Disclosed is a printed circuit board according to an embodiment. The printed circuit board comprises: a base board; a metal layer, including a pad and a metal line formed in the base board; a solder resist layer that is formed on the base board on which the metal layer is formed and has an opening through which the surface of the metal line is exposed; and an underfill that is formed between the solder resist layer and a semiconductor chip electrically connected to the pad and includes a blocking area formed in the opening.

A semiconductor package provides a low profile connection to a bottom side of the semi-conductor package. The semi-conductor package includes a computer processor die and a substrate. The computer processor die is mounted on to a top surface of the substrate. The substrate is mounted on to a printed circuit board. A voltage regulator is coupled to the printed circuit board. A top surface of the voltage regulator is coupled to a bottom surface of the substrate. The package also includes a connector device. The connector device includes a cable configured to conduct power from an upstream source, and a low-profile connector module attached to an end of the cable. The connector module is configured to interface to a bottom surface of the voltage regulator.

An electrical connector used for connecting an chip module to a printed circuit board includes an insulating housing, a number of terminals and a cover. The insulating housing includes a body portion. The terminals are insert molded in the body portion. The body portion includes an upper face and a lower face. Each of the terminals includes a first soldering portion extending upwardly beyond the upper face and a second soldering portion extending downwardly beyond the lower face. The cover covers the insulating housing. The electrical connector has a simple structure and a simple manufacturing process.

A voltage regulator module includes a first circuit board assembly and a magnetic core assembly. The first circuit board assembly includes a first printed circuit board, a plurality of switch elements and a first molding compound layer. The switch elements are mounted on a first surface of the first printed circuit board. The first molding compound layer is formed on the first surface of the first printed circuit board to encapsulate the switch elements. The magnetic core assembly is arranged beside a second surface of the first printed circuit board, and includes a magnetic core portion and at least one first U-shaped copper structure. The magnetic core portion includes a plurality of openings. Each first U-shaped copper structure is penetrated through two corresponding openings to define two inductors. A first terminal of each inductor and the corresponding switch element are connected in series to define a phase circuit.

A board-to-board connecting structure which adds no significant thickness to a single printed circuit board includes a first circuit board and a second circuit board. The first circuit board includes first circuit substrate, adhesive layer, and second circuit substrate. The first circuit substrate includes first base layer, first inner wiring layer with first pad, and first outer wiring layer defining a receiving space. The second circuit substrate includes insulating layer and two second outer wiring layers. A conductive via in the second circuit substrate connects the two second outer wiring layers. The second circuit board includes second base layer and also two third outer wiring layers each with a second pad. The second circuit board is laterally disposed in the receiving space and one second pad connects to the conductive via and the other to the first pad.

A compliant interconnect with a cylindrical bellows structure is configured to reduce a stress between a substrate and a PCB board. The stress can be caused by a CTE (coefficient of thermal expansion) mismatch, a physical movement, or a combination thereof. The compliant interconnect can be solder to and/or immobilized on one or more coupling structure. Alternatively, the compliant interconnect can include an instant swapping structure (such as a socket) that makes the upgrade of the electronic components easier.

Provided is a printed circuit board including: an insulating layer; electronic devices embedded in the insulating layer; and an adhesive layer for fixing the electronic devices.

A method for forming a Z-directed component for insertion into a mounting hole in a printed circuit board according to one example includes filling a first cavity having a tapered surface with a body material. A first layer of a constraining material is provided on top of the first cavity and has a second cavity having a width that is smaller than the first cavity. The second cavity is filled with the body material. Successive layers of the constraining material are provided on top of the first layer of the constraining material. Cavities of the successive layers of the constraining material are selectively filled with at least the body material to form layers of the main body portion of the Z-directed component. The constraining material is dissipated to release the Z-directed component from the constraining material and the Z-directed component is fired.

An apparatus includes a heat-dissipating substrate, a power circuit and a magnetic assembly. The heat-dissipating substrate includes a thermal contact surface. The power circuit includes at least one switch element in contact with the thermal contact surface of the heat-dissipating substrate. The magnetic assembly includes at least one first electrical conductor and a magnetic core module comprising at least one hole, wherein the at least one first electrical conductor passes through the at least one hole, and a terminal of the at least one first electrical conductor is electrically connected to the at least one switch element. The heat-dissipating substrate, the power circuit and the magnetic assembly are arranged in sequence along a same direction. A projection of the power circuit on the thermal contact surface partially overlaps a projection of the magnetic assembly on the thermal contact surface.

Systems and methods for applying solder to a pin. The methods comprising: disposing a given amount of solder on a non-wettable surface of a planar substrate; aligning the pin with the solder disposed on the non-wettable surface of the planar substrate; inserting the pin in the solder; and/or performing a reflow process to cause the solder to transfer from the planar substrate to the pin.