Generally discussed herein are systems and apparatuses that include a dense interconnect bridge and techniques for making the same. According to an example a technique can include creating a multidie substrate, printing an interconnect bridge on the multidie substrate, electrically coupling a first die to a second die by coupling the first and second dies through the interconnect bridge.

A lamination circuit board structure lamination circuit board structure includes a printed circuit board substrate including conductive wiring traces on at least a first wiring face, a prepreg layer formed over the first wiring face, and a patch having an area smaller than 1,000 mm.sup.2. The patch includes conductive wiring traces formed on a wiring face and is laminated to the printed circuit board substrate over the prepreg layer, oriented with the wiring face in contact with and pressed into the prepreg layer. Portions of the prepreg layer fill interstices between the conductive wiring traces.

In a method for manufacturing a stack component in which an interposer is interposed to form a space for inserting an interlayer connection pin between circuit layers to be stacked, the method includes a printing step of simultaneously printing and forming the circuit layer and the interposer side by side in a planar manner by a 3D printer, a step of mounting a circuit element on the circuit layer, a step of mounting the interposer on the circuit layer, a step of inserting the interlayer connection pin into the interposer mounted on the circuit layer, and a step of electrically connecting the circuit layer and another circuit layer by the interlayer connection pin by stacking the other circuit layer on the circuit layer via the interposer.

A circuit board with high light reflectivity includes an inner wiring base board, a base board with a high light reflectivity, a first insulation layer, a first conductor layer, and a second insulation layer. A first opening in the inner wiring base board receives the base board. The first insulation layer is stacked on a surface of the inner wiring base board and defines a second opening corresponding in position to the first opening and exposing a portion of the base board. The first conductor layer is on a surface of the first insulation layer away from the inner wiring base board and includes connecting pads on the base board. The second insulation layer and the second conductor are stacked in that order on another surface of the inner wiring base board. A method for manufacturing the circuit board is also disclosed.

Embodiments provide a method for manufacturing a microelectronic arrangement. The method includes a step of providing a chip-film module with a semiconductor chip and a film substrate having arranged thereon the semiconductor chip, wherein the chip-film module includes at least one coupling element spaced apart from the semiconductor chip and electrically coupled to at least one terminal of the semiconductor chip. Furthermore, the method includes a step of embedding the chip-film module into a printed circuit board, wherein, in embedding the chip-film module into the printed circuit board, the at least one coupling element of the chip-film module is coupled vertically [e.g. in the vertical direction [e.g. in relation to the printed circuit board]] [e.g. perpendicular to a surface of the printed circuit board] to at least one coupling counter element of the printed circuit board

A connection structure-embedded substrate includes: a printed circuit board including a plurality of first insulating layers of which at least one has a cavity provided therein, a plurality of first wiring layers disposed as at least one of an outer portion and an inner portion of the plurality of first insulating layers, and a first build-up insulating layer disposed on an upper surface of the plurality of first insulating layers; and a connection structure at least partially disposed in the cavity. The first build-up insulating layer is disposed in the cavity, and each of a lower surface of the connection structure and a lower surface of the cavity is in contact with at least a portion of the first build-up insulating layer, respectively.

A component carrier includes a stack having at least one electrically conductive layer structure and/or at least one electrically insulating layer structure. A cavity is formed in the stack and has a non-polygonal outline. A component is in the cavity. A method of manufacturing such a component carrier is also provided.

A uniform thickness flex circuit is taught that uses more than one dielectric layer. A first dielectric layer is more flexible and capable of reliably bending at a radius of curvature at which a second dielectric layer cannot be reliably bent. The second dielectric layer has at least one more desirable electrical characteristic than the first dielectric area, for example leakage. Use of the uniform thickness flex circuit to protect sensitive material in an electronic enclosure is also described.

A connection structure embedded substrate includes a printed circuit board including a first insulating body and a plurality of first wiring layers disposed on at least one of an external region or an internal region of the first insulating body; and a connection structure embedded in the first insulating body and including first and second substrates. The first and second substrates are disposed adjacent to each other.

A method for producing a printed circuit board is disclosed, In the method, a slot is formed in a substrate having at least three layers with the slot extending through at least two of the layers. The slot has a length and a width with the length being greater than the width. The sidewall of the substrate surrounding the slot is coated with a conductive layer. Then, the conductive layer is separated into at least two segments that are electrically isolated along the side wall of the substrate.