An electronic device and methods for fabricating the same are disclosed herein that utilize a dam formed on a printed circuit board (PCB) that is positioned to substantially prevent edge bond material, utilized to secure a chip package to the PCB, from interfacing with the solder balls transmitting signals between the PCB and chip package.

A plug-in connector device has a printed circuit board element, a first plug-in connector element which is electrically and mechanically connected to the printed circuit board element by a soldered connection, and a second plug-in connector element which is electrically and mechanically connected to the printed circuit board element by electrical press-in contacts. The second plug-in connector element has a housing section with a recess in which the first plug-in connector element is arranged in such a way that outer surfaces of the first plug-in connector element make contact with inner surfaces of the recess.

Provided is a connector-mounted board manufacturing method for manufacturing a connector-mounted board, the connector-mounted board including a circuit board, on which a terminal and an electronic component are mounted, and a connector housing attached to the terminal. The connector-mounted board manufacturing method includes: executing a mounting process of mounting the terminal and the electronic component on the circuit board; and executing an attaching process of attaching the connector housing to the terminal after the mounting process has been executed.

A semiconductor device and a method of manufacturing a semiconductor device are provided. The semiconductor device includes a carrier, an element, and a first electronic component. The element is disposed on the carrier. The first electronic component is disposed above the element. The element is configured to adjust a first bandwidth of a first signal transmitted from the first electronic component.

A semiconductor device and a method of manufacturing a semiconductor device are provided. The semiconductor device includes a carrier, an element, and a first electronic component. The element is disposed on the carrier. The first electronic component is disposed above the element. The element is configured to adjust a first bandwidth of a first signal transmitted from the first electronic component.

A method for step-soldering includes applying a first solder alloy having a melting point in a temperature range from 160 to 210° C. to a jointed portion of a first electronic component and a substrate, and heating them in the temperature range from 160 to 210° C., and applying a second solder alloy having the melting point in a temperature range lower than 160° C. to a joint portion of a second electronic component and the substrate, and heating them in the temperature range lower than 160° C. The first solder alloy consists of 13-22 mass % of In, 0.5-2.8 mass % of Ag, 0.5-5.0 mass % of Bi, 0.002-0.05 mass % of Ni and a balance Sn.

A printed circuit board for mounting electrical components thereupon include: a first side; a second side opposite the first side; electrical connection points disposed on the surface of an exterior edge of the printed circuit board; and wherein the exterior edge of the printed circuit board is between the first side and the second side. Further a method of manufacturing a printed circuit board for mounting electrical components thereupon includes the steps of disposing interconnect structures within the printed circuit board adjacent to at least one edge of the printed circuit board; and removing material from the printed circuit board edge to expose the interconnect structures such that the exposed interconnect structures correspond to a component connection footprint.

A die package structure and a method for fabricating the same are provided. The method includes: fixing a first die on a package base; aligning first hollow pads of a flexible printed circuit board with first pads of the first die, and fixing the flexible printed circuit board; soldering the first hollow pads to the first pads; fixing a second die on the flexible printed circuit board to overlap with the first die; folding the flexible printed circuit board, such that second hollow pads of the flexible printed circuit board are aligned with second pads of the second die, and signal test pads of the flexible printed circuit board are exposed; fixing the flexible printed circuit board on the second die; soldering the second hollow pads to the second pads; soldering metal wires to the signal test soldering pads; and soldering package pins to the metal wires.

A battery pack comprises a set of battery cells, a battery cell holder holding the battery cells, at least one battery strap having a first end connected to a terminal of one of the battery cells and a second end extending from the battery cell holder, a printed circuit board having a first side and a second side, components mounted on the second side of the printed circuit board, a trace on the second side of the printed circuit board extending from one components to a contact connected to the trace and mated with the second end of the at least one battery strap. Multiple vias extend from the first side to the second side, and the contact comprises a first portion having a through hole and a leg integrally formed with and approximately perpendicular to the first portion, the leg extending from the first side of the PCB to the second side of the PCB through a first via, the trace extending from the first via, the leg soldered to the second side of the PCB and the via and the through hole aligned with a second via adjacent to the first via, the through hole sized and configured to receive a PCB end of the strap, the PCB end of the strap soldered to the contact.

According to an aspect of the disclosure, an example microelectronic device assembly includes a substrate, a microelectronic element electrically connected to the substrate, a stiffener element overlying the substrate, and a heat distribution device overlying the rear surface of the microelectronic element. The stiffener element may extend around the microelectronic element. The stiffener element may include a first material that has a first coefficient of thermal expansion (“CTE”). A surface of the stiffener element may face toward the heat distribution device. The heat distribution device may include a second material that has a second CTE. The first material may be different than the second material. The first CTE of the first material of the stiffener element may be greater than the second CTE of the second material of the heat distribution device.