A module substrate for a semiconductor module including a wiring substrate having an upper surface and a lower surface opposite to each other and including a wiring formed therein, the wiring substrate having at least one through groove in at least one sidewall and extending in a thickness direction, and a through-groove test terminal including at least one contact pad, a surface of the contact pad being exposed from an inner wall of the through-groove, the contact pad being spaced apart from a vertical plane extending from the sidewall of the wiring substrate may be provided.

Methods for producing a printed circuit board and printed circuit boards are disclosed, including a method in which a slot is formed in a substrate, the substrate having at least three layers with the slot extending through at least two of the layers. The slot has a length and a width with the length being greater than the width. The sidewall of the substrate surrounding the slot is coated with a conductive layer. The conductive layer is separated into at least two segments that are electrically isolated along the side wall of the substrate.

A method of manufacturing a base plate includes the following steps: providing a first substrate, the first substrate including a first base layer, a first copper coating and a second copper coating covered on two sides of the first base layer; opening at least one first hole on the first substrate, the first hole penetrating the first base layer and the first copper; forming a first electroplated coating on the first copper coating, the first copper coating filling the first hole to form a first connecting portion; opening at least one second hole on the first connecting portion and the first electroplated coating to form a plurality of second connecting pins.

A method of manufacturing a base plate includes the following steps: providing a first substrate, the first substrate including a first base layer, a first copper coating and a second copper coating covered on two sides of the first base layer; opening at least one first hole on the first substrate, the first hole penetrating the first base layer and the first copper; forming a first electroplated coating on the first copper coating, the first copper coating filling the first hole to form a first connecting portion; opening at least one second hole on the first connecting portion and the first electroplated coating to form a plurality of second connecting pins.

A printed circuit board assembly includes a first printed circuit board with first surface and second surface with a slit portion and a second printed circuit board with third surface and fourth surface with a first end portion and a second end portion. The first end portion is fitted in the slit portion and a tip of the first end portion protrudes from the second surface. The first printed circuit board includes first electrodes arranged along the slit portion in a longitudinal direction of the slit portion on the second surface. The second printed circuit board includes second electrodes arranged in the first end portion on the third and fourth surfaces. The second electrodes are joined to the first electrodes with solder. The first printed circuit board includes a support fixed to the first surface. The second printed circuit board is attached to the support by an adhesive substance.

A multilayer printed circuit board is provided having a first conductive layer and a first plating resist selectively positioned within the first conductive layer. A second plating resist may be selectively positioned within a second conductive layer. A through hole extends through the first plating resist in the first conductive layer and the second plating resist in the second conductive layer. An interior surface of the through hole is plated with a conductive material except along a length between the first plating resist and the second plating resist. This forms a partitioned plated through hole having a first via segment electrically isolated from a second via segment.

The disclosure relates to an electronic device including an interposer. The interposer includes a substrate and a plurality of connecting structures disposed on the substrate and electrically connecting a first circuit board and a second circuit board disposed in the electronic device. The plurality of connecting structures includes a plurality of via holes formed in the substrate, a plurality of conductive members disposed in the plurality of via holes, an insulating member disposed between the plurality of conductive members, and a plurality of pads disposed on the outer periphery of the plurality of conductive members. The plurality of conductive members may be separately disposed on the substrate to electrically connect with the first and second circuit boards.

A method of manufacturing a base plate includes the following steps: providing a first substrate, the first substrate including a first base layer, a first copper coating and a second copper coating covered on two sides of the first base layer; opening at least one first hole on the first substrate, the first hole penetrating the first base layer and the first copper; forming a first electroplated coating on the first copper coating, the first copper coating filling the first hole to form a first connecting portion; opening at least one second hole on the first connecting portion and the first electroplated coating to form a plurality of second connecting pins.

A printed wiring board includes a main substrate and a rising substrate. A support portion of the rising substrate is inserted into a slit in the main substrate. In a direction in which a plurality of first electrodes are aligned, a width of each of the plurality of first electrodes is larger than a width of each of a plurality of second electrodes, and the width of each of the plurality of second electrodes is arranged to fit within the width of each of the plurality of first electrodes.

A multilayer printed circuit board is provided having a first conductive layer and a first plating resist selectively positioned within the first conductive layer. A second plating resist may be selectively positioned within a second conductive layer. A through hole extends through the first plating resist in the first conductive layer and the second plating resist in the second conductive layer. An interior surface of the through hole is plated with a conductive material except along a length between the first plating resist and the second plating resist. This forms a partitioned plated through hole having a first via segment electrically isolated from a second via segment.