A composite circuit board includes a flexible board, rigid boards, adhesive layers, and protection glue; the adhesive layers are sandwiched between the rigid boards and the flexible board and used for bonding the rigid boards and the flexible board; the rigid boards are provided with step slots passing through the rigid boards; the adhesive layers are provided with through slots passing through the adhesive layers; the step slots and the through slots are communicated with each other to form a thinning recess; the thinning recess exposes the flexible board; and the protection glue covers steps of the thinning recess and at least a portion of the exposed area of the flexible board.

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.

In an antenna in package structure, a plurality of supporting blocks spaced apart from each other are disposed between a first substrate and a second substrate, and an antenna cavity is formed between every two adjacent supporting blocks. Therefore, a height of the supporting block determines a height of the antenna cavity. The supporting blocks spaced apart from each other are located between the first substrate and the second substrate, and at least one of the first substrate or the second substrate adheres to the supporting blocks spaced apart from each other using an adhesive layer.

The present invention discloses a method for manufacturing a multi-layer flexible circuit board, comprising the steps of: (1) manufacturing a double-sided FPC flexible board; (2) manufacturing a novel material layer structure; (3) hot pressing at least one group of upeer novel material layer structures on the circuits on the upper and/or lower surfaces of the double-sided FPC flexible board; forming a protective layer on the circuits of an outermost novel material layer structure and/or on exposed circuits of the double-sided FPC flexible board so as to obtain a multi-layer flexible circuit board. The present invention also discloses a multi-layer flexible circuit board manufactured by performing the above-mentioned method. The manufacturing process of the present invention is simplified, convenient and efficient; the multi-layer flexible circuit board not only greatly simplifies the novel material layer structure and reduces the overall thickness, but also has the function of high-speed transmission of high-frequency signals, especially suitable for new 5G technology products. It can protect and resist the migration of copper ions when it is energized between circuits so as to ensure the safety and normal operation of circuits.

The present application relates to the technical field of circuit board fabricating, and provides a method for fabricating an asymmetric board, the method includes fabricating a master board, fabricating a second sub-board, thermal compression bonding the master board and the second sub-board, and milling a finished board; further includes at least one of the following three steps: laying copper on the connection positions of the master board except for the second copper layer of an outermost layer to obtain laying copper area, digging copper on the connection positions of the third copper layer, and after the step of milling the finished board, on each of the impositions, performing depth control milling at the connection positions from a side of the second sub-board on each imposition to obtain a depth control groove.

A process of fabricating an electromagnetic circuit includes providing three laminate sheets, forming a first feature in a first laminate sheet of the three laminate sheets, and forming a second feature in a second laminate sheet of the three laminate sheets. The second feature is aligned with the first feature when aligning the second laminate sheet with the first laminate sheet. The process further includes stacking the three laminate sheets so that the first laminate sheet is positioned above and aligned with the second laminate sheet and the second laminate sheet is positioned above and aligned with the third laminate sheet. The first feature and the second feature define a contiguous element. The process further includes filling the contiguous element with an electrically conductive material to form an electrically continuous conductor.

The present disclosure provides a method for manufacturing a board-to-board connection structure. The method includes defining a first through hole in a first circuit board, disposing a first connector within the first through hole by a first conductive paste, and connecting the first connector to a second circuit board on which a second connector is installed, thereby realizing a connection of the two circuit boards, and reducing a height of the two circuit boards after the connection. That is, the height of the board-to-board connection structure is reduced. Additionally, since the first connector is received within the first through hole, the first connector is not easy to be damaged and oxidized. The present disclosure further provides a board-to-board connection structure manufactured by the above method.

A component carrier includes a layer stack with at least one electrically insulating layer structure and/or at least one electrically conductive layer structure, at least one opening in the layer stack, a first curable dielectric element arranged at least partially on the opening, and a second curable dielectric element arranged adjacent to the first curable dielectric element, so that there is an interface region in between. A part of the first curable dielectric element extends partially into the opening.

A semiconductor assembly includes a laminate substrate that includes a plurality of laminate layers of electrically insulating material stacked on top of one another, a semiconductor package that includes a package body of electrically insulating encapsulant material and a plurality of electrical contacts that are exposed from the package body, wherein the semiconductor package is embedded within the laminate layers of the laminate substrate, wherein the semiconductor package comprises a delamination mitigation feature, wherein the delamination mitigation feature comprises one or both of a macrostructure that engages with the laminate layers, and a roughened surface of microstructures that enhances adhesion between the semiconductor package and the laminate layers.

A process of fabricating an electromagnetic circuit includes providing three laminate sheets, forming a first feature in a first laminate sheet of the three laminate sheets, and forming a second feature in a second laminate sheet of the three laminate sheets. The second feature is aligned with the first feature when aligning the second laminate sheet with the first laminate sheet. The process further includes stacking the three laminate sheets so that the first laminate sheet is positioned above and aligned with the second laminate sheet and the second laminate sheet is positioned above and aligned with the third laminate sheet. The first feature and the second feature define a contiguous element. The process further includes filling the contiguous element with an electrically conductive material to form an electrically continuous conductor.