A transistor includes a plurality of gate fingers that extend in a first direction and are spaced apart from each other in a second direction, each of the gate fingers comprising at least spaced-apart and generally collinear first and second gate finger segments that are electrically connected to each other. The first gate finger segments are separated from the second gate finger segments in the first direction by a gap region that extends in the second direction. A resistor is disposed in the gap region.

A dual-sided MOS IC includes an isolation layer and a MOS transistor. The isolation layer separates the MOS IC into a MOS IC frontside and a MOS IC backside. The MOS transistor is on both the MOS IC frontside and the MOS IC backside. The MOS transistor includes MOS gates, a first source connection in a first subsection of the MOS IC frontside, and a second source connection in a second subsection of the MOS IC backside. The first and second source connections are electrically coupled together through a first front-to-backside connection extending through the isolation layer. The MOS transistor further includes a first drain connection in the first subsection of the MOS IC backside, and a second drain connection in the second subsection of the MOS IC frontside. The first and second drain connections are electrically coupled together through a second front-to-backside connection extending through the isolation layer.

A display device includes a signal line disposed on a substrate. A signal input line is disposed on the substrate and connected to a driver. A first insulating layer is disposed on the signal line. A second insulating layer is disposed on the signal input line and the first insulating layer. First contact holes penetrate the first insulating layer and the second insulating layer and expose a portion of the signal line. Second contact holes penetrate the second insulating layer and expose a portion of the signal input line. A connecting member connects the signal line and the signal input line through the first and the second contact holes and is disposed on the second insulating layer. The first and the second contact holes are alternately arranged in the second insulating layer.

A semiconductor device includes a device region including a compound semiconductor material and a non-device region at least partially surrounding the device region. The semiconductor device further includes a dielectric material in the non-device region and at least one electrode in the device region. The semiconductor device further includes at least one pad electrically coupled to the at least one electrode, wherein the at least one pad is arranged on the dielectric material in the non-device region.

An ESD protection device including a Si substrate with an ESD protection circuit formed at the surface of the substrate; pads formed on the Si substrate; a rewiring layer opposed to the surface of the Si substrate, which includes terminal electrodes electrically connected to the pads. The rewiring layer includes a SiN protection film formed on the surface of the Si substrate to cover parts of the pads except regions in contact with openings (contact holes) formed in a resin layer, and the resin layer that is lower in dielectric constant than the SiN protection film, and formed between the SiN protection film and the terminal electrodes. Thus, provided is a semiconductor device which can reduce the generation of parasitic capacitance, and eliminates variation in parasitic capacitance generated.

Embedded packaging for devices and systems comprising lateral GaN power transistors is disclosed. The packaging assembly is suitable for large area, high power GaN transistors and comprises an assembly of a GaN power transistor and package components comprising a three level interconnect structure. In preferred embodiments, the three level interconnect structure comprises an on-chip metal layer, a copper redistribution layer and package metal layers, in which there is a graduated or tapered contact area sizing through the three levels for dividing/applying current on-chip and combining/collecting current off-chip, with distributed contacts over the active area of the GaN power device. This embedded packaging assembly provides a low inductance, low resistance interconnect structure suitable for devices and systems comprising large area, high power GaN transistors for high voltage/high current applications.

There is provided a field-effect transistor including: a gate electrode; a semiconductor layer having a source region and a drain region with the gate electrode in between; contact plugs provided on the source region and the drain region; first metals stacked on the contact plugs; and a low-dielectric constant region provided in a region between the first metals along an in-plane direction of the semiconductor layer and provided at least in a first region below bottom surfaces of the first metals along a stacking direction.

A package substrate that includes a first portion and a redistribution portion. The first portion is configured to operate as a capacitor. The first portion includes a first dielectric layer, a first set of metal layers in the dielectric layer, a first via in the dielectric layer, a second set of metal layers in the dielectric layer, and a second via in the dielectric layer. The first via is coupled to the first set of metal layers. The first via and the first set of metal layers are configured to provide a first electrical path for a ground signal. The second via is coupled to the second set of metal layers. The second via and the second set of metal layers are configured to provide a second electrical path for a power signal. The redistribution portion includes a second dielectric layer, and a set of interconnects.

A semiconductor device of the present invention includes a semiconductor layer including a main IGBT cell and a sense IGBT cell connected in parallel to each other, a first resistance portion having a first resistance value formed using a gate wiring portion of the sense IGBT cell and a second resistance portion having a second resistance value higher than the first resistance value, a gate wiring electrically connected through mutually different channels to the first resistance portion and the second resistance portion, a first diode provided between the gate wiring and the first resistance portion, a second diode provided between the gate wiring and the second resistance portion in a manner oriented reversely to the first diode, an emitter electrode disposed on the semiconductor layer, electrically connected to an emitter of the main IGBT cell, and a sense emitter electrode disposed on the semiconductor layer, electrically connected to an emitter of the sense IGBT cell.

A semiconductor device includes a semiconductor layer laminate disposed on a semiconductor substrate, a first and a second low-side transistors, and a first and a second high-side transistors. Each of the transistors is disposed on the semiconductor layer laminate, and includes a gate electrode, a source electrode, and a drain electrode. The second low-side transistor is disposed between the first low-side transistor and the first high-side transistor, and the first high-side transistor is disposed between the second low-side transistor and the second high-side transistor. The source electrodes of the first and the second low-side transistors are combined into one source electrode, the drain electrodes of the first and the second high-side transistors are combined into one drain electrode, and the drain electrode of the second low-side transistor and the source electrode of the first high-side transistor are combined into one first electrode.