A printed circuit board module (10) has a printed circuit board (20) with a first side (21), a second side (22) and a contact hole (30). A sleeve-type via (32) is provided in the contact hole 30. An annular ring (35, 36) is associated with the via (32), on at least one side (33, 34). The annular ring (35, 36) is arranged on the first side (21) or on the second side (22) of the printed circuit board (20). The annular ring (35, 36) is electrically connected to the via (32). The annular ring (35, 36) has an annular ring edge (40), at least in sections. The printed circuit board module (10) has a solder resist layer (50). It extends, at least in sections, from outside the annular ring edge (40) over the annular ring edge (40) to an outer region (42) of the annular ring (35, 36). An inner region (44) not covered with the solder resist layer (50), remains on the annular ring (35, 36).

A method for manufacturing a flexible circuit board is provided. The method for manufacturing a flexible circuit board includes the following steps: providing a carrier substrate, forming a flexible substrate on the carrier substrate, and forming a plurality of circuit strings on the flexible substrate. A flexible circuit board manufactured by the above method is also provided.

According to various embodiments described herein, an article comprises a glass or glass-ceramic substrate having a first major surface and a second major surface opposite the first major surface, and a via extending through the substrate from the first major surface to the second major surface over an axial length in an axial direction. The article further comprises a helium hermetic adhesion layer disposed on the interior surface; and a metal connector disposed within the via, wherein the metal connector is adhered to the helium hermetic adhesion layer. The metal connector coats the interior surface of the via along the axial length of the via to define a first cavity from the first major surface to a first cavity length, the metal connector comprising a coating thickness of less than 12 m at the first major surface. Additionally, the metal connector coats the interior surface of the via along the axial length of the via to define a second cavity from the second major surface to a second cavity length, the metal connector comprising a coating thickness of less than 12 m at the second major surface and fully fills the via between the first cavity and the second cavity.

Provided is a printed wiring board comprising: a substrate; a conductive layer including a land and a wiring and formed on a surface of the substrate, the wiring having a width smaller than the land and drawn from the land; and an insulating layer formed on the conductive layer. The insulating layer has an opening corresponding to a position of the land, and an edge of the opening runs above the land and above one of edges in a width direction of the wiring.

A solder resist is configured such that pattern covering portions of the solder resist covering straight portions of adjacent wiring patterns are separated from each other in an area outside of a resin mold part. Thus, even if the solder resist is cracked, cracks will not be formed so as to connect between the adjacent wiring patterns. As such, even if moisture generated by condensation or the like enters in the crack, it is less likely that a short circuit will occur between the adjacent wiring patterns.

A printed circuit board includes an insulating layer, a circuit pattern on the insulating layer, and a surface treatment layer on the circuit pattern. The surface treatment layer includes a bottom surface having a width wider than a width of a top surface of the circuit pattern.

A semiconductor device has a semiconductor die with a plurality of bumps formed over contact pads on a surface of the semiconductor die. The bumps can have a fusible portion and non-fusible portion. A plurality of conductive traces is formed over a substrate with interconnect sites having a width greater than 20% and less than 80% of a width of a contact interface between the bumps and contact pads. The bumps are bonded to the interconnect sites so that the bumps cover a top surface and side surface of the interconnect sites. An encapsulant is deposited around the bumps between the semiconductor die and substrate. The conductive traces have a pitch as determined by minimum spacing between adjacent conductive traces that can be placed on the substrate and the width of the interconnect site provides a routing density equal to the pitch of the conductive traces.

Provided is a printed wiring board comprising: a substrate; a conductive layer including a land and a wiring and formed on a surface of the substrate, the wiring having a width smaller than the land and drawn from the land; and an insulating layer formed on the conductive layer. The insulating layer has an opening corresponding to a position of the land, and an edge of the opening runs above the land and above one of edges in a width direction of the wiring.

A circuit substrate and a semiconductor package structure are provided. The circuit substrate includes a body and a via hole array. The via hole array includes via hole column units periodically arranged along a first direction. Each via hole column unit includes first to sixth via holes passing through the body and electrically connected to a capacitor. Any two adjacent via holes of the first to sixth via holes transmit power and ground signals. The sixth via hole of one of the via hole column units is adjacent to the first via hole of another one of the via hole column units, which is adjacent to the one of the via hole column units. The sixth via hole of one of the via hole column units and the first via hole of another one of the via hole column units transmit power and ground signals.

A circuit substrate and a semiconductor package structure are provided. The circuit substrate includes a body and a via hole array. The via hole array includes via hole column units periodically arranged along a first direction. Each via hole column unit includes first to sixth via holes passing through the body and electrically connected to a capacitor. Any two adjacent via holes of the first to sixth via holes transmit power and ground signals. The sixth via hole of one of the via hole column units is adjacent to the first via hole of another one of the via hole column units, which is adjacent to the one of the via hole column units. The sixth via hole of one of the via hole column units and the first via hole of another one of the via hole column units transmit power and ground signals.