A method of manufacturing a through hole of a substrate includes forming, to the substrate, a cutting hole surrounding a removal-target-part such that a connection part of the substrate remains, the connection part that connects the removal-target-part that is removed from the substrate and a remaining part other than the removal-target-part that has been removed, along a cutting line of the through hole formed to the substrate; applying plating on an area including an inner peripheral wall face of the cutting hole of the substrate; applying a film covering an opening of the cutting hole on a surface of the substrate applied with the plating and performing exposure and development of the film to form an etching resist covering an area including the opening of the cutting hole; performing etching of the plating applied on the substrate; removing the etching resist; and cutting the connection part to remove the removal-target-part.

A multi-layer ceramic electronic component includes: a ceramic body including internal electrodes laminated in one axial direction and having a main surface facing in the one axial direction; and an external electrode including a base layer including a step portion formed on the main surface, and a plated layer formed on the base layer, the external electrode being connected to the internal electrodes.

An electronic control unit has a substrate that includes a terminal connection portion that is a through hole that extends through the substrate from a first surface to a second surface. A resist opening along an outer edge of the terminal connection portion exposes a circuit pattern from a surface resist layer. A plurality of vias are disposed at positions adjacent to the resist opening in a heat receiving area to facilitate the transfer of heat during a soldering process from the first surface to the second surface.

A printed circuit board includes a plurality of layers including attachment layers and routing layers; and via patterns formed in the plurality of layers, each of the via patterns including first and second signal vias forming a differential signal pair, the first and second signal vias extending through at least the attachment layers; ground vias extending through at least the attachment layers, the ground vias including ground conductors; and shadow vias located adjacent to each of the first and second signal vias, wherein the shadow vias are free of conductive material in the attachment layers. The printed circuit board may further include slot vias extending through the attachment layers and located between via patterns.

A method for positioning at least one electronic component (3) on a circuit board (1) provided for installation in a vehicle headlamp, wherein the circuit board (1) comprises at least one position mark and the at least one electronic component (3) is positioned relative to the at least one position mark on the circuit board (1), wherein the at least one position mark is detected optically and is used for positioning, wherein the at least one position mark used is at least one alignment mark (5, 6, 7, 8, 8, 8) of the circuit board (1) which, in the vehicle headlamp, when the circuit board (1) is installed, interacts mechanically with a positioning means (9, 15) of the vehicle headlamp that is complementary to the alignment mark (5, 6, 7, 8,8, 8).

A glass substrate includes a first surface and a second surface that are opposite to each other. Multiple through holes pierce through the glass substrate from the first surface to the second surface. Each of five through holes randomly selected from the multiple through holes includes a first opening at the first surface and a second opening at the second surface. The approximate circle of the first opening has a diameter greater than a diameter of the approximate circle of the second opening. The first opening has a roundness of 5 m or less. Perpendicularity expressed by P=t.sub.c/t.sub.0 ranges from 1.00000 to 1.00015, where P is the perpendicularity, t.sub.c is the distance between the center of the approximate circle of the first opening and the center of the approximate circle of the second opening, and t.sub.0 is the thickness of the glass substrate.

A circuit module includes a substrate on which a first electrode and a second electrode are provided, a first electronic component, and a first resin layer. The first electrode includes a first electrode base body and a first plating film. The second electrode and the first electronic component are covered with the first resin layer. The second electrode includes a second electrode base body, a metal column, whose one end is directly connected to the second electrode base body and another end is positioned in an inner side relative to an outer surface of the first resin layer, a second plating film with a cylindrical shape covering a side surface of a connection body of the second electrode base body and the metal column, and a covering portion connected to the other end of the metal column.

A multilayer board includes a flexible base material including laminated insulator layers and curved along an X-axis direction on a plane orthogonal or substantially orthogonal to a lamination direction, an interlayer connection conductor on the flexible base material, and a notch pair on the flexible base material at positions symmetrical or substantially symmetrical in the X-axis direction with respect to a position of the interlayer connection conductor, the notch pair extending in a Y-axis direction orthogonal or substantially orthogonal to the X-axis direction on the plane. The interlayer connection conductor is within a region defined by the notch pair and lines respectively joining ends of the notch pair in the Y-axis direction. A radius of curvature of a region of the flexible base material between the notch pair in the X-axis direction being greater than curvature radii of regions outside of the notch pair.

An electronic device includes a first substrate, a second substrate, plural conductive pads, plural hole structures, plural connection pads and plural conductive structures. Hole structures penetrate through the first and second substrates, and are arranged corresponding to the conductive pads. Second ends of hole structures are located at the second substrate, and the corresponding conductive pad is exposed by one of the second ends. Connection pads enclose first ends of hole structures. Conductive structures are arranged in the hole structures and electrically connected to corresponding conductive pads and connection pads. The second diameter portion of each conductive structure penetrates through first substrate and conductive pad and is electrically connected to corresponding connection pad and conductive pad, and first diameter portion thereof penetrates through second substrate and is electrically connected to corresponding conductive pad. Each conductive pad defines an opening, which is exposed by second end of corresponding hole structure.

The present disclosure relates to a core-substrate, a substrate, a use of the substrate, and a semiconductor device comprising the same, wherein the core-substrate is a core-substrate applied to the manufacture of a semiconductor packaging substrate, and the core-substrate distinguished into a product area where a product utilized as a substrate of an individual semiconductor is disposed; and a blank area excepting for the product area, wherein the blank area comprises a protective area disposed between the product area and the substrate, and the protective area comprises a concave or a via. The embodiment can substantially suppress the occurrence of damage in the product area utilized as a substrate for semiconductor packaging, even though a core-substrate which may be easily broken by external impact.