A semiconductor device has an element part and an outer peripheral part, and a deep layer is formed in the outer peripheral part more deeply than a base layer. When a position of the deep layer closest to the element part is defined as a boundary position, a distance between the boundary position and a position closest to the outer peripheral part in an emitter region is defined as a first distance, and a distance between the boundary position and a position of an end of a collector layer is defined as a second distance, the first distance and the second distance are adjusted such that a carrier density in the outer peripheral part is lowered based on breakdown voltage in the outer peripheral part lowered by the deep layer.

A compound semiconductor device includes a heterojunction bipolar transistor and a bump. The heterojunction bipolar transistor includes a plurality of unit transistors. The bump is electrically connected to emitters of the plurality of unit transistors. The plurality of unit transistors are arranged in a first direction. The bump is disposed above the emitters of the plurality of unit transistors while extending in the first direction. The emitter of at least one of the plurality of unit transistors is displaced from a center line of the bump in the first direction toward a first side of a second direction which is perpendicular to the first direction. The emitter of at least another one of the plurality of unit transistors is displaced from the center line of the bump in the first direction toward a second side of the second direction.

In order to reduce electric field concentration in a semiconductor device including a main transistor section and a sense transistor section, the semiconductor device is provided, the semiconductor device including a semiconductor substrate of a first conductivity type, a main transistor section in an active region on the semiconductor substrate, and a sense transistor section outside the active region on the semiconductor substrate, wherein the active region is provided with a main well region of a second conductivity type, and wherein the sense transistor section has a sense gate trench section formed extending from the outside of the active region to the main well region on the front surface of the semiconductor substrate.

Transistors including semiconductor regions where operating current flows are provided above a substrate. Operating electrodes of conductive material having thermal conductivity higher than the semiconductor regions and contacting the semiconductor regions to conduct operating current to the semiconductor regions are disposed. A conductor pillar for external connection contains contact regions where the semiconductor regions and the operating electrodes contact, and is electrically connected to the operating electrodes. The contact regions are disposed in a first direction. Each contact region has a planar shape long in a second direction orthogonal to the first direction. A first average distance, obtained by averaging distances in the second direction from each end portion of the contact region in the second direction to an edge of the conductor pillar across the contact regions, exceeds an average distance value in a height direction from the contact region to a top surface of the conductor pillar.

A microelectronic device has a common terminal transistor with two or more channels, and sense transistors in corresponding areas of the channels. The channels and the sense transistors share a common node in a semiconductor substrate. The sense transistors are configured to provide sense currents that are representative of currents through the corresponding channels. The sense transistors are located so that a ratio of the channel currents to the corresponding sense currents have less than a target value of cross-talk. The microelectronic device may be implemented without a compensation circuit which provides a compensation signal used to adjust one or more of the sense currents to reduce cross-talk. A method of forming the microelectronic device, including estimating a potential distribution in the semiconductor substrate containing the common node of the common terminal transistor, and selecting locations for the sense transistors based on the estimated potential distribution, is disclosed.

A microelectronic device has a common terminal transistor with two or more channels, and sense transistors in corresponding areas of the channels. The channels and the sense transistors share a common node in a semiconductor substrate. The sense transistors are configured to provide sense currents that are representative of currents through the corresponding channels. The sense transistors are located so that a ratio of the channel currents to the corresponding sense currents have less than a target value of cross-talk. The microelectronic device may be implemented without a compensation circuit which provides a compensation signal used to adjust one or more of the sense currents to reduce cross-talk. A method of forming the microelectronic device, including estimating a potential distribution in the semiconductor substrate containing the common node of the common terminal transistor, and selecting locations for the sense transistors based on the estimated potential distribution, is disclosed.

A power semiconductor switch includes a cross-trench structure associated with at least one IGBT cell. The cross-trench structure merge at least one control trench, at least one dummy trench and at least one further trench of at least one IGBT cell to each other. The cross-trench structure overlaps at least partially along a vertical direction with trenches of the at least one IGBT-cell.

A first wiring is disposed above operating regions of plural unit transistors formed on a substrate. A second wiring is disposed above the substrate. An insulating film is disposed on the first and second wirings. First and second cavities are formed in the insulating film. As viewed from above, the first and second cavities entirely overlap with the first and second wirings, respectively. A first bump is disposed on the insulating film and is electrically connected to the first wiring via the first cavity. A second bump is disposed on the insulating film and is electrically connected to the second wiring via the second cavity. As viewed from above, at least one of the plural operating regions is disposed within the first bump and is at least partially disposed outside the first cavity. The planar configuration of the first cavity and that of the second cavity are substantially identical.

The disclosure provides a high ruggedness HBT structure, including: a sub-collector layer on a substrate and formed of an N-type III-V semiconductor material; a collector layer on the sub-collector layer and formed of a III-V semiconductor material; a base layer on the collector layer and formed of a P-type III-V semiconductor material; an emitter layer on the base layer and formed of one of N-type semiconductor materials of InGaP, InGaAsP and InAlGaP; a first emitter cap layer on the emitter layer and formed of one of undoped or N-type semiconductor materials of Al.sub.xGa.sub.1-xAs, Al.sub.xGa.sub.1-xAs.sub.1-yN.sub.y, Al.sub.xGa.sub.1-xAs.sub.1-zP.sub.z, Al.sub.xGa.sub.1-xAs.sub.1-wSb.sub.w, and In.sub.rAl.sub.xGa.sub.1-x-rAs, x having a highest value between 0.05x0.4, and y, z, r, w0.1; a second emitter cap layer on the first emitter cap layer and formed of an N-type III-V semiconductor material; and an ohmic contact layer on the second emitter cap layer and formed of an N-type III-V semiconductor material.

A cascode transistor device includes a semiconductor substrate, and a first and a second compound semiconductor transistors. The first compound semiconductor transistor includes a first n-type doping layer, a first p-type doping layer and a second n-type doping layer sequentially disposed on the semiconductor substrate. The second compound semiconductor transistor includes a third n-type doping layer, a second p-type doping layer and a fourth n-type doping layer sequentially disposed on the second n-type doping layer. Each of these doping layers is formed with an exposed metal contact. The exposed metal contact on the second n-type doping layer is electrically connected to the exposed metal contact on the third n-type doping layer.