A semiconductor module includes a semiconductor device having a first land, a second land, and a third land, a wiring board having a substrate, and a fourth land, a fifth land, and a sixth land disposed on the main surface of the substrate, a chip component having a first electrode and a second electrode disposed across a distance in the longitudinal direction and being disposed between the wiring board and the semiconductor device, a first solder joint for bonding the first land, the fourth land, and the first electrode, a second solder joint for bonding the second land, the fifth land, and the second electrode, and a third solder joint for bonding the third land and the sixth land. The volume of the first solder joint and the volume of the second solder joint are each larger than the volume of the third solder joint.

An electronic device includes a processor and a printed circuit board on which the processor is mounted. The printed circuit board includes a first circuit board, a first interposer formed on a first portion of the first circuit board, a second interposer formed on a second portion of the first circuit board that is adjacent to the first portion, a second circuit board coupled to the first interposer, and a third circuit board coupled to the second interposer.

An electronic component and a board having the same mounted thereon are provided. The electronic component includes an electronic component including a capacitor array in which a plurality of multilayer capacitors including a capacitor body and a pair of external electrodes, respectively disposed on both end portions of the capacitor body in a first direction, are stacked in a second direction, perpendicular to the first direction, and a length of a multilayer capacitor, disposed on a lower end in the second direction, in the first direction is less than a length of another multilayer capacitor in the first direction; and a pair of metal frames, respectively disposed to be connected to the pair of external electrodes of the multilayer capacitor disposed on the lower end.

The present disclosure provides an assembly structure for providing power for a chip. The assembly structure includes a circuit board configured to provide a first electrical energy; a chip provided with at least one electrical energy input terminal; and a first power converting module provided with at least one power output terminal. The first power converting module is electrically connected to the circuit board and the chip, converts the first electrical energy to a second electrical energy, and supplies the second electrical energy to the chip. The circuit board, the chip and the first power converting module are stacked; and a projection of the at least one electrical energy input terminal of the chip on the circuit board and a projection of the at least one the power output terminal of the first power converting module on the circuit board, are at least partially overlapped.

The present disclosure provides an assembly structure for providing power for a chip and an electronic device using the same. The assembly structure includes: a circuit board, configured to provide a first electrical energy; a chip; a power converting module, configured to electrically connect the circuit board and the chip, convert the first electrical energy to a second electrical energy, and supply the second electrical energy to the chip, wherein the chip, the circuit board and the power converting module are stacked; and a connection component, configured to electrically connect the circuit board and the power converting module. The present disclosure assembles a power converting module with a circuit board and a chip in a stacking manner, which may shorten a current path between the power converting module and the chip, reduce current transmission losses, improve efficiency of a system, reduce space occupancy and save system resource.

Printed circuit board (PCB) substrates include at least one pre-preg layer interposed between one or more electrically conductive layers, power device stacks, each having a power device embedded within the PCB substrate in a vertical stack configuration, and a flat heat pipe positioned between the power device stacks within the at least one pre-preg layer, one surface of the flat heat pipe directly bonded to a first one of the power device stacks and an opposite surface of the flat heat pipe thermally coupled to a second one of the power device stacks.

A medical, particularly a dental or dental surgical, ultrasonic treatment device for generating ultrasonic vibrations and transmitting the ultrasonic vibration to a tool, which can be connected to the ultrasonic treatment device, the medical ultrasonic treatment device having: an ultrasonic vibration generator with a plurality of piezoelectric elements to which an electric voltage can be applied, and a circuit board to supply the plurality of piezoelectric elements with the electric voltage. Furthermore, a method for manufacturing a corresponding medical ultrasonic treatment device is described.

A substrate of an electronic device includes a first set of contact pads and a first set of contact pillars having a height greater than the first set of contact pads. Components are coupled to the first set of contact pads and the first set of contact pillars in traversing directions. The components coupled to the contact pillars are positioned above the components coupled to the first set of contact pads such that at least a first portion of a first side of the component coupled to the contact traces faces a first side of the components coupled to the contact pillars. Stacking passive components in this manner can allow for increased component density without increasing package size.

An interposer of a multilayer ceramic capacitor includes a first through-hole in which a first pass-through conductive portion is provided on an inside wall thereof. A first surface side of the first through-hole is filled with a first conductive joining material that recessed at a central portion thereof as the first through-hole is seen from a second surface toward a first surface. The interposer includes a second through-hole in which a second pass-through conductive portion is provided on an inside wall thereof. A first surface side of the second through-hole is filled with a second conductive joining material that is recessed at a central portion thereof as the second through-hole is seen from a second surface toward a first surface.

The present invention is directed to a multilayer capacitor and a circuit board containing the multilayer capacitor. The capacitor includes a main body containing a first set of alternating dielectric layers and internal electrode layers and a second set of alternating dielectric layers and internal electrode layers. Each set contains a first internal electrode layer and a second internal electrode layer wherein each layer includes a top edge, a bottom edge opposite the top edge, and two side edges that define a main body of the layer. Each layer contains at least one lead tab extending from the top edge of the main body of the layer and at least one lead tab extending from the bottom edge of the main body of the layer wherein the lead tabs are offset from the side edges of the main body of the layer. In addition, external terminals are electrically connected to the internal electrode layers wherein the external terminals are formed on a top surface of the capacitor and a bottom surface of the capacitor opposing the top surface of the capacitor.