A printable electronic component includes a component substrate and a circuit disposed in or on the component substrate. One or more electrically conductive connection posts protrude from the component substrate. One or more electrically conductive component contact pads are exposed on or over the component substrate on a side of the component substrate opposite the one or more connection posts. The one or more component contact pads and the one or more electrically conductive connection posts are both electrically connected to the circuit. The components can be printed onto a destination substrate and electrically connected to contact pads on the destination substrate through the connection posts. The components can also be printed onto other components and electrically connected through the connection posts and component contact pads to form a three-dimensional electronic structure.

Interposer printed circuit boards for power modules and associated methods are disclosed. In at least one illustrative embodiment, a printed circuit board assembly may comprise a printed circuit board having a surface, an electrical component mounted on the surface, a pin mounted on the surface, and an interposer printed circuit board mounted on the surface. The electrical component may have a first height orthogonal to the surface. The pin may have a second height orthogonal to the surface, where the second height is greater than the first height. The interposer printed circuit board may comprise a pad and an outer solder bump positioned on the pad. The outer solder bump may be positioned at a third height orthogonal to the surface, where the third height is greater than the first height.

A circuit board optimized for a denser component population within a standard size of footprint includes a mother board and a plurality of sub-board layers stacked on and connected to the mother board. Each of the sub-board layers has a plurality of daughter boards. The sub-board layers are composed of a first sub-board layer and a second sub-board layer. The daughter boards of the first sub-board layer are arranged on a side of the mother board, and the daughter boards of the second sub-board layer are arranged on the daughter boards of the first sub-board layer.

A manufacturing method of a component embedded package carrier includes the following steps: providing the dielectric layer; a first copper foil layer and a second copper foil layer; forming a plurality of through holes; forming a conductive material layer on the first copper foil layer and the second copper foil layer; patterning the conductive material layer, the first copper foil layer and the second copper foil layer, thereby defining the conductive through hole structures, the first patterned conductive layer and the second patterned conductive layer and forming the core layer comprises; disposing at least one electronic component inside the opening of the core layer; laminating a first insulating layer and a first circuit layer located on the first insulating layer onto the first patterned conductive layer; laminating a second insulating layer and a second circuit layer located on the second insulating layer onto the second patterned conductive layer.

A circuit board optimized for a denser component population within a standard size of footprint includes a mother board and a plurality of sub-board layers stacked on and connected to the mother board. Each of the sub-board layers has a plurality of daughter boards. The sub-board layers are composed of a first sub-board layer and a second sub-board layer. The daughter boards of the first sub-board layer are arranged on a side of the mother board, and the daughter boards of the second sub-board layer are arranged on the daughter boards of the first sub-board layer.

An inner module with a retainer is installed primarily inside a wireless earphone, including a circuit loop, an insulation seat to fix the circuit loop, and at least a retainer. The circuit loop includes at least a first circuit board, and at least a second circuit board which is extended from the first circuit board. The insulation seat includes at least a base plate to enclose the first circuit board, and a first side wall which is extended from the base plate. The first side wall is provided with a first positioning slot to accommodate the second circuit board. The retainer is fixed on the first side wall to fix the second circuit board in the first positioning slot. Therefore, the inner module is formed into a modularized design to simplify the assembly procedure of the wireless earphone.

A semiconductor package structure and manufacturing method thereof are provided. The semiconductor package structure includes a package structure and a rigid-flexible substrate. The package structure includes semiconductor dies, a molding compound and a redistribution layer. The molding compound laterally encapsulates the semiconductor dies. The redistribution layer is disposed at a front side of the semiconductor dies and electrically connected to the semiconductor dies. The rigid-flexible substrate is disposed at a side of the redistribution layer opposite to the semiconductor dies, and includes rigid structures, a flexible core and a circuit layer. The rigid structures respectively have an interconnection structure therein. The interconnection structures are electrically connected to the redistribution layer. The flexible core laterally penetrates and connects the rigid structures. The circuit layer is disposed over a surface of the flexible core, and electrically connected with the interconnection structures.

A display device includes a display panel, a main circuit board, a first connecting circuit board, a second connecting circuit board, and a sealing member. The display panel includes a first pad row and a second pad row. The first connecting circuit board is connected to the first pad row, and the second connecting circuit board is connected to the second pad row. The second pad row is spaced farther from an edge of the display panel than the first pad row. The sealing member is disposed between the first connecting circuit board and the second connecting circuit board to seal a gap between the first connecting circuit board and the display panel.

This disclosure includes multiple assemblies, sub-assemblies, etc., as well as one or more methods of fabricating same. For example, a first assembly includes a first circuit board. The first circuit board further includes first connector elements disposed on a first edge of the first circuit board and second connector elements disposed on a second edge of the first circuit board. The first edge may be disposed substantially opposite the second edge on the first circuit board. The apparatus may further include first circuitry affixed to the first circuit board. The first edge of the first circuit board aligns with a first axial end of the first circuitry and the second edge of the first circuit board aligns with a second axial end of the first circuitry. The first assembly is used to fabricate a second assembly.

A circuit board assembly (1), comprising a first circuit board (10) and a second circuit board (20) which are electrically connected with each other, and a monolithic substrate (30) configured for supporting a power component and comprising a first contact surface (31) that is fixedly connected to and forms a thermal contact with the second circuit board (20), the circuit board assembly being characterized in that, the substrate (30) further comprises a second contact surface (32) that is fixedly connected to the first circuit board (10) and forms a thermal contact with the first circuit board (10) so that the substrate functions as an extension of the first circuit board to support the second circuit board. A radio unit comprising a circuit board assembly (1) is also disclosed.