A build-up process for fabricating a multi-layer PCB is provided during which a mezzanine redistribution, or routing, structure is formed within one of the PCB dielectric material layers that allows additional electrical interconnections (i.e., traces and crossovers) to be made within that layer, thereby obviating the need to add an additional PCB layer in order to make those interconnections. The mezzanine redistribution structure also can be interconnected with the metal layers that are above and below it to further increase routing complexity and flexibility. The mezzanine redistribution structure can be formed without increasing the total thickness of the PCB and without substantially increasing costs.

A first insulating layer is formed on a support substrate. The first insulating layer includes a first portion and a second portion. The second portion has a thickness smaller than that of the first portion. A ground layer having electric conductivity higher than that of the support substrate is formed on the second portion of the first insulating layer. The ground layer is electrically connected to the support substrate. A second insulating layer is formed on the first insulating layer to cover the ground layer. A write wiring trace is formed on the second insulating layer to overlap with the first portion and the second portion of the first insulating layer.

Disclosed herein are printed circuit boards (PCBs) with patterned ground structure filters and data storage devices comprising such PCBs. Each PCB comprises a resonator having an L-shape or a zig-zag shape in a plane of the printed circuit board and at least one signal trace. The resonator has a first dimension and a second dimension in the plane of the printed circuit board. A portion of the at least one signal trace is situated over the resonator and is separated by a distance from the resonator by a dielectric material. In some embodiments, at least part of the portion of the at least one signal trace extends in a same direction as the first dimension (in the case of an L-shaped resonator) or tracks the zig-zag shape of the resonator (in the case of a zig-zag-shaped resonator).

A printed circuit board (PCB) structure is provided for a solid state drive. In an embodiment, a solid state drive includes top and bottom layers, multiple intermediate layers and a ground cage. Each of top and bottom layers includes a plurality of components for operation of the solid state drive. The multiple intermediate layers enable electrical signals to pass between components on the top and bottom layers, one of the multiple intermediate layers including a power plane having a high voltage relative to each of the other planes. The ground cage shields signal traces on the same layer as the power plane and planes in adjacent layers from noise generated by the power plane.

A circuit including a grounding layer, a pair of signal lines and an insulating layer is provided. The grounding layer has a void region. The void region includes a first straight line part, a second straight line part and a third straight line part. The second straight line part and the third straight line part are connected to two ends of the first straight line part. An orthogonal projection of the pair of signal lines on the grounding layer crosses the first straight line part. The insulating layer is disposed between the grounding layer and the pair of signal lines and separates the grounding layer from the pair of signal lines.

The present disclosure generally relates to a shielded three-layer patterned ground structure in a PCB. The PCB may be disposed in a hard disk drive. To reduce costs, PCBs are being made with only four total layers separated by dielectric material. Conductive traces in PCBs can have the problem of common mode current flowing through the traces and thus increasing the magnitude of EMI noise. By providing a shielded three-layer patterned ground structure, not only is the cost reduced, but so is the common mode current and the magnitude of EMI noise, all without any negative impact to the differential signal.

A flat cable (100) includes an insulative carrier (20) extending along a front-to-back direction, a set of signal conductors (10) held by the insulative carrier, and a metal grid layer (30) attached to the insulative carrier. The insulative carrier has a top face facing upwardly and a bottom face facing downwardly. The insulative carrier defines a set of receiving passageways (210) disposed along a transverse direction perpendicular to the front-to-back direction. The set of signal conductors extend along the front-to-back direction and have different pitches along the transverse direction. The metal grid layer is attached to the top face or the bottom face. The metal grid layer has different densities along the front-to-back direction in order to make the impedance of the flat cable consistent along the front-to-back direction.

A printed wiring board includes a power supply conductor pattern arranged on one conductor layer, one ground conductor pattern arranged on the one conductor layer, and another ground conductor pattern arranged on the another conductor layer so as to be opposed to the power supply conductor pattern. The power supply conductor pattern includes a power supply pad on which a terminal of a capacitor is to be bonded. The one ground conductor pattern includes a ground pad on which another terminal of the capacitor is to be bonded. A slit is formed in the another ground conductor pattern so as to pass through a projection portion defined by projecting the power supply pad onto the another ground conductor pattern and divide a projection portion defined by projecting the power supply conductor pattern onto the another ground conductor pattern.

A printed wiring board (1) includes: a base substrate (3); a plurality of pads (15a, 17a) for electrical connection that are disposed at one surface side of the base substrate (3) and at a connection end portion (13) to be connected with another electronic component (50); wirings (9, 11) that are connected with the pads (15a, 17a); and engageable parts (28, 29) that are formed at side edge parts of the connection end portion (13) and are to be engaged with engagement parts (58) of the other electronic component (50) in the direction of disconnection. The flexible printed wiring board (1) further includes reinforcement layers (31, 32) that are disposed at the other surface side of the base substrate (3) and at a frontward side with respect to the engageable parts (28, 29) when viewed in the direction of connection with the other electronic component, and that are formed integrally with the wirings (9).

An electronic device includes a housing configured to form an internal space, a radiating sheet configured to be disposed in the internal space; at least one electronic component configured to be disposed in the internal space and to be in contact with the radiating sheet. An FPCB antenna module configured to be disposed on the radiating sheet includes a conductive pattern and a nonconductive layer configured to surround the conductive pattern, wherein the nonconductive layer may extend on the radiating sheet to a region in which the electronic component is positioned.