Disclosed is a printed circuit board (PCB) module including a first PCB comprising a base PCB, a sidewall disposed on a periphery of the base PCB, and conductive vias penetrating the sidewall, a second PCB disposed on the sidewall to cover a cavity formed by the sidewall of the first PCB, and at least one electronic component disposed inside the cavity and located on the first PCB and/or the second PCB, wherein the sidewall comprises a first layer disposed on an upper face of the base PCB and constructed of an insulating member, a second layer disposed on the first layer and comprising a polyimide, a third layer disposed on the second layer and constructed of an insulating member, and a fourth layer disposed on the third layer and comprising a conductive member conductive with respect to the conductive vias.

Processes for laminating a graphene-coated printed circuit board (PCB) are disclosed. An example laminated PCB may include a lamination stack that may include an inner core, an adhesive layer, and at least one graphene-metal structure. Pressure and heat—which may be applied under vacuum or controlled gas atmosphere—may be applied to the lamination stack, after all materials have been placed. The graphene of the graphene-metal structure is designed to promote high frequency performance and heat management within the PCB.

A method for forming resistance on circuit board is provided and includes the following steps. First, a substrate is provided. Next, a second metal layer is provided on the substrate, and the first metal layer is covered by the second metal layer. Then, a resistance is formed on the second metal layer, and the resistance is directly above the first metal layer. Thereafter, the second metal layer is cut so that the edge of the second metal layer is aligned with that of the first metal layer. The second metal layer is separated from the first metal layer. Next, the second metal layer is pressed with a circuit board, and the resistance is attached to a dielectric layer of the circuit board. Then, the second metal layer is etched to form a circuit pattern on the resistance.

The invention discloses a method of improving a wire structure of a circuit board, comprising the following steps: providing a multi-layer circuit board, including an inner circuit and a surface circuit; forming an opening to expose the inner circuit; forming a first circuit layer in the opening; removing the first circuit layer, the first conductive circuit, and the surface circuit on the multi-layer circuit board and removing a part of the first circuit layer in the opening; forming an adhesion promoter layer in the opening and on the multi-layer circuit board; forming a second conductive circuit on the adhesion promoter layer and on the first conductive circuit layer in the opening; forming a photoresist layer on the second conductive circuit layer; forming a second circuit layer in the opening and on the multi-layer circuit board, and removing the photoresist layer and a part of the second conductive circuit.

A method for forming a circuit board having a dielectric core, a foil top surface, and a thin foil bottom surface with a removable foil backing of sufficient thickness to absorb heat from a laser drilling operation to prevent the penetration of the thin foil bottom surface during laser drilling utilizes a sequence of steps including a laser drilling step, removing the foil backing step, electroless plating step, patterned resist step, electroplating step, resist strip step, tin plate step, and copper etch step, which provide dot vias of fine linewidth and resolution.

A component carrier includes a stack with at least one electrically conductive layer structure, at least one electrically insulating layer structure, and a hole in the stack having a first hole portion covered with metal and having a second hole portion not covered with metal, wherein the second hole portion is defined by an anti-plating dielectric structure and an electroless plateable separation barrier.

A resistor-embedded circuit board and a method for processing the resistor-embedded circuit board are provided by the present disclosure. By opening an embedded-resistor cavity on a substrate, embedding a resistor into the embedded-resistor cavity to acquire a circuit board containing a built-in resistor. By opening the embedded-resistor cavity, it is very easy to realize high-precision control of a shape and a thickness of an embedded resistor, and realize very high-precision resistor-embedding; and it is easy to realize high-precision and massive processing. In a resistor-embedded layer, a resistor is built in a substrate. Then, in a process of pressing, a crack and a relatively large deformation will not be caused after pressing due to an irregular surface of the resistor-embedded layer, thereby improving a reliability and a quality rate of the circuit board.

The method for producing a laminate having a patterned metal foil includes masking the whole surface of a first metal foil in a laminate having the first metal foil, a first insulating resin layer having a thickness of 1 to 200 μm and a second metal foil laminated in this order, and patterning the second metal foil.

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 according to an embodiment includes an insulating layer; a first pad disposed on an upper surface of the insulating layer; a second pad disposed on a lower surface of the insulating layer; a first device mounted on the first pad; a second device mounted on the second pad; a first molding layer disposed on the insulating layer and molding the first device; and a second molding layer disposed on the lower surface of the insulating layer and molding the second device, wherein a lower surface of the second molding layer is positioned on the same plane as a lower surface of the second device.