A method includes forming a redistribution structure on a carrier substrate, coupling a first side of a first interconnect structure to a first side of the redistribution structure using first conductive connectors, where the first interconnect structure includes a core substrate, where the first interconnect structure includes second conductive connectors on a second side of the first interconnect structure opposite the first side of the first interconnect structure, coupling a first semiconductor device to the second side of the first interconnect structure using the second conductive connectors, removing the carrier substrate, and coupling a second semiconductor device to a second side of the redistribution structure using third conductive connectors, where the second side of the redistribution structure is opposite the first side of the redistribution structure.

A circuit board includes a substrate, a driver circuit, at least one light-emitting element, a grounding circuit, and an antenna unit. The substrate includes a first circuit layer and a second circuit layer. The driver circuit is located on the first circuit layer. The light-emitting element is located on the first circuit layer and is electrically connected to the driver circuit, so that the driver circuit controls the light-emitting element to emit light. The grounding circuit is located on the second circuit layer and is electrically connected to the driver circuit. The grounding circuit includes a plurality of conductive traces, and the conductive traces are arranged toward one side to form a clearance area on the second circuit layer. The antenna unit is located on the first circuit layer and corresponds to the clearance area to receive and transmit a radio frequency signal.

In one embodiment, a printed circuit board includes a first circuit board portion comprising a set of first conducting layers and one or more plated through hole (PTH) vias formed through the first conducting layers and a second circuit board portion comprising a set of second conducting layers. The second circuit board portion has an area less than an area of the first circuit board portion, and the second circuit board portion is coupled to the first circuit board portion via a laminate layer such that the first and second conducting layers are parallel with one another. The printed circuit board further includes one or more PTH vias formed through the first and second conducting layers in an area of the printed circuit board where the first and second circuit board portions overlap.

Embedded organic interposers for high bandwidth are provided. Example embedded organic interposers provide thick conductors with more dielectric space, and more routing layers of such conductors than conventional interposers, in order to provide high bandwidth transmission capacity over longer spans. The embedded organic interposers provide high bandwidth transmission paths between components such as HBM, HBM2, and HBM3 memory stacks, and other components. To provide the thick conductors and more routing layers for greater transmission capacity, extra space is achieved by embedding the organic interposers in the core of the package. Example embedded organic interposers lower a resistive-capacitive (RC) load of the routing layers to provide an improved data transfer rate of 1 gigabits per second over at least a 6 mm span, for example. The embedded interposers are not limited to use with memory modules.

A flexible display panel and a display device are provided. The flexible display panel includes a bending region and a display region. The bending region includes a plurality of metal wirings; each metal wiring is in long strip shape and includes a metal strip; a plurality of openings are defined through the metal strip. In the width direction of the metal strip, a ratio of a minimum distance from a point of an edge of the one of the openings to a neighboring side of the metal strip to a minimum width of the metal strip ranges from 0.1 to 0.7. A wiring structure of the bending region can prevent a stress concentration of the bending region, enhance a strength during a bending process, and avoid a breakage of the metal wiring.

A wiring structure is provided. The wiring structure includes an upper redistribution structure, a lower redistribution structure, a conductive structure, an upper bonding layer and a lower bonding layer. The conductive structure is disposed between and electrically connected to the upper redistribution structure and the lower redistribution structure. The upper bonding layer is disposed between the upper redistribution structure and the conductive structure to bond the upper redistribution structure and the conductive structure together. The lower bonding layer is disposed between the lower redistribution structure and the conductive structure to bond the lower redistribution structure and the conductive structure together.

Package to printed circuit board (PCB) transitions are described. In one aspect, a multi-layer PCB includes an external layer having a transition region configured to receive an electrical component and a clear routing region outside of the transition region. The PCB includes first via(s) that extend from the transition region to an inner trace routing layer. The trace routing layer is disposed between the external layer and the second inner trace routing layer. The first inner trace routing layer includes a transition area disposed under the transition region of the external layer, a clear routing area outside of the transition region, and a transmission line that connects a given first via to a second via for a second electrical component. The transmission line includes conductive trace(s) that each have a first width in the transition area and a second width, greater than the first width, in the clear routing area.

Fine feature formation techniques for printed circuit boards are described. In one embodiment, for example, a method may comprise fabricating a conductive structure on a low density interconnect (LDI) printed circuit board (PCB) according to an LDI fabrication process and forming one or more fine conductive features on the LDI PCB by performing a fine feature formation (FFF) process, the FFF process to comprise removing conductive material of the conductive structure along an excision path to form a fine gap region within the conductive structure. Other embodiments are described and claimed.

A circuit board includes a composite layer of a non-conductor inorganic material and an organic material, a plurality of conductive structures, a first built-up structure, and a second built-up structure. The composite layer of the non-conductor inorganic material and the organic material has a first surface and a second surface opposite to each other and a plurality of openings. The conductive structures are respectively disposed in the openings of the composite layer of the non-conductor inorganic material and the organic material. The first built-up structure is disposed on the first surface of the composite layer of the non-conductor inorganic material and the organic material and electrically connected to the conductive structures. The second built-up structure is disposed on the second surface of the composite layer of the non-conductor inorganic material and the organic material and electrically connected to the conductive structures.

Fine feature formation techniques for printed circuit boards are described. In one embodiment, for example, a method may comprise fabricating a conductive structure 306 on a low density interconnect (LDI) printed circuit board (PCB) 150 according to an LDI fabrication process and forming one or more fine conductive features on the LDI PCB by performing a fine feature formation (FFF) process, the FFF process to comprise removing conductive material of the conductive structure along an excision path to form a fine gap region 308 within the conductive structure. Other embodiments are described and claimed.