A chip package structure and an electronic equipment may reduce probability of short circuit failure during chip packaging and improve chip reliability. The chip package structure includes: a chip, a substrate, and a lead; the chip is disposed above the substrate; wherein the chip includes a pin pad and a test metal key, and the lead is configured to electrically connect the pin pad and the substrate; the test metal key is disposed in an edge region of the chip that is not under the lead.

A semiconductor device includes two or more semiconductor elements, a lead with island portions on which the semiconductor elements are mounted, a heat dissipation member for dissipating heat from the island portions, a bonding layer bonding the island portions and the heat dissipation member, and a sealing resin covering the semiconductor elements, the island portions and a part of the heat dissipation member. The bonding layer includes mutually spaced individual regions provided for the island portions, respectively.

A method for manufacturing a semiconductor device includes (i) a step of preparing a first semiconductor chip having a first electrode pad thereon and a second semiconductor chip having a second electrode pad thereon and larger in thickness than the first semiconductor chip, the second electrode pad being larger in size than the first electrode pad, (ii) a step of mounting the first semiconductor chip and the second semiconductor chip on the same planarized surface of a substrate having a uniform thickness, (iii) a step of bonding a ball formed by heating and melting a bonding wire to the second electrode pad, (iv) a step of first-bonding the bonding wire to the first electrode pad, and (v) a step of second-bonding the bonding wire to the ball.

A half-bridge power semiconductor module includes an insulating wiring board including a positive-electrode wiring conductor, a bridge wiring conductor, and a negative-electrode wiring conductor arranged on or above a single insulating plate in such a way as to be electrically insulated from each other. The back-surface electrodes of a high-side power semiconductor device and a low-side power semiconductor device are joined to the front sides of the positive-electrode wiring conductor and the bridge wiring conductor. Front-surface electrodes of the high-side power semiconductor device and the low-side power semiconductor device are connected to the bridge wiring conductor and the negative-electrode wiring conductor by a plurality of bonding wires and a plurality of bonding wires.

A current sensor device may include a routable molded lead frame that includes a molded substrate. The current sensor device may include a conductor and a semiconductor chip mounted to the molded substrate. The semiconductor chip may include a magnetic field sensor that is galvanically isolated from the conductor by the molded substrate and is configured to sense a magnetic field created by current flowing through the conductor. The current sensor device may include one or more leads configured to output a signal generated by the semiconductor chip. The one or more leads may be galvanically isolated from the conductor by the molded substrate.

The subject disclosure relates generally to a method of implementing magnetic shielding walls with specific respective dimensions to reduce crosstalk between transmission lines in wire-bonds for supercomputing chipsets. In one embodiment, the device comprises: a chip-set comprised of superconducting materials; at least one superconducting data line attached to chip-set dies by a set of wire bonds; and magnetic shielding walls that respectively isolate the set of wire bonds.

Generally discussed herein are systems and apparatuses that can include apparatuses, systems, or method for a flexible, wire bonded device. According to an example an apparatus can include (1) a first rigid circuit comprising a first plurality of bond pads proximate to a first edge of the first rigid circuit, (2) a second rigid circuit comprising a second plurality of bond pads proximate to a first edge of the second rigid circuit, the second rigid circuit adjacent the first rigid circuit and the first edge of the second rigid circuit facing the first edge of the first rigid circuit, or (3) a first plurality of wire bonded wires, each wire bonded wire of the first plurality of wire bonded wires electrically and mechanically connected to a bond pad of the first plurality of bond pads and a bond pad of the second plurality of bond pads.

A semiconductor device package includes an electronic component, a first substrate, a first bonding wire and a second substrate. The electronic component has a first surface. The first substrate is disposed on the first surface of the electronic component. The first bonding wire electrically connects the first substrate to the electronic component. The second substrate is disposed on the first surface of the electronic component. The second substrate defines an opening accommodating the first substrate and the first bonding wire.

The invention discloses a parallel electrode combination, which includes a first power module electrode and a second power module electrode, wherein a soldering portion of the first power module electrode and a soldering portion of the second power module electrode are respectively used to connect a copper layer of a power source inside a power module, and a connecting portion of the first power module electrode and a connecting portion of the second power module electrode are opposite in parallel. The invention further discloses a power module and a power module group using the parallel electrode combination. In the invention, the connecting portion of the first power module electrode and the connecting portion of the second power module electrode are opposite in parallel.

A method and a device for establishing a wire connection between a first contact surface and at least one further contact surface. A contact end of a wire is positioned in a contact position relative to the first contact surface with a wire guiding tool. Subsequently, a mechanical, electrically conductive connection is established between the first contact surface and the contact end with a first solder material connection, and subsequently the wire guiding tool is moved to the further contact surface thus forming a wire section and establishing a further mechanical, electrically conductive connection between the wire section end and the further contact surface with a further solder material connection.