An electronic device includes a bond wire with a first end bonded by a ball bond to a planar side of a first conductive plate, and a second end bonded by a stitch bond to a conductive stud bump at an angle greater than or equal to 60 degrees. A wirebonding method includes bonding the first end of the conductive bond wire to the first conductive plate includes forming a ball bond to join the first end of the conductive bond wire to a planar side of the first conductive plate by a ball bond, and bonding the second end of the conductive bond wire to the conductive stud bump includes forming a stitch bond to join the second end of the conductive bond wire to the conductive stud bump.

A resin enclosure includes: an inner wall portion from a wall surface defining the space to a side surface of the lead terminal close to the space; and a covering portion that covers at least a part of a top surface of a first portion of the lead terminal.

A resin enclosure includes: an inner wall portion from a wall surface defining the space to a side surface of the lead terminal close to the space; and a covering portion that covers at least a part of a top surface of a first portion of the lead terminal.

A wire bonding apparatus according to an embodiment bonds a wire to a bonding portion by generating an ultrasonic vibration in a state of pressing the wire onto the bonding portion. The wire bonding apparatus includes a bonding tool that causes the wire to contact the bonding portion and applies a load, an ultrasonic horn that generates the ultrasonic vibration, a load sensor that continuously detects the load applied from the bonding tool to the bonding portion, and a controller that controls the operation of the bonding tool and the ultrasonic horn. The controller analyzes data of the load output from the load sensor between when the wire contacts the bonding portion and when the ultrasonic vibration is generated, and controls the operation of the bonding tool and the ultrasonic horn based on an analysis result.

A semiconductor device includes a semiconductor element, a first conductive member, a second conductive member, a connecting member, and a metal plate. The semiconductor element has an element obverse surface and an element reverse surface that are spaced apart from each other in a thickness direction. An obverse surface electrode is provided on the element obverse surface. The first conductive member faces the element reverse surface and is bonded to the semiconductor element. The first conductive member and the second conductive member are spaced apart from each other. The connecting member electrically connects the obverse surface electrode and the second conductive member. The metal plate is interposed between the obverse surface electrode and the connecting member in the thickness direction. The obverse surface electrode and the metal plate are bonded to each other by solid-phase diffusion.

A wire bonding tool includes a tool body with a tubular cavity extending through the tool body and a distal end. The distal end includes a flared opening at an end of the tubular cavity. The tool body further includes at least one protrusion at a level of the distal end.

A double-side cooling-type semiconductor device includes a first circuit board and a second circuit board, a semiconductor element bonded to a control electrode of the first circuit board, a first spacer disposed between the first circuit board and the semiconductor element, bonded to the first circuit board, and bonded to the semiconductor element, and a second spacer disposed between the second circuit board and the semiconductor element, bonded to the second circuit board, and bonded to the semiconductor element.

A double-side cooling-type semiconductor device includes a first circuit board and a second circuit board, a semiconductor element bonded to a control electrode of the first circuit board, a first spacer disposed between the first circuit board and the semiconductor element, bonded to the first circuit board, and bonded to the semiconductor element, and a second spacer disposed between the second circuit board and the semiconductor element, bonded to the second circuit board, and bonded to the semiconductor element.

A transistor device includes a substrate, a gate contact pad on the substrate, and a transistor die on the substrate adjacent the gate contact pad. The transistor die includes an active region and a gate bond pad adjacent the active region, and the gate bond pad has a side edge adjacent the active region that extends in a first direction. The transistor device includes a bonding wire bonded to the gate contact pad at a first end of the bonding wire and to the gate bond pad at a second end of the bonding wire. The bonding wire extends in a second direction that is oblique to the first direction such that the bonding wire forms an angle relative to the first direction that is less than 90 degrees.

A transistor device includes a substrate, a gate contact pad on the substrate, and a transistor die on the substrate adjacent the gate contact pad. The transistor die includes an active region and a gate bond pad adjacent the active region, and the gate bond pad has a side edge adjacent the active region that extends in a first direction. The transistor device includes a bonding wire bonded to the gate contact pad at a first end of the bonding wire and to the gate bond pad at a second end of the bonding wire. The bonding wire extends in a second direction that is oblique to the first direction such that the bonding wire forms an angle relative to the first direction that is less than 90 degrees.