Disclosed is a microsensor package. Particularly, disclosed is a microsensor package, in which a sensing chip is packaged by using PCBs stacked on top of one another, whereby the thickness of the package slim can be kept slim, and at the same time, it can be manufactured at a low cost and can be easily manufactured.

A method for producing a radio-frequency antenna in a conductor structural element with an encompassing layer sequence, including: providing a rigid carrier having an underside and a top side; defining an antenna assignment section on the rigid carrier; applying at least one electrically insulating layer with a recess in such a way that the antenna assignment section is exposed; placing a radio-frequency substrate above the antenna assignment section with formation of a cavity between the rigid carrier and the radio-frequency substrate; aligning and fixing the radio-frequency substrate relative to the rigid carrier; laminating the layer construction prepared in this manner such that resin material of the at least one electrically insulating layer liquefies and encloses the radio-frequency substrate with the cavity being left free; cutting the antenna assignment section out of the rigid carrier from the outer underside (remote from the layer construction) of the rigid carrier.

A multilayer circuit board structure includes superconducting connections to internal layers thereof, for example by inclusion of superconducting vias. Two or more panels can each comprise respective electrically insulative substrates, each have one or more through-holes, and also include a respective bimetal foil on at least a portion of a respective surface thereof, which is patterned to form traces. The bimetal foil includes a first metal that is non-superconductive in a first temperature range and a second metal that is superconductive in the first temperature range. The panels are plated to deposit a third metal on exposed traces of the second metal, the third metal superconductive in the first temperature range. Panels are join (e.g., laminated) to form at least a three-layer superconducting printed circuit board with an inner layer, two outer layers, and superconducting vias between the inner layer and at least one of the two outer layers.

According to one aspect, the invention provides a method of providing conductive structures between two foils in a multi-foil system. The system comprises at least two foils, from which at least one foil comprises a terminal. The method comprises the steps of (in any order) providing at least one solid state adhesive layer, patterning adhesive layer with through-holes; filling the through-holes with conductive material, so as to form the conductive structure, connected to the terminal; and bonding the at least two foils. One advantage of the invention is that it may be used in a manufacturing process for multi-foil systems.

A method of making printed circuit board vias using a double drilling and plating method is disclosed. A first hole is drilled in a core, the first hole having a first diameter. The first hole is filled and/or plated with an electrically conductive material. A circuit pattern may be formed on one or two conductive layers of the core. A multilayer structure may then be formed including a plurality of cores that also include pre-drilled and plated via holes, wherein at least some of the pre-drilled and plated via holes are aligned with the first hole. A second hole is then drilled within the first hole and the aligned pre-drilled and plated holes, the second hole having a second diameter where the second diameter is smaller than the first diameter. A conductive material is then plated to an inner surface of the second hole.

Method for producing a conductor structural element with a layer sequence having an internal layer substrate, including the steps: providing a rigid carrier having an underside and a top side; defining a cut-out section on the rigid carrier; applying at least one electrically insulating layer with a recess in such a way that the cut-out section is exposed; placing an internal layer substrate above the cut-out section with formation of a cavity between the rigid carrier and the internal layer substrate; aligning and fixing the internal layer substrate relative to the rigid carrier; laminating the layer construction prepared in this manner such that resin material of the at least one electrically insulating layer liquefies and encloses the internal layer substrate with the cavity being left free; producing a cut-out by cutting the cut-out section out of the rigid carrier from the outer underside of the rigid carrier.

A method for attaching two electronics boards, e.g., a testing PCB and a space transformer, comprises rack welding resin prepreg and a mylar film to a testing PCB; laser drilling via holes in the resin prepreg and mylar film such that the holes are aligned on one side of the resin prepreg with connection/capture pads on the testing PCB and aligned (after attachment) on the other side of the resin prepreg with connection capture pads on a space transformer, filling the via holes with sintering paste; applying a pressure treatment to remove air, bubbles, and voids from the sintering paste; removing the mylar film; and using a lamination press cycle to attach a space transformer to the resin prepreg.

In a wiring base body of a printed wiring board, a conductive post including a wiring portion and a wiring are embedded in an insulating resin film. Therefore, even in a region in which a wiring portion is formed, the wiring base body is not increased in thickness. In addition, even in a region in which a wiring is formed, the wiring base body is not increased in thickness. Therefore, it is possible to obtain a printed wiring board having high flatness by stacking a plurality of wiring base bodies and constituting a printed wiring board.

A method for manufacturing a multilayer wiring board is disclosed. The method comprises a printed wiring board manufacturing step (I) of preparing printed wiring boards having both electrical connection pads for establishing an electrical connection between the boards and non-connection pads for not establishing an electrical connection between the boards on the same plane; and a lamination step (II) of overlaying the boards so that the electrical connection pads face each other, and laminating the boards so that the boards are bonded to each other through a conductive paste provided between the facing electrical connection pads. In the step (I), (Ia) an insulating film is attached to at least one of surfaces faced when the boards are overlaid in the lamination step (II), (Ib) holes are bored in the insulating film so that the electrical connection pads are exposed, and (Ic) a conductive paste is provided in the holes.

To improve the peel strength of a wiring pattern formed at a cavity bottom portion while enabling connection between an electronic component inside a cavity and a circuit outside the cavity to be performed at the cavity bottom portion. A method of manufacturing a printed wiring board according to the present disclosure includes performing pattern plating on a substrate made of insulating resin. Forming an electrical conductor layer on a seed layer of a second face, forming a first insulating resin layer on a first face and forming a second insulating resin layer. Drilling in and removing the insulating resin to form a cavity. Removing, by laser machining, a remaining portion of the substrate in the cavity and exposing a surface position of the second insulating resin layer to be equivalent to a surface position of the electrical conductor layer embedded in the second insulating resin layer.