An electrical component having partial bodies, a base on which the partial bodies are arranged, and at least one connection contact for electrically connecting the partial bodies to a carrier. A method for producing an electrical component having one or more partial bodies is also disclosed.

An electrical component comprises a main body, a fulcrum portion and at least two terminals including a first terminal and a second terminal. Each of the terminals has a first portion and a second portion. The first portion of one of the first terminal and the second terminal is brought into contact with a circuit board when the main body is tilted relative to the circuit board with the fulcrum portion, which acts as a fulcrum, under an insertion state where the terminals are inserted into through-holes, respectively, while none of the terminals are soldered thereto. When the main body is tilted relative to the circuit board with the fulcrum portion, which acts as the fulcrum, under the insertion state, the second portion of one of the first terminal and the second terminal is brought into contact with the circuit board to regulate an excessive tilt of the main body.

An electronic component includes an insulator and an inductor pattern and a capacitor pattern which are arranged in the insulator. The inductor pattern and the capacitor pattern are electrically connected between one end and the other end of the first inductor pattern.

A power distributor of an electrical system of a motor vehicle, including a circuit board, which has a main connection to a main circuit and multiple secondary connections. Each secondary connection is assigned to one secondary circuit and electrically contacted with the main connection via a circuit breaker having two connections. The connections of each circuit breaker are electrically contacted directly with the circuit board. The invention also relates to a circuit breaker.

An electrical connection contact (5) for a ceramic component (2) is specified. The connection contact (5) comprises a first material (M1) and a second material (M2) arranged thereon, wherein the first material (M1) has a high electrical conductivity and the second material (M2) has a low coefficient of thermal expansion.

An electronic device includes a substrate having a top surface, a bottom surface and at least one opening therethrough. The substrate has circuitry. A relay is mounted to the substrate and is electrically connected to the circuitry. The relay has a switching device configured to activate the relay. The switching device has contacts electrically connected to the circuitry. The relay is mounted to the substrate in the opening such that at least a portion of the switching device is positioned above the top surface and at least a portion of the switching device is positioned below the top surface.

Power amplifier assemblies and components are disclosed. According to some embodiments, a power amplifier assembly (10) is provided that includes a power amplifier (12) having a gate lead (14), a drain lead (13) and a source contact surface (15). An extended heat slug (11) is mounted against the source contact surface to conduct heat away (18) from the surface and to extend the electrical path of the source. The extended heat slug has at least a length that is greater than the length of the source contact surface.

A high-power electronics device and a method of forming same are disclosed. The high-power electronics device is formed of a plurality of layers including molding compound, a printed circuit board, electrically conductive contacts, at least one electronic component, and molding compound. In an embodiment, a layer of a dielectric carrier is also provided.

Methods for mounting a power amplifier (PA) assembly having an extended heat slug (11) are disclosed. According to one aspect, a method includes manufacturing a left side PCB (22a) and a right side PCB (22b). The method further includes sliding the left side PCB and the right side PCB inward (30) to encompass the PA assembly so that one of the left and right side PCB is in a position to contact a drain of the PA (13) and so that the other of the left and right side PCB is in a position to contact a gate of the PA (14).

In a method for forming a microelectronic device, a substrate is loaded into a mold press. The substrate has a first surface and a second surface. The second surface is placed on an interior lower surface of the mold press. The substrate has a plurality of wire bond wires extending from the first surface toward an interior upper surface of the mold press. An upper surface of a mold film is indexed to the interior upper surface of the mold press. A lower surface of the mold film is punctured with tips of the plurality of wire bond wires for having the tips of the plurality of wire bond wires extending above the lower surface of the mold film into the mold film. The tips of the plurality of wire bond wires are pressed down toward the lower surface of the mold film to bend the tips over.