According to the present invention, a power module includes an insulating substrate, a semiconductor device provided on the insulating substrate, an internal terminal provided on the insulating substrate and electrically connected to the semiconductor device, a sealing material that seals the internal terminal, the semiconductor device and the insulating substrate so that an end portion of the internal terminal is exposed, a case that is separate from the sealing material and covers the sealing material and an elastic member that connects the case and the end portion of the internal terminal.

According to one embodiment, a semiconductor module includes a first circuit component, a first connection member, and a first wire. The first circuit component includes a first substrate, a first conductive layer, a first switching device, and a first diode. The first substrate has an insulation property. The first connection member is provided on a first electrode of the first switching device and the fourth electrode of the first diode, and has a conductive property. The first wire connects the first conductive layer and the first connection member.

In some examples, a device comprises at least two semiconductor die, wherein each respective semiconductor die of the at least two semiconductor die comprises at least two power transistors, an input node on a first side of the respective semiconductor die, a reference node on the first side of the respective semiconductor die, and a switch node on a second side of the respective semiconductor die. The device further comprises a first conductive element electrically connected to the respective input nodes of the at least two semiconductor die. The device further comprises a second conductive element electrically connected to the respective reference nodes of the at least two semiconductor die.

A power semiconductor module including a positive-side switching device and a positive-side diode device which are mounted on a positive-side conductive pattern, and a negative-side switching device and a negative-side diode device which are mounted on an output-side conductive pattern. When an insulating substrate is viewed in plan view, the positive-side diode device and the negative-side diode device are disposed between the positive-side switching device and the negative-side switching device, and the negative-side diode device is disposed closer to the positive-side switching device than the positive-side diode device is.

A power converter (100) comprising a semiconductor chip (101) with a first (101a) and a parallel second (101b) surface, and through-silicon vias (TSVs, 110). The chip embedding a high-side (HS) field-effect transistor (FET) interconnected with a low side (LS) FET. Surface (101a) includes first metallic pads (111) as inlets of the TSVs, and an attachment site for an integrated circuit (IC) chip (150). Surface (101b) includes second metallic pads (115) as outlets of the TSVs, and third metallic pads as terminals of the converter: Pad (123a) as HS FET inlet, pad (122a) as HS FET gate, pad (131a) as LS FET outlet, pad (132a) as LS FET gate, and gate (140a) as common HS FET and LS FET switch-node. Driver-and-controller IC chip 150) has the IC terminals connected to respective first pads.

A CMOS type semiconductor image sensor module wherein a pixel aperture ratio is improved, chip use efficiency is improved and furthermore, simultaneous shutter operation by all the pixels is made possible, and a method for manufacturing such semiconductor image sensor module are provided. The semiconductor image sensor module is provided by stacking a first semiconductor chip, which has an image sensor wherein a plurality of pixels composed of a photoelectric conversion element and a transistor are arranged, and a second semiconductor chip, which has an A/D converter array. Preferably, the semiconductor image sensor module is provided by stacking a third semiconductor chip having a memory element array. Furthermore, the semiconductor image sensor module is provided by stacking the first semiconductor chip having the image sensor and a fourth semiconductor chip having an analog nonvolatile memory array.

A packaged transistor device (100) comprises a semiconductor chip (101) including a transistor with terminals distributed on the first and the opposite second chip side; and a slab (110) of low-grade silicon (l-g-Si) configured as a ridge (111) framing a depression including a recessed central area suitable to accommodate the chip, the ridge having a first surface in a first plane and the recessed central area having a second surface in a second plane spaced from the first plane by a depth (112) at least equal to the chip thickness, the ridge covered by device terminals (120; 121) connected to attachment pads in the central area having the terminals of the first chip side attached so that the terminals (103) of the opposite second chip side are co-planar with the device terminals on the slab ridge.

An electronic system comprises a first chip of single-crystalline semiconductor shaped as a hexahedron and including a first electronic device embedded in a second chip of single-crystalline semiconductor shaped as a container having a slab bordered by retaining walls, and including a second electronic device. The container shaped as a slab bordered by the retaining walls and including conductive traces and terminals. The first chip is attached to the slab of second chip, forming nested chips. The first and second chips embedded in the container. The nested first and second chips are operable as an electronic system and the container is operable as the package of the system.

A packaged transistor device (100) comprises a semiconductor chip (101) including a transistor with terminals distributed on the first and the opposite second chip side; and a slab (110) of low-grade silicon (l-g-Si) configured as a ridge (111) framing a depression including a recessed central area suitable to accommodate the chip, the ridge having a first surface in a first plane and the recessed central area having a second surface in a second plane spaced from the first plane by a depth (112) at least equal to the chip thickness, the ridge covered by device terminals (120; 121) connected to attachment pads in the central area having the terminals of the first chip side attached so that the terminals (103) of the opposite second chip side are co-planar with the device terminals on the slab ridge.

In some examples, a device comprises at least two semiconductor die, wherein each respective semiconductor die of the at least two semiconductor die comprises at least two power transistors, an input node on a first side of the respective semiconductor die, a reference node on the first side of the respective semiconductor die, and a switch node on a second side of the respective semiconductor die. The device further comprises a first conductive element electrically connected to the respective input nodes of the at least two semiconductor die. The device further comprises a second conductive element electrically connected to the respective reference nodes of the at least two semiconductor die.