A component carrier includes a base structure and an electrically conductive wiring structure on the base structure. The wiring structure has a nonrectangular cross-sectional shape configured so that an adhesion promoting constriction is formed by at least one of the group consisting of the wiring structure and a transition between the base structure and the wiring structure.

A circuit board device includes: a printed wiring board; an IC chip provided on an obverse surface of the board and having at least one ground terminal; and a wiring pattern, disposed on the board, for providing a ground potential to the ground terminal of the IC chip. The wiring pattern is disposed on a reverse surface of the printed wiring board. The circuit board device has at least one via that is connected to the wiring pattern and passes through the printed wiring board at a position within a region where the IC chip is mounted on the obverse surface of the printed wiring board.

In a die-substrate assembly, a copper inter-component joint is formed by bonding corresponding copper interconnect structures together directly, without using solder. The copper interconnect structures have distal layers of (111) crystalline copper that enable them to bond together at a relatively low temperature (e.g., below 300 C.) compared to the relatively high melting point (about 1085 C.) for the bulk copper of the rest of the interconnect structures. By avoiding the use of solder, the resulting inter-component joint will not suffer from the adverse IMC/EM effects of conventional, solder-based joints. The distal surfaces of the interconnect structures may be curved (e.g., one concave and the other convex) to facilitate mating the two structures and improve the reliability of the physical contact between the two interconnect structures. The bonding may be achieved using directed microwave radiation and microwave-sensitive flux, instead of uniform heating.

A printed circuit board includes an insulating layer; an interconnection layer disposed on the insulating layer, and including a plurality of metal pads for mounting a semiconductor chip thereon; and a solder resist layer disposed on the insulating layer and covering the interconnection layer, the solder resist layer having a plurality of openings respectively exposing at least a portion of at least one of the plurality of metal pads. A rectangular region created by substantially connecting outer edges of outermost openings among the plurality of openings in a straight line is substantially equally divided into a plurality of cells, and a ratio of areas of the metal pads disposed in each cell to an area of each cell is calculated, and when a maximum value thereof is P.sub.Max and a minimum value thereof is P.sub.Min, (P.sub.Max?P.sub.Min)*100?20.

A method for manufacturing a flexible printed circuit board, comprising: providing a flexible printed circuit substrate; defining first through holes and second through holes through the flexible printed circuit substrate; and forming first conductive pillars and second conductive pillars; and defining first grooves by removing a portion of each first conductive pillar and defining second grooves by removing a portion of each second conductive pillar; the first grooves and the second grooves are defined from an outer surface of the flexible printed circuit board on the second conductive pattern layer side to a surface of the second conductive pattern layer away from the first conductive pattern layer; each of the first grooves is aligned with and corresponds to one first conductive pillar, and each of the second grooves is aligned with and corresponds to one second conductive pillar.

A circuit board device includes: a printed wiring board; an IC chip provided on an obverse surface of the board and having at least one ground terminal; and a wiring pattern, disposed on the board, for providing a ground potential to the ground terminal of the IC chip. The wiring pattern is disposed on a reverse surface of the printed wiring board. The circuit board device has at least one via that is connected to the wiring pattern and passes through the printed wiring board at a position within a region where the IC chip is mounted on the obverse surface of the printed wiring board.

In a die-substrate assembly, a copper inter-component joint is formed by bonding corresponding copper interconnect structures together directly, without using solder. The copper interconnect structures have distal layers of (111) crystalline copper that enable them to bond together at a relatively low temperature (e.g., below 300 C.) compared to the relatively high melting point (about 1085 C.) for the bulk copper of the rest of the interconnect structures. By avoiding the use of solder, the resulting inter-component joint will not suffer from the adverse IMC/EM effects of conventional, solder-based joints. The distal surfaces of the interconnect structures may be curved (e.g., one concave and the other convex) to facilitate mating the two structures and improve the reliability of the physical contact between the two interconnect structures. The bonding may be achieved using directed microwave radiation and microwave-sensitive flux, instead of uniform heating.

A component carrier includes a base structure and an electrically conductive wiring structure on the base structure. The wiring structure has a nonrectangular cross-sectional shape configured so that an adhesion promoting constriction is formed by at least one of the group consisting of the wiring structure and a transition between the base structure and the wiring structure.

An electronic device mountable in an electrical motor, comprising: a printed circuit board with a hole for mounting a semiconductor package which comprises an integrated magnetic sensing device, the semiconductor package comprising leads; and reinforcement material; wherein the semiconductor package is mounted in the hole with the leads soldered to the printed circuit board, and wherein a gap is present between the semiconductor package and the printed circuit board, wherein the reinforcement material is at least covering part of the leads and at least part of the printed circuit board.

A flexible printed circuit board (PCB), a method for manufacturing the flexible PCB, and a PCB structure having the flexible PCB are disclosed. A flexible printed circuit board includes a first conductive pattern layer, a second conductive pattern layer, a plurality of first conductive pillars, and a plurality of second conductive pillars. Each of the plurality of first conductive pillars electrically connects to the first conductive pattern layer and is spaced from the second conductive pattern layer, and a plurality of second conductive pillars electrically connects to the second conductive pattern layer and is spaced from the first conductive pattern layer. The plurality of first conductive pillars and the plurality of second conductive pillars are exposed from one surface of the flexible printed circuit board to form a plurality of electrical contact pads.