According to one aspect of the present invention, a lead-free solder alloy includes 2% by mass or more and 3.1% by mass or less of Ag, more than 0% by mass and 1% by mass or less of Cu, 1% by mass or more and 5% by mass or less of Sb, 3.1% by mass or more and 4.5% by mass or less of Bi, 0.01% by mass or more and 0.25% by mass or less of Ni, and Sn.

Embodiments of the invention are directed to an integrated circuit (IC) package assembly, including: one or more printed circuit boards (PCBs); and a set of chip packages, each including: an overmold; and an IC chip, overmolded in the overmold, and wherein: the chip packages are stacked transversely to an average plane of each of the chip packages, thereby forming a stack wherein a main surface of one of the chip packages faces a main surface of another one of the chip packages; and each of the chip packages is laterally soldered to one or more of said one or more PCBs and arranged transversally to each of said one or more PCBs, whereby an average plane of each of said one or more PCBs extends transversely to the average plane of each of the chip packages of the stack. Further embodiments are directed to related devices and fabrication methods.

Computer modules with small thicknesses and associated methods of manufacturing are disclosed. In one embodiment, the computer modules can include a module substrate having a module material and an aperture extending at least partially into the module material. The computer modules can also include a microelectronic package carried by the module substrate. The microelectronic package includes a semiconductor die carried by a package substrate. At least a portion of the semiconductor die extends into the substrate material via the aperture.

Computer modules with small thicknesses and associated methods of manufacturing are disclosed. In one embodiment, the computer modules can include a module substrate having a module material and an aperture extending at least partially into the module material. The computer modules can also include a microelectronic package carried by the module substrate. The microelectronic package includes a semiconductor die carried by a package substrate. At least a portion of the semiconductor die extends into the substrate material via the aperture.

A semiconductor package module may include a first substrate, and a second substrate disposed to face the first substrate. The semiconductor package module may include an interconnection member electrically connecting the first substrate to the second substrate and including a plurality of wires. Portions of the plurality of wires may be twisted and wound together and may be bent to extend in a predetermined direction.

The circuit board assembly includes a first circuit board having a first plurality of electronic components attached to a major surface of the first circuit board. The first plurality of electronic components is electrically interconnected to a first plurality of conductive pads defined on the major surface of the first circuit board. A second circuit board has a second plurality of electronic components attached to a first major surface of the second circuit board. The second plurality of electronic components is electrically interconnected to a second plurality of conductive pads defined on a second major surface of the second circuit board. The first and second circuit board are attached by coupling the first and second plurality of conductive pads. A portion of the first plurality of electronic components on the first circuit board are disposed within a cavity defined by the second major surface of the second circuit board.

A mounting member includes a plurality of internal connecting portions, each of which is electrically connected to an electronic device, and a plurality of external connecting portions, each of which is soldered, wherein the plurality of external connecting portions include a first connecting portion in communication with at least any of the plurality of internal connecting portions, and a second connecting portion different from the first connecting portion, and surfaces of the first connecting portion and the second connecting portion include gold layers, and a thickness of the gold layer of the second connecting portion is smaller than a thickness of the gold layer of the first connecting portion.

Method and apparatus for bonding an electrical circuit component onto a substrate. A first electrically conductive bonding pad is formed on the component, and a second electrically conductive bonding pad is formed on the substrate. One of said first and second bonding pads is physically split into at least two parts, with electrical discontinuity between the two parts. An electrically conductive bond is formed between the first and second bonding pads such that electrical continuity is established from one part of the one bonding pad, through the other of the bonding pads, and through the second part of the one bonding pad. The integrity of the electrically conductive bond is evaluated by testing electrical continuity between the at least two parts.

A leadless chip carrier comprises a thermal pad for attaching to a printed circuit board (PCB) and an integrated circuit electrically connected to a plurality of electrical lead frame pads for connection to a plurality of corresponding pads on the PCB. The leadless chip carrier further comprises a non-collapsible conductive shim bonded to a first surface of the thermal pad and each of the plurality of electrical lead frame pads is attached to a volume of solder. The conductive shim provides a stand-off between the thermal pad and the PCB and improves the integrity of a joint between the thermal pad and the PCB.

The present disclosure provides a semiconductor module comprising a semiconductor device removably pressed-fit in a cavity formed in a printed circuit board and methods for manufacturing the same. The semiconductor device and the cavity of the printed circuit board can cooperate with each other and act as an electrical plug and an electrical socket respectively. Soldering the semiconductor device on the printed circuit board can be avoided. Therefore, the packaging process can be more flexible and reliability issues with solder joints can be eliminated. Moreover, heatsink can be mounted on top and/or bottom of the semiconductor device after being received in the cavity of the printed circuit board. Thermal dissipation efficiency can be greatly enhanced.