A printing process for printing an ink pattern on a substrate is provided. The ink pattern to be printed is based on an available pattern layout. The pattern layout defines a desired layout of the ink pattern to be printed. Based on the pattern layout an input image for allocating dot positions of the ink pattern is generated. The printing process includes a step of comparing a scan image with the input image to carry out a quality inspection to detect any print defects in the printed ink pattern. The printing process includes a step of providing a decision on an approval or a rejection of the printed ink pattern. In case of an approval, the substrate can be supplied to a subsequent processing station to finalise the substrate. In case of a rejection, the substrate including print defects can be recycled.

A device embedded substrate (20), includes: an insulation layer (12) including an insulation resin material; an electric or electronic device (4) embedded in the insulation layer (12); a terminal (15) serving as an electrode included in the device (4); a conductor pattern (18) formed on the surface of the insulation layer (12); and a conducting via (21) for electrically connecting the conductor pattern (18) and the terminals (15) with each other. The conducting via (21) is made up of a large-diameter section (21a) having a large diameter and a small-diameter section (21b) having a smaller diameter than that of the large-diameter section (21a), in order starting from the conductor pattern (18) toward the terminal (15). A stepped section (17) is formed between the large-diameter section (21a) and the small-diameter section (21b). The large-diameter section (21a) is formed so as to penetrate a sheet-shaped glass cloth (11) disposed in the insulation layer (12).

A method of manufacturing an intermediate product for an interposer including a glass substrate having a plurality of through holes is provided. The method includes a step of forming a resin layer on a support substrate, and a step of forming a laminated body by adhering the glass substrate having the plurality of through holes on the resin layer. The glass substrate having the plurality of through holes has a thickness within a range of 0.05 mm to 0.3 mm.

A method of forming a self-supported electronic device, including depositing a sacrificial layer on a first surface substrate, wherein the sacrificial layer is substantially soluble in a first solvent. At least one device layer is deposited in a desired pattern on top of the sacrificial layer. The at least one device layer is substantially insoluble in the at least one device layer. The sacrificial layer is at least partially dissolved in the first solvent to release at least a portion of the first device layer from the substrate. The at least one device layer removed from the substrate forms a self-supported electronic device, which is a thin film electronic device having at least a portion thereof that is not supported by a material carrier.

An electronic component mounting structure, manufacturing method and an electronic component product are provided. The electronic component mounting structure comprises a printed circuit board, a metal flange, and a plurality of electronic components provided on the metal flange; a groove is provided on the printed circuit board, a metal layer is coated on a wall of the groove, the metal flange is restricted to the metal layer on the wall and is fixed in the groove, the one or more electronic components are connected to each other through a plurality of wires based on a circuit requirement, an input electrode and an output electrode are provided on the printed circuit board in a portion adjacent to the metal flange, and the input electrode and the output electrode are connected to the one or more electronic components mounted on the metal flange through wires respectively.

A manufacturing method for an electronic device according to the present disclosure includes (i) forming an insulating film on a surface of a cylinder, (ii) forming the insulating film having a via hole on the surface of the cylinder by pressing a relief member against the insulating film to remove a portion of the insulating film facing a protrusion of the relief member, and (iii) providing a precursor of an insulating layer having the via hole filled with conductive ink on a wiring substrate, wherein the via hole faces a wiring of the wiring substrate.

A method of manufacturing an intermediate product for an interposer including a glass substrate having a plurality of through holes is provided. The method includes a step of forming a resin layer on a support substrate, and a step of forming a laminated body by adhering the glass substrate having the plurality of through holes on the resin layer. The glass substrate having the plurality of through holes has a thickness within a range of 0.05 mm to 0.3 mm.

A manufacturing method of the circuit board includes the following. The third substrate has an opening and includes a first, a second and a third dielectric layers. The opening penetrates the first and the second dielectric layers, and the opening is fully filled with the third dielectric layer. The first, the second and the third substrates are press-fitted so that the second substrate is located between the first and the third substrates. Multiple conductive structures are formed so that the first, the second and the third substrates are electrically connected through the conductive structures to define a ground path. A conductive via structure is formed to penetrate the first substrate, the second substrate, and the third dielectric layer of the third substrate. The conductive via structure is electrically connected to the first and the third substrates to define a signal path. The ground path surrounds the signal path.

A multilayer circuit board includes a first substrate and a second substrate in stack. The first substrate is provided with two first pads, two second pads, and two first sub-circuits. The first pads and the second pads are electrically connected to the first sub-circuits. The second substrate has a top surface, a bottom surface, a lateral edge, and two openings. The bottom surface of the second substrate is attached to the top surface of the first substrate. The openings extend from the top surface to the bottom surface of the second substrate. The first pads of the first substrate are in the opening of the second substrate; the second pads of the first substrate are not covered by the second substrate. The second substrate is further provided with a pad on the top surface and a second sub-circuit electrically connected to the pad of the second substrate.

A substrate for mounting a semiconductor device includes an insulating layer having first and second opposed surfaces defining a thickness. First and second electrically conductive lands are included in the insulating layer. The first electrically conductive lands extend through the whole thickness of the insulating layer and are exposed on both the first and second opposed surfaces. The second electrically conductive lands have a thickness less than the thickness of the insulating layer and are exposed only at the first surface. Electrically conductive lines at the first surface of the insulating layer couple certain ones of the first electrically conductive lands with certain ones of the second electrically conductive lands. The semiconductor device is mounted to the first surface of the insulating layer. Wire bonding may be used to electrically coupling the semiconductor device to certain ones of the first and second lands.