In a high-frequency module provided with a shield member between components, improvement in the degree of freedom in design such as arrangement of components or the like is achieved while preventing damage to a wiring board. A high-frequency module (1a) includes a multilayer wiring board (2), a plurality of components (3a) and (3b) mounted on an upper surface (20a) of the multilayer wiring board (2), and a shield member (5) for shielding between the component (3a) and the component (3b), in which the shield member (5) is formed in a flat plate shape, with a plurality of metal pins (5a) each stacked in a thickness direction of the sealing resin layer (4) such that a length direction is made to be substantially parallel to the upper surface (20a) of the multilayer wiring board (2), and a resin molded portion (5b) for fixing the metal pins (5a).

This disclosure teaches methods for making high-temperature superconducting striated tape combinations and the product high-temperature superconducting striated tape combinations. This disclosure describes an efficient and scalable method for aligning and bonding two superimposed high-temperature superconducting (HTS) filamentary tapes to form a single integrated tape structure. This invention aligns a bottom and top HTS tape with a thin intervening insulator layer with microscopic precision, and electrically connects the two sets of tape filaments with each other. The insulating layer also reinforces adhesion of the top and bottom tapes, mitigating mechanical stress at the electrical connections. The ability of this method to precisely align separate tapes to form a single tape structure makes it compatible with a reel-to-reel production process.

Electronics modules according to embodiments of the present technology may include a circuit board having a first surface from which an electronic component extends and a second surface opposite the first surface. The circuit board may include a tie-bar residual extending from a sidewall of the circuit board beyond the width across the first surface. The modules may also include an overmold at least partially encapsulating the circuit board. The overmold may be characterized by a first height extending normal to the first surface of the circuit board across the width of the circuit board. The overmold may extend laterally beyond the width along a length of the first surface. The overmold may define a region about the tie-bar residual characterized by a recessed height. The overmold may define a notch recessed from an outer edge of the overmold. The notch may be located across the tie-bar residual.

A thermoplastic composition includes: (a) poly(cyclohexylenedimethylene terephthalate) (PCT) or a copolymer thereof; (b) at least 10 wt % of a reinforcing filler comprising glass fiber; (c) a laser direct structuring (LDS) additive comprising a tin oxide, an antimony oxide, or a combination thereof; and (d) a reflection additive comprising a titanium compound. A weight ratio of total titanium in the composition to the LDS additive in the composition is at least 0.7:1, or a weight ratio of total titanium in the composition to the PCT is 1.1:1 or less.

The present invention relates to an assembly to be used in an inkjet printer, an inkjet printer and a method for printing. The assembly comprises (i) a first fixture configured to hold a first print head; and (ii) at least two processing lines A, B, C, D, wherein each processing line A, B, C, D includes a first printing section in which a functional layer is printed on a surface of an electronic device, a sintering section spaced apart from the first printing section and configured to sinter the functional layer, wherein the sintered functional layer exhibits a crystal lattice structure, and a transport mechanism (4) configured to move from the printing section to the sintering section. The first fixture is movable from one processing line A, B, C, D to another processing line A, B, C, D.

Disclosed are special component carriers made of MID-capable plastic in order to make the geometric arrangement of electrical components, such as microprocessors, LEDs, sensors, antennas and the like, on a circuit board more flexible. Said component carriers can have a standardized footprint for connecting to the circuit board and can be adapted to the terminals and the geometric arrangement of the components using individually applied conducting tracks, in particular in an LDS process. Furthermore, the specially shaped component carriers allow the electrical components to be geometrically oriented, in particular at a right angle to the circuit board and parallel to the circuit board, which is especially highly advantageous for antennas and acceleration sensors. Furthermore, SMT soldering is made possible in the pre-mounted state even for temperature-sensitive components.

A PCB for wireless power transfer includes an antenna and the antenna includes a coil. A method for manufacturing the PCB includes providing a prefabricated PCB, the prefabricated PCB including a PCB design and a first area and providing a first sheet of a conductive metal for the first area. The method includes applying an etch resistant coating on a coil area within the first area and laser cutting the first sheet within the coil area, based on a laser cutting path for a first plurality of turns for a first layer of the coil, the first geometry configured wireless power transfer. The method further includes substantially exposing the first sheet to an etching solution, the etching solution substantially removing first portions of the conductive metal from the substrate to define, at least, first turn gaps between at least two of the first plurality of turns.

A flexible circuit (FC) and a method of forming the FC each include providing a first dielectric layer, applying a plurality of conductive circuit traces that are substantially parallel to each other to the first dielectric layer, providing a second dielectric layer atop the first dielectric layer and the plurality of conductive circuit traces to form a third dielectric layer having the plurality of conductive traces disposed therein and being configured to support and insulate the plurality of conductive traces, and forming a plurality of channels extending at least partially through a thickness of the third dielectric layer, wherein the plurality of channels are arranged between the plurality of conductive circuit traces and substantially parallel thereto and are configured to provide increased flexibility of the FC.

A method for manufacturing a wiring substrate includes preparing a substrate including an insulating layer and metal foils, forming a through hole in the substrate to penetrate through the insulating layer and foils, forming a first plating film on the substrate such that the first film is formed on the entire surface of each metal foil and the inner wall of the hole, laminating one or more resin sheets on the first film such that the resin sheet or sheets cover the first film on the entire surface of a respective one of the foils, pressing the resin sheet or sheets such that resin is extruded from the resin sheet or sheets into the hole and fills space surrounded by the first film inside the hole, removing the resin sheet or sheets, and forming a second plating film on the substrate to cover surface of the resin in the hole.

The method for producing a laminate having a patterned metal foil includes masking the whole surface of a first metal foil in a laminate having the first metal foil, a first insulating resin layer having a thickness of 1 to 200 μm and a second metal foil laminated in this order, and patterning the second metal foil.