A method of manufacturing a printed board, the method comprising: a first step of preparing a laminate having a base member in which a plurality of layers of glass cloths and a plurality of resin layers are alternately laminated, a first metal layer attached to one surface of the base member, and a second metal layer attached an opposite surface of the base member; a second step of forming a protective layer removable with a predetermined solvent on each of the first metal layer and the second metal layer; and a third step of irradiating the laminate on which the protective layer is formed with a laser beam to thereby form a through-hole penetrating in a thickness direction of the laminate.

A printed circuit board includes an insulating substrate, a plurality of pads on a top surface of the insulating substrate, a protective layer formed on the insulating substrate and having an opening to expose top surfaces of the pads, a bump formed on at least one of the pads and protruding upward of a surface of the protective layer. The bump has a curved lateral side.

A shielded printed wiring board with electromagnetic wave shielding film on both sides thereof is produced by placing electromagnetic wave shielding films on the two sides of the printed wiring board, with ends thereof protruding past an end of the printed wiring board. The protruding ends of the electromagnetic wave shielding films are brought together, with an air gap therebetween, and an initial application of heat and pressure causes the ends of the electromagnetic wave shielding film to adhere to each other, but without completely curing adhesive resin components of the electromagnetic wave shielding films. Protective film layers are removed from the electromagnetic wave shielding films, followed by subsequent application of heat and pressure to complete cure of the adhesive resin and to remove the air gap.

A wiring substrate is manufactured by attaching an adhesive protective film to a metal-foiled laminate sheet, forming bottomed via holes by partially removing the film and an insulating film, filling conductive pastes into the holes, and peeling the film. A wiring substrate is manufactured by forming an adhesive protective layer so as to cover a patterned metal foil on a metal-foiled laminate sheet, forming bottomed step via holes by partially removing the layer and an insulating film, filling conductive pastes into the holes, and peeling off a protective film. The wiring substrate and the second wiring substrate are laminated in such a way that protruding parts of the pastes come into contact with respective protruding parts of the pastes.

A mounting substrate includes a through-hole 13 formed in a substrate 10, a first land part 21, a second land part 31, a first component attaching part 22, a second component attaching part 32, a conductive layer 14, and a filling member 15 filled into a part of the through-hole 13. A shortest distance allowable value L.sub.0 from the center of the first land part 21 to a component 51 is determined on the basis of the volume V.sub.h of a part of the through-hole 15 positioned above a top surface of the filling member 15 on the side of the first land part 21, the length L.sub.1 of the component 51 to be mounted to the first component attaching part 22, and the maximum allowable value of the inclination of the component 51 to be mounted to the first component attaching part 22 relative to the first surface 11 of the substrate 10.

Some embodiments include a method. The method can include providing a carrier substrate having an edge. Further, the method can include providing a cross-linking adhesive, and providing a flexible substrate having an edge. Further still, the method can include coupling the flexible substrate to the carrier substrate using the cross-linking adhesive such that at least a portion of the edge of the flexible substrate is recessed from the edge of the carrier substrate and such that the cross-linking adhesive has an exposed portion of the cross-linking adhesive at an offset portion of the first surface of the carrier substrate between the at least the portion of the edge of the flexible substrate and the edge of the carrier substrate. Meanwhile, the method can include etching the exposed portion of the cross-linking adhesive. Other embodiments of related methods and devices are also disclosed.

A method including: attaching a plurality of conductive tracks to at least one surface of a substrate, depositing a coating comprising at least one halo-hydrocarbon polymer on the at least one surface of the substrate, and soldering through the coating.

Provided is an embedded printed circuit board, including: a first insulating substrate including a first cavity and a second cavity; a first element disposed in the first cavity; an adhesive layer for adhering the first insulating substrate to the first element and including an opening to which the first element is exposed; and an second insulating substrate forming a bonding layer of a lower surface of the first insulating substrate and a bottom surface of the second cavity.

A method for manufacturing a printed wiring board includes forming a removable layer over first pads in central portion of an interlayer insulation layer to mount IC chip, forming on the interlayer and removable layers a resin insulation layer having openings exposing second pads in peripheral portion of the interlayer layer to connect second substrate, forming a seed layer on the resin layer, in the openings and on the second pads, forming on the seed layer a plating resist having resist openings exposing the openings of the resin layer with diameters greater than the openings, filling the resist openings with electrolytic plating such that metal posts are formed in the resist openings, removing the resist, removing the seed layer exposed on the resin layer, and removing the removable layer and the resin layer on the removable layer such that cavity exposing the first pads is formed in the resin layer.

A mounting substrate includes a through-hole 13 formed in a substrate 10, a first land part 21, a second land part 31, a first component attaching part 22, a second component attaching part 32, a conductive layer 14, and a filling member 15 filled into a part of the through-hole 13. A shortest distance allowable value L.sub.0 from the center of the first land part 21 to a component 51 is determined on the basis of the volume V.sub.h of a part of the through-hole 15 positioned above a top surface of the filling member 15 on the side of the first land part 21, the length L.sub.1 of the component 51 to be mounted to the first component attaching part 22, and the maximum allowable value of the inclination of the component 51 to be mounted to the first component attaching part 22 relative to the first surface 11 of the substrate 10.