A semiconductor device has a semiconductor substrate, and multiple first bipolar transistors on the first primary surface side of the semiconductor substrate. The first bipolar transistors have a first height between an emitter layer and an emitter electrode in the direction perpendicular to the first primary surface. The semiconductor device further has at least one second bipolar transistor on the first primary surface side of the semiconductor substrate. The second bipolar transistor have a second height, greater than the first height, between an emitter layer and an emitter electrode in the direction perpendicular to the first primary surface. Also, the semiconductor has a first bump stretching over the multiple first bipolar transistors and the at least one second bipolar transistor.

A current source includes a substrate, a base region of a first doping type formed in the substrate, an emitter region of a second doping type formed in the substrate and surrounding the base region, a first collector region of the second doping type formed in the base region, and at least one second collector region of the second doping type formed in the base region, wherein the emitter region includes a deep-well portion and an extending portion, the deep-well portion situated beneath the base region, the extending portion laterally surrounding the base region, the extending portion joined at its bottom to the deep-well portion, the extending portion being flush at its top with a top surface of the substrate. A method of forming the current source is also disclosed.

A compound semiconductor device comprises a heterojunction bipolar transistor including a plurality of unit transistors, a capacitor electrically connected between a RF input wire and a base wire for each unit transistor of the unit transistors, and a bump electrically connected to emitters of the unit transistors. The unit transistors are arranged in a first direction. The bump is disposed above the emitters of the unit transistors while extending in the first direction. The transistors include first and second unit transistors, the respective emitters of the first and second unit transistors being disposed on first and second sides, respectively, of a second direction, perpendicular to the first direction, with respect to a center line of the bump extending in the first direction. The capacitor is not covered by the bump, and respective lengths of the respective base wires connected respectively to the first and second unit transistors are different.

At least one unit transistor is arranged over a substrate. A first wiring as a path of current that flows to each unit transistor is arranged over the at least one unit transistor. An inorganic insulation film is arranged over the first wiring. At least one first opening overlapping a partial region of the first wiring in a plan view is provided in the inorganic insulation film. An organic insulation film is arranged over the inorganic insulation film. A second wiring coupled to the first wiring through the first opening is arranged over the organic insulation film and the inorganic insulation film. In a plan view, a region in which the organic insulation film is not arranged is provided outside a region in which the first wiring is arranged. The second wiring is in contact with the inorganic insulation film outside the region in which the first wiring is arranged.

On a single-crystal semiconductor substrate with an upper surface including a first direction in which an inverted mesa step extends and a second direction in which a forward mesa step extends in response to anisotropic etching in which an etching rate depends on crystal plane orientation, a bipolar transistor including a collector layer, a base layer, and an emitter layer that are epitaxially grown, and a base wire connected to the base layer are arranged. A step is provided at an edge of the base layer, and the base wire is extended from inside to outside of the base layer in a direction intersecting the first direction in a plan view. An intersection of the edge of the base layer and the base wire has a disconnection prevention structure that makes it difficult for step-caused disconnection of the base wire to occur.

One illustrative device disclosed herein includes a semiconductor substrate, a bipolar junction transistor (BJT) device that comprises a collector, a base and an emitter, at least one piezoelectric structure comprising a piezoelectric material positioned adjacent the BJT device, and at least first and second conductive contact structures that are conductively coupled to the piezoelectric structure.

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 is 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 semiconductor device includes a semiconductor element including a bipolar transistor disposed on a compound semiconductor substrate, a collector electrode, a base electrode, and an emitter electrode, the bipolar transistor including a collector layer, a base layer, and an emitter layer, the collector electrode being in contact with the collector layer, the base electrode being in contact with the base layer, the emitter electrode being in contact with the emitter layer; a protective layer disposed on one surface of the semiconductor element; an emitter redistribution layer electrically connected to the emitter electrode via a contact hole in the protective layer; and a stress-relieving layer disposed between the emitter redistribution layer and the emitter layer in a direction perpendicular to a surface of the compound semiconductor substrate.

An integrated circuit includes a plurality of first n-type regions and a plurality of second n-type regions that each intersect a surface of a substrate. The first n-type regions are arranged in a first linear array within a first n-well and a second linear array within a second n-well. The first and second n-wells are each located within and separated by a first p-type region. The second n-type regions are located within and separated by a second p-type region. An n-type trench region is located between the first and second p-type regions. The n-type trench region extends into the substrate toward an n-type buried layer that extends under the first p-type region and the second p-type region.

A semiconductor device includes a heterojunction bipolar transistor and a bump. The heterojunction bipolar transistor (HBT) includes a plurality of unit transistors. The bump is electrically connected to emitters of the plurality of unit transistors through respective overlying conductor filled via openings that overlap in a plan view with a width portion of the bump. The semiconductor device reduces heat resistance in an HBT cell by satisfying two conditions, the first of which is related to specific sizing and positioning of a width portion of the overlying via opening relative to the width portion of the bump, and the second of which is related to positioning the base electrode entirely within a specific region of the width portion of the overlapping overlying via opening.