A transistor device includes a substrate, a source region provided on the substrate, a drain region spaced apart from the source region in a direction parallel to a top surface of the substrate, a pair of constant current generating patterns provided in the substrate to be adjacent to the source region and the drain region, respectively, a gate electrode provided on the substrate and between the source region and the drain region, and a gate insulating film interposed between the gate electrode and the substrate, wherein, the pair of constant current generating patterns generate a constant current between the drain region and the substrate, and the constant current is independent from a gate voltage applied to the gate electrode.

Resistor structures of stacked devices and methods of forming the same are provided. The, resistor structures may include a substrate, an upper semiconductor layer that may be spaced apart from the substrate in a vertical direction, a lower semiconductor layer that may be between the substrate and the upper semiconductor layer, and first and second resistor contacts that may be spaced apart from each other in a horizontal direction. At least one of the upper semiconductor layer, the lower semiconductor layer, and a portion of the substrate may contact the first and second resistor contacts.

Improve the reliability of a semiconductor device. A resistive element Rg is filled in a trench TR formed in a well region PW of a semiconductor substrate. The resistive element Rg and the trench TR have an endless shape in plan view. The resistive element Rg is connected to a first contact member PG that is electrically connected to a gate pad GP, and a second contact member PG that is electrically connected to a gate wiring GW. Furthermore, a third contact member PG, which electrically connects an emitter electrode EE to the well region PW, is positioned in an area surrounded by an endless shape of the resistive element Rg, between the first and second contact members PG in a Y direction.

Described herein are semiconductor devices and methods of forming the same. In some aspects, methods of forming a semiconductor device includes forming a gate stack having a self-aligning cap and a gate metal on a substrate, depositing a resist mask onto the semiconductor device, and patterning the resist mask such that the gate stack is exposed. Additionally, methods include removing the self-aligning cap and the gate metal from the exposed gate stack, depositing a resistor metal on the semiconductor device such that a metal resistor is formed within the exposed gate stack, and forming a bar contact and contact via above the metal resistor.

A transistor includes: a semiconductor substrate; a plurality of gate electrodes, a plurality of source electrodes, and a plurality of drain electrodes on the semiconductor substrate; a drain pad on the semiconductor substrate and connected to the plurality of drain electrodes; a metal wiring on the semiconductor substrate and arranged spaced apart from, adjacent to and parallel to the drain pad; and a ground pad on the semiconductor substrate and connected to both ends of the metal wiring.

An integrated circuit structure includes: a semiconductor substrate; a shallow trench isolation (STI) region in the semiconductor substrate; one or more active devices formed on the semiconductor substrate; and a resistor array having a plurality of resistors disposed above the STI region; wherein the resistor array comprises a portion of one or more interconnect contact layers that are for interconnection to the one or more active devices.

A high-frequency integrated circuit (1) of an embodiment of the present disclosure includes: a high-frequency circuit (10); a terminal (20) electrically coupled to the high-frequency circuit; a first transistor (M1) provided between the terminal and a reference potential line; and a second transistor (M2) provided between the terminal and the reference potential line. The first transistor includes a gate (G) and a drain (D) that are electrically coupled to the terminal, and a source (S) electrically coupled to the reference potential line. The second transistor includes a source (S) electrically coupled to the terminal, and a gate (G) and a drain (D) that are electrically coupled to the reference potential line.

A semiconductor device for high-frequency amplification includes a substrate; a first nitride semiconductor layer above the substrate; a two-dimensional electron gas layer; a second nitride semiconductor layer; and a source electrode, a drain electrode, and a gate electrode spaced apart from each other above the first nitride semiconductor layer. In a plan view, an active region with a two-dimensional electron gas layer includes a high-electron-mobility transistor and the resistor provided above the second nitride semiconductor layer. In the plan view, a non-active region includes a drain terminal and a gate terminal connected to the drain electrode or the gate electrode; and a first resistor terminal and a second resistor terminal connected to the resistor.

A material stack comprising a plurality of bi-layers, each bi-layer comprising two semiconductor material layers, is fabricated into both a low voltage transistor structure and a high voltage transistor structure. Within the low voltage transistor structure, a first of two semiconductor material layers may be replaced with a gate stack while the high voltage transistor structure may retain both of two semiconductor material layers. The material stack may also be fabricated into both a transistor structure and a resistor structure. Within the transistor structure, a first of two semiconductor material layers may be replaced with a gate stack while the resistor structure may retain both of two semiconductor material layers.

A heterojunction device having at least three terminals, the at least three terminals comprising a high voltage terminal, a low voltage terminal and a control terminal. The heterojunction device further comprises at least one main power heterojunction transistor, an auxiliary gate circuit comprising at least one first low-voltage heterojunction transistor, a pull-down circuit comprising a capacitor and a charging path for the capacitor. The heterojunction device further comprises at least one monolithically integrated component, wherein the capacitor is configured to provide an internal rail voltage for the at least one monolithically integrated component.