The present invention is directed to a semiconductor chip comprising a high voltage device and a low voltage device disposed thereon. The chip may be formed in several different configurations. For example, the semiconductor chip may include a NPN bipolar transistor, PNP bipolar transistor, a diode, an N channel DMOS transistor and the like. the first doped well being configured as a base of the DMOS transistor, a P channel DMOS transistor and the like. These and other embodiments are described in further detail below.

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 collector layer, a base layer, an emitter layer, and an emitter mesa layer are placed above a substrate in this order. A base electrode and an emitter electrode are further placed above the substrate. The emitter mesa layer has a long shape in a first direction in plan view. The base electrode includes a base electrode pad portion spaced from the emitter mesa layer in the first direction. An emitter wiring line and a base wiring line are placed on the emitter electrode and the base electrode, respectively. The emitter wiring line is connected to the emitter electrode via an emitter contact hole. In the first direction, the spacing between the edges of the emitter mesa layer and the emitter contact hole on the side of the base wiring line is smaller than that between the emitter mesa layer and the base wiring line.

Structures for a heterojunction bipolar transistor and methods of fabricating such structures. A hardmask is formed that includes an opening over a first portion of a substrate in a first device region and a shape over a second portion of the substrate in a second device region. An oxidized region in the first portion of the substrate while the shape blocks oxidation of the second portion of the substrate. The oxidized region is subsequently removed from the first portion of the substrate to define a recess. A first base and a first emitter of a first heterojunction bipolar transistor are formed over the first portion of the substrate in the first device region, and a second base and a second emitter of a second heterojunction bipolar transistor are formed in the recess over the second portion of the substrate in the second device region.

Structures for a heterojunction bipolar transistor and methods of fabricating such structures. A hardmask is formed that includes an opening over a first portion of a substrate in a first device region and a shape over a second portion of the substrate in a second device region. An oxidized region in the first portion of the substrate while the shape blocks oxidation of the second portion of the substrate. The oxidized region is subsequently removed from the first portion of the substrate to define a recess. A first base and a first emitter of a first heterojunction bipolar transistor are formed over the first portion of the substrate in the first device region, and a second base and a second emitter of a second heterojunction bipolar transistor are formed in the recess over the second portion of the substrate in the second device region.

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.

A microfluidic device can include a base an outer surface of which forms one or more enclosures for containing a fluidic medium. The base can include an array of individually controllable transistor structures each of which can comprise both a lateral transistor and a vertical transistor. The transistor structures can be light activated, and the lateral and vertical transistors can thus be photo transistors. Each transistor structure can be activated to create a temporary electrical connection from a region of the outer surface of the base (and thus fluidic medium in the enclosure) to a common electrical conductor. The temporary electrical connection can induce a localized electrokinetic force generally at the region, which can be sufficiently strong to move a nearby micro-object in the enclosure.

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.

The present invention is directed to a semiconductor chip comprising a high voltage device and a low voltage device disposed thereon. The chip may be formed in several different configurations. For example, the semiconductor chip may include a NPN bipolar transistor, PNP bipolar transistor, a diode, an N channel DMOS transistor and the like. the first doped well being configured as a base of the DMOS transistor, a P channel DMOS transistor and the like. These and other embodiments are described in further detail below.

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.