A light device may include a printed circuit board having at least one conductive section. An LED may be electrically connected and fixed on a conductive section of the printed circuit board by means of a soldered connection. The printed circuit board may also include a coating-type insulating layer and/or the conductive section has an edge. The fixing region of the LED is connected to a discharge space by means of an outlet, so that during the production process, melted solder can flow off in a defined manner. The arrangement and/or embodiment of the outlet is such that in a preferred direction of movement of the LED is developed in order to position same in a defined manner.

The manufacturing method includes (a) preparing first printed circuit board and second printed circuit board, the first printed circuit board being provided with a plurality of first terminals, the second printed circuit board being provided with a plurality of second terminals, and the first terminals or the second terminals being coated with solders; and (b) connecting the first terminals and the second terminals, respectively, via respective solders by performing thermocompression on connecting portions of the first printed circuit board and the second printed circuit board. Each second terminal includes a first end portion and a second end portion in a long axis direction, and in the step (b), pressure is applied to each second terminal such that the height of each of the first end portion and second end portion is larger than the height in another portion of the second terminal.

A component-embedded substrate includes a cavity including through-holes penetrating through resin sheets in a stacked body of resin sheets having flexibility. An electronic chip component including external electrodes is disposed in the cavity. The resin sheet on which the electronic chip component is located is provided with through-holes into which conductive pastes are filled. The resin sheet includes cut-away portions communicating with a through-hole and located at a distance from each other across the through-hole. When this stacked body is hot-pressed, the conductive pastes overflow from the through-holes. However, the overflowing conductive pastes enter the cut-away portions.

Heat-assisted wiring traces and a conductive support substrate are respectively formed on first and second surfaces of an insulating layer. Further, connection terminals electrically insulated from the support substrate and electrically respectively connected to the heat-assisted wiring traces are formed on the second surface of the insulating layer. Each connection terminal has an element connection portion, a pattern connection portion and a spread blocking portion. When a circuit element is connected to the element connection portion of the connection terminal by solder, spreading of a molten solder applied to the element connection portion to the pattern connection portion is blocked by the spread blocking portion.

A process of fabricating a circuit includes providing a first sheet of dielectric material including a first top surface having at least one first conductive trace and a second sheet of dielectric material including a second top surface having at least one second conductive trace, depositing a first solder bump on the at least one first conductive trace, applying the second sheet of dielectric material to the first sheet of dielectric material with bonding film sandwiched in between, bonding the first and second sheets of dielectric material to one another, and providing a conductive material to connect the first solder bump on the at least one first conductive trace to the at least one second conductive trace.

A printed circuit board includes a circuit board body and a solder pad row disposed on a back of the circuit board body. The solder pad row includes a solder thief pad and a plurality of circular pin solder pads. An outline of an edge, on the solder thief pad proximate to the pin solder pads is an arc that is concave toward the solder thief pad.

An electronic device and an electromagnetic shielding frame are provided. The electromagnetic shielding frame includes a ring-shaped portion and a plurality of soldering tabs that extend from the ring-shaped portion along a protruding direction. The soldering tabs are spaced apart from each other and are in a ring-shaped arrangement. At least one of the soldering tabs has a patterned slot layout so as to be defined as a patterned tab. A portion of the patterned slot layout of the patterned tab arranged away from the ring-shaped portion has a layout distance. The patterned slot layout is arranged along a first direction and a second direction. The first direction and the protruding direction have a first angle therebetween that is smaller than 90 degrees, and the second direction and the protruding direction have a second angle therebetween that is smaller than 90 degrees.

A printed circuit board includes an internal insulating layer, an internal conductive pattern layer disposed on the internal insulating layer and including a line portion and a bonding pad portion, and an external insulating layer disposed on the internal conductive pattern layer and the internal insulating layer and having an accommodation groove extending therethrough to expose the bonding pad portion. The bonding pad portion includes a connection pattern extending from the line portion of the internal conductive pattern layer embedded in the external insulating layer, and exposed to the accommodation groove; a land pattern disposed closer to a center portion of the accommodation groove than the connection pattern; and a dam pattern connecting the connection pattern and the land pattern, in which a line width of the dam pattern is narrower than a line width of the land pattern.

A process of fabricating a circuit includes providing a first sheet of dielectric material including a first top surface having at least one first conductive trace and a second sheet of dielectric material including a second top surface having at least one second conductive trace, depositing a first solder bump on the at least one first conductive trace, applying the second sheet of dielectric material to the first sheet of dielectric material with bonding film sandwiched in between, bonding the first and second sheets of dielectric material to one another, and providing a conductive material to connect the first solder bump on the at least one first conductive trace to the at least one second conductive trace.

An electronic device and an electromagnetic shielding frame are provided. The electromagnetic shielding frame includes a ring-shaped portion and a plurality of soldering tabs that extend from the ring-shaped portion along a protruding direction. The soldering tabs are spaced apart from each other and are in a ring-shaped arrangement. At least one of the soldering tabs has a patterned slot layout so as to be defined as a patterned tab. A portion of the patterned slot layout of the patterned tab arranged away from the ring-shaped portion has a layout distance. The patterned slot layout is arranged along a first direction and a second direction. The first direction and the protruding direction have a first angle therebetween that is smaller than 90 degrees, and the second direction and the protruding direction have a second angle therebetween that is smaller than 90 degrees.