A method, system, apparatus, and/or device to creating a set of miniaturized electrode pillars. The method, system, apparatus, and/or device may include patterning a set of miniaturized electrode pillars on a substrate and coating the set of miniaturized electrode pillars with an interstitial filler disposed between the set of miniaturized electrode pillars. The interstitial filler may insulate the set of miniaturized electrode pillars from each other and bolster the set of miniaturized electrode pillars.

A wiring structure of a head suspension including a flexure that supports a head and is attached to a load beam applying load onto the head, includes write wiring and read wiring formed on the flexure and connected to the head, each having wires of opposite polarities and further including a stacked interleaved part which includes segments electrically connected to the respective wires of the write wiring, the segments stacked on and facing the wires through an electrical insulating layer so that the facing wire and segment have opposite polarities, is manufactured by a wiring step, an insulating layer forming step and a stacked interleaved part forming step.

An aspect includes one or more board layers. A first chip cavity is formed within the one or more board layers, wherein a first Josephson amplifier or Josephson mixer is disposed within the first chip cavity. The first Josephson amplifier or Josephson mixer comprises at least one port, each port connected to at least one connector disposed on at least one of the one or more board layers, wherein at least one of the one or more board layers comprises a circuit trace formed on the at least one of the one or more board layers.

Disclosed is a method for manufacturing a flexible printed circuit board and a flexible printed circuit board manufactured thereby, which minimizes a dielectric loss due to a high frequency signal and preventing a loss of the high frequency signal. The disclosed method for manufacturing the flexible printed circuit board according to an embodiment of the present disclosure includes preparing a base sheet; preparing a bonding sheet having a melting temperature lower than a melting temperature of the base sheet; forming a laminate by stacking the base sheet and the bonding sheet; and bonding by heating and pressurizing the laminate.

A mechanical subtractive method of manufacturing a flexible circuitry layer may include mechanically removing at least a portion of a conductive mesh, wherein, following the mechanical removal, a remaining portion of the conductive mesh forms at least a portion of a circuitry trace comprising an electrode; forming an electrical connection between the electrode and a terminal of an interfacing component, wherein the interfacing component comprises a connector; and encasing at least a portion of the circuit trace with an insulative layer.

An interposer for mechanically and electrically connecting two circuit boards is described. The interposer can be bent to enclose an area of a circuit board. The interposer can include a first layer external to the enclosed area. The first layer can be conductive and can serve as an EMI shield. The interposer can also include a second layer internal to the enclosed area. The second layer can be non-conductive but can carry multiple discrete pins that can electrically couple the first and second circuit boards and provide signal transmission pathways between the circuit boards. The interposer can be formed by folding a sheet of conductive material having different cutout regions that forms a comb pattern into multiple stacked layers. Then, the bent regions that connect the stacked layers can be removed so that the conductive bars in the comb patterns can be separated and isolated to form discrete pins.

A printed circuit board includes a spread weave of fibers having a first direction and a second direction with corresponding fibers spread more in the first direction than the second direction; and one or more pairs of traces on the spread weave of fibers, wherein the first direction has less differences in dielectric permittivity seen by each trace than the second direction, wherein the one or more pairs of traces are routed according to a routing design that includes one or more fixed regions on the spread weave of fibers, where routing of traces therein is restricted to linear, non-angled routed in the first direction.

The disclosure provides an improved resin film product is comprised of a partially cured b-staged resin film that has a thickness in the range of 1 mils to about 10 mils and that is disposed between two protective layers, as well as methods for their manufacture and use in the production of layups used to manufacture printed circuit boards.

Integrated circuit packages (100) having electrical and optical connectivity and methods of making the same are disclosed herein. According to one embodiment, an integrated circuit package includes a structured glass article (120) including a glass substrate (122), an optical channel (132), and redistribution layers. The integrated circuit package (100) further includes an integrated circuit chip (160) positioned on the glass substrate (122) and in optical communication with the optical channel (132) and in electrical continuity with the redistribution layers (136).

An electronic module has a first substrate 11; an electronic element 13, 23 provided on one side of the first substrate 11; a sealing part 90 that seals at least the electronic element 13, 23; a connection terminal 110 electrically connected to the electronic element 13, 23 and exposed from a side surface of the sealing part 90; and a stress relaxation terminal 150, which is not electrically connected to the electronic element 13, 23, exposed from the side surface of the sealing part 90.