconnect structures correspond to a component connection footprint.

An electrical component is configured to allow electrical cables to be mounted directly to a package substrate, such that electrical traces of the package substrate directly place the electrical cables in electrical communication with an integrated circuit that is mounted to the package substrate without passing through any separable interfaces of an electrical connector.

A packaging method includes steps of: forming first and second wiring layers electrically connected to each other on two opposite surfaces of a substrate; then configuring mother substrate interconnecting bumps on the first wiring layer and along perimeter of a daughter substrate unit, and then cutting along the perimeter of the daughter substrate unit to expose lateral faces of the mother substrate interconnecting bumps and configuring solder materials thereon; then configuring first and second chips on the first and the second wiring layers to form electrical interconnection between the two chips. A package structure enables interconnecting two chips through one single daughter substrate unit with its wiring layers directly connecting with lateral face contacts of the mother carrier substrate through the mother substrate interconnecting bumps. Hence, area of the daughter substrate unit is reduced; lengths of the interconnection paths are shortened, and qualities of communication and space utilization are enhanced.

System for enabling circuit board surface-slot-edge connections. A main board includes a slot through its surfaces. At least one edge of the slot includes electrical contacts to the main board. An auxiliary board includes a connector component mounted on a surface that opposes a surface of the main board. When the connector component is aligned with the slot, the connector component can protrude vertically through the slot, in addition to moving laterally towards an edge of the slot. Electrical contacts on the edge of the slot can engage with electrical contacts in the connector component. This enables two boards to be arranged closely, without extending the main surface in an orthogonal or lateral direction, using a secure connection provided by a connector attached to the auxiliary board, rather than the main board.

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.

An interconnection includes a circuit board assembly and a hybrid cable assembly. The circuit board assembly includes first and second outer layer assemblies and an intermediate layer assembly. The first and second outer layer assemblies each include an electrically conductive layer. A cable-receiving space is formed at a first side edge of the circuit board assembly. The hybrid cable assembly includes a dielectric waveguide system having a core and a cladding and being configured to transmit a radar wave in a frequency range from about 70 to about 300 GHz. A first conductor system configured to transmit power and/or data is disposed adjacent to the dielectric waveguide system and includes an electrically conductive inner conductor assembly inserted into the cable-receiving space and galvanically connected to a first inner-conductor connection region. The core of the dielectric waveguide system is inserted into the cable-receiving space and disposed at a waveguide connection region.

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 printed circuit board includes a first transmission line provided on an insulating base, a first ground conductor, a notch portion that exposes a part of the first ground conductor, a conductor provided in the notch portion and electrically connected to the first ground conductor, and a first electrode exposed on a main surface of the insulating base facing a flexible board and electrically connected to the first transmission line. The flexible board includes a second transmission line provided on an insulating sheet, a second ground conductor, a second electrode exposed on a main surface of the insulating sheet facing the printed circuit board and connected to the second transmission line, and a third electrode exposed on the main surface of the insulating sheet and connected to the second ground conductor. The conductor and the third electrode are connected by solder.