A method of fabricating a battery protection circuit package according to one aspect of the present invention includes forming a first mounting structure by mounting battery protection circuit elements on a printed circuit board (PCB), forming a second mounting structure by mounting the first mounting structure on a lead frame which comprises an input/output terminal portion for external connection and at least one metal tab for battery cell connection, forming an encapsulation structure by encapsulating the second mounting structure with a molding material to encapsulate at least a part of the battery protection circuit elements while exposing the input/output terminal portion and the at least one metal tab of the lead frame, and bonding at least one flexible printed circuit board (FPCB) to the input/output terminal portion of the encapsulation structure.

A semiconductor-module external terminal includes a bottom portion to be soldered and a terminal body vertically bent from the bottom portion, and the terminal body includes a first groove on a left end side and a second groove on a right end side of a bending portion which is bent immediately above the bottom portion, and the first groove and the second groove are asymmetrical with respect to a center line passing the terminal body in a vertical direction.

A security element intended to be electrically connected to an electronic card. The security element includes: a metal portion, called a dome; a conductive assembly including conductive tracks which are not connected to each other including an outer track and a central track, each having a conductive tab intended to connect them to the electronic card; and a non-conductive support having lumens via which the conductive tabs extend from the conductive tracks to the electronic card. The ends of the conductive tabs are intended to be in contact with the electronic card and do not extend beyond the non-conductive assembly such that the connections between the tracks and the electronic card are located under a lower face of the non-conductive assembly.

A circuit board includes a substrate, a first inner circuit layer, a second inner circuit layer, a first insulating layer, a first optical fiber extending along a first direction, an optical component, an electrical component, a transparent insulating layer, a first inclined surface, a first reflective layer, a second inclined surface, a second reflective layer, and a second optical fiber extending along a second direction.

There is provided a method for implementing an electronic card. The method can include providing the electronic card with a printed circuit board. The method further includes selecting one of a first side and a second side as a specified side on which only connection hardware is to be mounted. The first side is located at a first x-y plane and the second side is located at a second x-y plane, the first and second x-y planes being separated by a length equal to a thickness of the PCB. The first and second x-y planes are parallel.

A method for producing an electronic sensor module includes applying first soldering material onto electrical soldering pads of a printed circuit board element and/or electrical soldering pads of a printed circuit board element contact side of a sensor carrier, arranging the sensor carrier with the electrical soldering pads of the printed circuit board element contact side on the electrical soldering pads of the printed circuit board element to produce electrical connections between connecting lines and the printed circuit board element, applying second soldering material onto electrical connecting elements of a sensor element and/or soldering pads of the sensor receptacle, arranging the sensor element in the sensor receptacle such that the second soldering material produces electrical connections between the electrical connecting elements of the sensor element and the soldering pads of the sensor receptacle, and reflow-soldering the first soldering material and the second soldering material in a joint reflow-soldering process.

A wireless communication device manufacturing system includes: a mounting apparatus including a mounting head mounted with a suction nozzle that sucks and holds an RFIC module including an RFIC chip, a terminal electrode, and a hot melt adhesive layer; a conveyance apparatus configured to convey the antenna base material including an antenna pattern to a mounting position; and a heating apparatus configured to heat the hot melt adhesive layer of the RFIC module. The wireless communication device manufacturing system bonds the RFIC module in a state where the hot melt adhesive layer is softened by heating of the heating apparatus to the antenna base material disposed at the mounting position through the hot melt adhesive layer, and capacitively couples the antenna pattern and the terminal electrode through the hot melt adhesive layer.

An electronic device module includes a first substrate, at least one electronic device mounted on a lower surface of the first substrate, a second substrate mounted on a lower surface of the first substrate to electrically connect the first substrate to an external source of power, a connecting conductor bonded to a lower surface of the second substrate, and a sealing portion sealing the electronic device, the second substrate, and the connecting conductor, wherein a mounting height of the second substrate is configured to be lower than a mounting height of the electronic device.

An apparatus includes a circuit board and a plurality of bus bars fixed to the circuit board. The plurality of bus bars may include a first bus bar and a second bus bar formed from adjacent portions of a bus bar wire. The first bus bar may include a first bus bar first unplated portion and the second bus bar may include a second bus bar first unplated portion. The first bus bar first unplated portion and the second bus bar first unplated portion may be formed during formation of the first bus bar.

The apparatus according to various embodiments includes one or more processors, and one or more memories operatively connected to the one or more processors. The one or more memories may store instructions that, when executed, cause the one or more processors to acquire a plurality of first position offsets of a plurality of first components respectively mounted on a plurality of first substrates with respect to a plurality of pads of the plurality of first substrates corresponding to the plurality of first components from the optical measurement device, set a range of a normal state for a component position offset based on the plurality of first position offsets, generate a control signal for adjusting at least one control parameter of the component mounting device associated with a component mounting position based on the range of the normal state, and transmit the control signal to the component mounting device.