A second lead frame is set onto a conductive layer and a busbar. The second lead frame has holes previously formed at opposite ends thereof, and pieces of solder material or solder pieces are inserted into the holes. Then, the solder pieces are vibrated by an ultrasonically vibrating tool, whereby the solder pieces are melted without having a high temperature. The second lead frame is thus bonded to the conductive layer and the busbar. A semiconductor element and the busbar are connected by a first lead frame and the second lead frame. The connection structure thereof is such that the second lead frame to be bonded by ultrasonic bonding or other bonding methods is not directly in contact with the semiconductor element, which eliminates the risk of damage to the semiconductor element.

IC device assemblies including a power delivery bus board that is mounted to a primary PCB (i.e., motherboard) that further hosts a power-sink device and a power-source device. The bus board, as a secondary PCB, may be surface-mounted on a back side of the primary PCB opposite the power source and sink devices, which are mounted on the front side of the primary PCB. The bus board need only be dimensioned so as to bridge a length between first and second back-side regions of the primary PCB that are further coupled to a portion of the front-side pads employed by the power-sink device. The secondary PCB may be purpose-built for conveying power between the source and sink devices, and include, for example, short, wide traces, that may be formed from multiple heavyweight metallization layers.

The present disclosure describes light systems in which the intensity of base color LEDs configured to emit light within a target color region is increased using additional white LEDs and the emitted light is filtered so that a dominant portion of light passing through the filter at a particular viewing angle is within the target color region. The present disclosure also describes methods for forming a printed circuit board with an integral heat sink arrangement by depositing additional solder on solder pads that are not used to connect electronic components so that the additional solder acts as a heat sink.

A dispensing system for depositing material on an electronic substrate includes a frame, a dispensing unit gantry movably coupled to the frame, a dispensing unit coupled to the dispensing unit gantry, a vision system gantry coupled to the frame, and a vision system coupled to the vision system gantry. A controller is configured to manipulate the vision system with the vision gantry system to move to the position defined by a feature, to acquire an image of at least a portion of a feature, to search for an edge of interest along a center of the image, and to return a value indicating an offset of zero (0), which is interpreted as the location that is exactly as expected, and an offset that reflects where the edge of interest intersected that axis location.

A substrate for mounting an electronic component includes a base material including insulating resin, a first conductor layer formed on first surface of the material, a second conductor layer formed on second surface of the material, and a metal block inserted into a hole penetrating through the first conductor, material and second conductor such that the metal block is fitted in the hole. The material has a bent portion in contact with the metal block in the hole such that the bent portion is bending toward the second conductor, the metal block has surface on first conductor side such that the surface has an outer peripheral portion having a curved-surface shape, and the hole has a first fitting inlet on the first conductor layer side and a second fitting inlet on second conductor side and that the metal block is positioned in contact with the second fitting inlet.

An electrode structure on a circuit board, the electrode structure comprising a metal structure disposed on and electrically connected to the circuit board, wherein the metal structure and a surface of the circuit board forms a space therebetween, wherein at least one first electrical component is disposed in the space and an outer surface of the metal structure forms an electrode for electrically connecting with an external component.

A module includes a PCB including a substrate, a component pad and at least one wire pad, an SMT component mounted to a component pad, a wire fence, a mold compound and a top conductive layer. Each wire pad is connected to ground by a corresponding via extending through the substrate, and the wire fence includes wire loops connected to each wire pad. The mold compound is disposed over the PCB, the SMT component and the wire fence, and defines multiple holes extending partially through the mold compound to top-edges of the wire loops, respectively, where a conductive material fills the holes. The top conductive layer is disposed over the mold compound, and is in electrical contact with the conductive material filling the holes. The wire fence, the conductive material, and the top conductive layer provide shielding of the SMT component from electromagnetic radiation.

A method of forming an electronic device is described which comprises a stack of electronic components wherein each electronic component comprises a face and external terminations. A component stability structure is attached to at least one face. A circuit board is provided wherein the circuit board comprises circuit traces arranged for electrical engagement with the external terminations. The component stability structure mechanically engages with the circuit board and inhibits the electronic device from moving relative to the circuit board.

A bonding structure bonds a Cu wiring line and a device electrode with each other. The bonding structure is arranged between the Cu wiring line and the device electrode, and comprises a first intermetallic compound (IMC) layer (a layer of an intermetallic compound of Cu and Sn) formed on the interface with the Cu wiring line, a second intermetallic compound (IMC) layer (a layer of an intermetallic compound of Cu and Sn) formed on the interface with the device electrode, and an intermediate layer that is present between the intermetallic compound layers. In the intermediate layer, a network-like IMC (a network-like intermetallic compound of Cu and Sn) is present in Sn.

A flexible printed wiring board according to an aspect includes an insulating base film and a conductive pattern stacked on one surface side of the base film. The flexible printed wiring board further includes one or more square-shaped connecting terminals stacked over the conductive pattern with solder in between on one edge side of the conductive pattern. The connecting terminal is made of metal and includes a bent portion with both ends bent opposite to the base film. The connecting terminal includes a plated layer on an outer surface side of the bent portion.