A printed wiring board includes a central resin insulating layer, an electronic component embedded in the central resin insulating layer, a first resin insulating layer formed on a first surface side of the central resin insulating layer, and a second resin insulating layer formed on a second surface side of the central resin insulating layer on the opposite side with respect to the first surface side. The central resin insulating layer does not contain a core material, and one of the first resin insulating layer and the second resin insulating layer includes a core material and the other one of the first resin insulating layer and the second resin insulating layer does not contain a core material.

An electronic assembly is disclosed that includes a flexible insulating film, a semiconductor component that has a thickness of less than 50 micrometers, a conductive interconnect extending through the flexible insulating film, a second patterned metal wiring film adjacent, and a third patterned metal wiring film. The second patterned metal wiring film is electrically coupled with the third patterned metal wiring film through the conductive interconnect. The semiconductor component is coupled to the first patterned metal wiring film and at least one of the second patterned metal wiring film or the third patterned metal wiring film.

A circuit board with a heat-recovery function includes a substrate, a heat-storing device, and a thermoelectric device. The heat-storing device is embedded in the substrate and connected to a processor for performing heat exchange with the processor. The thermoelectric device embedded in the substrate includes a first metal-junction surface and a second metal-junction surface. The first metal-junction surface is connected to the heat-storing device for performing heat exchange with the heat-storing device. The second metal-junction surface is joined with the first metal-junction surface, in which the thermoelectric device generates an electric potential by a temperature difference between the first metal-junction surface and the second metal-junction surface.

The present invention provides stencil-based processes for fan-out wafer-level packaging (FOWLP) that addresses the limitations associated with prior art over-molding of dies. In the inventive process, a temporary carrier is coated with a release layer and curable adhesive backing layer. A die stencil film is then laminated to the coated carrier, and the dies are placed inside pre-formed cavities created in the laminated stencil. The gaps between the dies and the stencil are filled with a curable polymeric material, and a redistribution layer is constructed according to conventional processes. This process results in better repeatability, lower bowing in the carrier, and enhanced downstream processing.

A printed wiring board includes a central resin insulating layer, an electronic component embedded in the central resin insulating layer, a first resin insulating layer formed on a first surface side of the central resin insulating layer, and a second resin insulating layer formed on a second surface side of the central resin insulating layer on the opposite side with respect to the firs surface side. The central resin insulating layer does not contain a core material, and one of the first resin insulating layer and the second resin insulating layer includes a core material and the other one of the first resin insulating layer and the second resin insulating layer does not contain a core material.

A semiconductor package structure includes an encapsulant, a first chip, a second chip, a first redistribution layer and a second redistribution layer. The encapsulant has a first surface and a second surface opposite to each other. The first chip is in the encapsulant, wherein the first chip includes a plurality of contact pads exposed from the first surface of the encapsulant. The second chip is in the encapsulant, wherein second chip includes a plurality of contact pads exposed from the second surface of the encapsulant. The first redistribution layer is over the first surface of the encapsulant and electrically connected to the contact pads of the first chip. The second redistribution layer is over the second surface of the encapsulant and electrically connected to the contact pads of the second chip.

A circuit board with a heat-recovery function includes a substrate, a heat-storing device, and a thermoelectric device. The heat-storing device is embedded in the substrate and connected to a processor for performing heat exchange with the processor. The thermoelectric device embedded in the substrate includes a first metal-junction surface and a second metal-junction surface. The first metal-junction surface is connected to the heat-storing device for performing heat exchange with the heat-storing device. The second metal-junction surface is joined with the first metal-junction surface, in which the thermoelectric device generates an electric potential by a temperature difference between the first metal-junction surface and the second metal-junction surface.

A circuit board includes a core layer, at least one passive component, a first and a second conductive wire layers, at least one contact pad, and a resin packing layer. The core layer defines at least one through hole to receive the passive component. The first and the second conductive wire layers are connected to two opposite surfaces of the core layer. Each contact pad is positioned between and connected to one passive component and the first conductive wire layer. The resin packing layer is filled among the core layer, each passive component, each contact pad, the first and the second conductive wire layers. The resin packing layer can connect the first and the second conductive wire layers to the core layer, and connect the core layer, each passive component, and each contact pads to each other.

An electronic device according to the present disclosure includes a component, an electrode placed on the component, a conductor which includes a first conductor section, including an electrode contact surface in contact with the electrode, and two second conductor sections, electrically connected to two respective facing edges of the first conductor section to extend in respective directions away from the electrode and including respective inclined surfaces inclined in directions toward a central axis passing through a center of the electrode and perpendicular to the surface of the electrode, an insulator which is in contact with the two second conductor sections from sides opposite to the central axis and encloses the conductor and the electrode, and a case housing the component, the electrode, the conductor, and the insulator. A space without the insulator is defined between the two second conductor sections.

An electronic assembly is disclosed that includes a flexible insulating film, a semiconductor component that has a thickness of less than 50 micrometers, a conductive interconnect extending through the flexible insulating film, a second patterned metal wiring film adjacent, and a third patterned metal wiring film. The second patterned metal wiring film is electrically coupled with the third patterned metal wiring film through the conductive interconnect. The semiconductor component is coupled to the first patterned metal wiring film and at least one of the second patterned metal wiring film or the third patterned metal wiring film.