The semiconductor device includes first and second semiconductor elements. Each element has an obverse surface and a reverse surface, with a first electrode arranged on the reverse surface, and with a second electrode arranged on the obverse surface. The semiconductor device further includes: a first lead having an obverse surface and a reverse surface; an insulating layer covering the first lead, the first semiconductor element and the second semiconductor element; a first electrode connected to the second electrode of the first semiconductor element; and a second electrode connected to the first lead. The first semiconductor element and the first lead are bonded to each other with the reverse surface of the first semiconductor element facing the lead obverse surface. The second semiconductor element and the first lead are bonded to each other with the reverse surface of the second semiconductor element facing the lead reverse surface.

A film package includes a film substrate, a first semiconductor chip on a first surface of the film substrate, a second semiconductor chip on the first surface of the film substrate, and a first conductive film on the first surface of the film substrate. The first conductive film covers the first semiconductor chip and the second semiconductor chip and includes a slit(s) or a notch(es). The slit(s) or notch(es) is/are disposed in a bridge region between the first semiconductor chip and the second semiconductor chip, in a plan view of the package.

Techniques and mechanisms to facilitate connection with one or more integrated circuit (IC) dies of a packaged device. In an embodiment, the packaged device includes a first substrate coupled to a first side of a package, and a second substrate coupled to a second side of the package opposite the first side. Circuitry, coupled via the first substrate to one or more IC dies disposed in the package, includes a circuit structure disposed at a cantilever portion of the first substrate. The cantilever portion extends past one or both of an edge of the first side and an edge of the second side. In another embodiment, a hardware interface disposed on the second substrate enables coupling of the packaged device to another device.

A semiconductor package includes a package substrate including a fastening section at one end and a connecting terminal section at an opposite end, at least one semiconductor device mounted on the package substrate, at least one heat pipe on the at least one semiconductor device, and a lid on the at least one semiconductor device and the at least one heat pipe. At least one end of the heat pipe is between the at least one semiconductor device and either the fastening section or the connecting terminal section.

A current sensor integrated circuit includes a lead frame having a primary conductor and at least one secondary lead, a semiconductor die disposed adjacent to the primary conductor, an insulation structure disposed between the primary conductor and the semiconductor die, and a non-conductive insulative material enclosing the semiconductor die, the insulation structure, a first portion of the primary conductor, and a first portion of the at least one secondary lead to form a package. The first portion of the at least one secondary lead (between a first end proximal to the primary conductor and a second end proximal to the second, exposed portion of the at least one secondary lead) has a thickness that is less than a thickness of the second, exposed portion of the least one secondary lead. A distance between the second, exposed portion of the primary conductor and the second, exposed portion of the at least one secondary lead is at least 7.2 mm.

A semiconductor device comprising a plurality of semiconductor chips and a plurality of electric wirings. The plurality of semiconductor chips are stacked in a first direction, each semiconductor chip of the plurality of semiconductor chips including a plurality of conductive pads that are aligned in an aligning direction, orthogonal to the first direction. The plurality of semiconductor chips are stacked such that each semiconductor chip is shifted from an adjacent semiconductor chip of the plurality of semiconductor chips by a first predetermined interval in the aligning direction and shifted from the adjacent semiconductor chip by a second predetermined interval in a second direction orthogonal to both the first direction and the aligning direction. The plurality of electric wirings electrically connect the plurality of conductive pads of every other semiconductor chip of the plurality of semiconductor chips, respectively.

A quantum device includes a quantum chip and a holder. The holder includes a pedestal, a recess portion formed in a main surface of the pedestal so as to be opposed to the quantum chip, and a suction tube provided such that in the recess portion, a suction opening is positioned in a bottom surface of the quantum chip.

The present invention is intended to provide a semiconductor module and a semiconductor device that are compatible with various rated currents. A semiconductor module includes a lead frame, and a semiconductor element joined with the lead frame. The lead frame includes a first joining structure and a second joining structure. The first joining structure includes a void part as a part at which the lead frame does not exist, and the second joining structure includes a void part as a part at which the lead frame does not exist. Each of the first joining structure and the second joining structure has a shape such that one of the first joining structure and the second joining structure complements at least part of the void part of the other assuming that the first joining structure and the second joining structure are overlapped.

A disclosed circuit arrangement includes a support structure having first and second posts. Electrically conductive round wire has a round cross-section, and a first portion is wrapped at least partially around the first post. A second portion of the wire extends in a straight line from a point on a perimeter of the first post to a point on a perimeter of the second post, and a third portion of the wire is wrapped at least partially around the second post. The second portion of the round wire defines one or more bond sites. An electronic device is electrically connected to the round wire at one of the one or more bond sites.

The invention provides methods and devices for fabricating printable semiconductor elements and assembling printable semiconductor elements onto substrate surfaces. Methods, devices and device components of the present invention are capable of generating a wide range of flexible electronic and optoelectronic devices and arrays of devices on substrates comprising polymeric materials. The present invention also provides stretchable semiconductor structures and stretchable electronic devices capable of good performance in stretched configurations.