A wiring circuit board includes two insulating layers, a wiring layer, a pad portion, and a conductive connection portion. The wiring layer is on one side in a thickness direction of the first insulating layer, and has a contact portion. The second insulating layer is on one side in the thickness direction of the first insulating layer to cover the wiring layer. The pad portion is on one side in the thickness direction of the second insulating layer. The second insulating layer has a through opening portion and having an opening along at least a part of a peripheral end portion of the pad portion. The contact portion of the wiring layer faces the through opening portion. The conductive connection portion, is connected to at least the peripheral end portion of the pad portion, and the contact portion, and electrically connects the wiring layer to the pad portion.

A wiring circuit board includes two insulating layers, a wiring layer, a pad portion, and a conductive connection portion. The wiring layer is on one side in a thickness direction of the first insulating layer, and has a contact portion. The second insulating layer is on one side in the thickness direction of the first insulating layer to cover the wiring layer. The pad portion is on one side in the thickness direction of the second insulating layer. The second insulating layer has a through opening portion and having an opening along at least a part of a peripheral end portion of the pad portion. The contact portion of the wiring layer faces the through opening portion. The conductive connection portion, is connected to at least the peripheral end portion of the pad portion, and the contact portion, and electrically connects the wiring layer to the pad portion.

A circuit board includes a substrate, a first inner circuit layer, a second inner circuit layer, a first insulating layer, a first optical fiber extending along a first direction, an optical component, an electrical component, a transparent insulating layer, a first inclined surface, a first reflective layer, a second inclined surface, a second reflective layer, and a second optical fiber extending along a second direction.

A method for manufacturing a flex inlay is provided. The method includes providing a flexible printed circuit having opposed surfaces. The method includes attaching components to a surface of the flexible printed circuit. The method includes applying a coverlay over at least one surface of the flexible printed circuit, wherein the coverlay is patterned to not cover any components attached to the surface of the flexible printed circuit. The coverlay at least in part forms an essentially planar surface of the flex inlay.

A method for forming resistance on circuit board is provided and includes the following steps. First, a substrate is provided. Next, a second metal layer is provided on the substrate, and the first metal layer is covered by the second metal layer. Then, a resistance is formed on the second metal layer, and the resistance is directly above the first metal layer. Thereafter, the second metal layer is cut so that the edge of the second metal layer is aligned with that of the first metal layer. The second metal layer is separated from the first metal layer. Next, the second metal layer is pressed with a circuit board, and the resistance is attached to a dielectric layer of the circuit board. Then, the second metal layer is etched to form a circuit pattern on the resistance.

Disclosed are a multilayer circuit board manufacturing apparatus and a multilayer circuit board manufacturing method. The present disclosure includes: a plurality of uncoilers configured to supply a plurality of different members; and a compressing machine configured to bond the members, which are supplied from the respective uncoilers, to each other. The compressing machine includes: a belt that rotates in contact with one surface of one of the plurality of members; and a pressing device which is located inside the belt and spaced apart from the belt, and presses the belt toward the member in a non-contact manner.

It is desirable to improve a longevity and reliability of a substrate used within an IC package. By modifying a design of the one or more layout masks used to create planes within a substrate, the resulting planes may have a non-straight pattern on the edges of each plane and may include a predetermined pattern of open spaces filled with dielectric materials in each plane. The improved mechanical strength of the patterned planes can effectively compensate the effect of mismatched thermal expansion during IC testing and deployment, resulting in increased durability and longevity of the package substrates.

To achieve miniaturization. A matching circuit is connected to a connection terminal that is one of an input terminal and an output terminal of an amplifier. A mounting substrate has a ground layer. The matching circuit includes a main line, a sub-line, and an IC chip. The main line is formed of a first conductor pattern intersecting a thickness direction of the mounting substrate, and is connected to a connection terminal of the amplifier. The sub-line is formed of a second conductor pattern intersecting the thickness direction of the mounting substrate, and is connected between the main line and the ground layer. The sub-line is opposed to the main line in the thickness direction of the mounting substrate. The IC chip is disposed on the mounting substrate, and includes an adjustment unit that adjusts impedance conversion characteristics of the matching circuit.

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.

Embodiments provide a multilayer printed circuit board intended to connect electronic components, the board comprising a stack of a plurality of conductive layers, the conductive layers comprising two surface layers and one or more internal layers, the board comprising one or more counterbored holes, each counterbored hole comprising a portion with metallization opening onto one of the two surface layers and a portion without metallization opening onto the other surface layer; the multilayer printed circuit board may advantageously comprise one or more metal pads, each metal pad being joined to one of the two surface layers so as to occult the portion without metallization of a corresponding counterbored hole.