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.

Semiconductor structures and methods of forming the same are provided. A method according to an embodiment includes forming a conductive feature and a first conductive plate over a substrate, conformally depositing a dielectric layer over the conductive feature and the first conductive plate, conformally depositing a conductive layer over the conductive feature and the first conductive plate, and patterning the conductive layer to form a second conductive plate over the first conductive plate and a resistor, the resistor includes a conductive line extending along a sidewall of the conductive feature. By employing the method, a high-resistance resistor may be formed along with a capacitor regardless of the resolution limit of, for example, lithography.

The present invention suppresses an increase in manufacturing cost and reduces switching noise. A field-effect transistor having a gate electrode embedded in a trench in an upper surface of a semiconductor substrate, a source region formed in the semiconductor substrate, and a drain region formed on a lower surface of the semiconductor substrate is provided with a gate wiring formed on the semiconductor substrate and being electrically connected to the gate electrode, a gate pad formed on the semiconductor substrate, a first resistor connected between the gate pad and the gate wiring and being configured to function when the field-effect transistor is turned ON, a second resistor connected between the gate pad and the gate wiring and being configured to function when the field-effect transistor is turned OFF, and a rectifier diode included in the first resistor or the second resistor between the gate pad and the gate wiring.

An electric fuse element has a first portion, a second portion arranged on one end of the first portion, and a third portion arranged on the other end of the first portion. A resistor element is arranged separately from the electric fuse element. A material of each of the electric fuse element and the resistor element has silicon metal or nickel chromium. The electric fuse element and the resistor element are arranged in an upper layer of the first wiring and in lower layer of the second wiring. A wiring width of the second portion and a wiring width of the third portion are larger than a wiring width of the first portion.

In some embodiments, a low-resistance path between an active cell and a power supply layer in an integrated circuit device includes at least one layer of a plurality of conductive lines commonly connected to at least one conductive line through a plurality of respective conductive pillars, the at least one conductive line being in the power supply layer or intervening the active cell and the power supply layer. In some embodiments, the integrated circuit device includes a conductive layer that includes the plurality of conductive lines and additional conductive portions, where the plurality of conductive lines are isolated from the additional conductive portions.

The present invention provides a thermal sensor integrated IC having a resistor and a converting circuit. The resistor is implemented by at least one metal line, wherein a resistance of the resistor is varied with a temperature of the resistor, the resistor has a first terminal and a second terminal, and one of the first terminal and the second terminal is arranged to provide a voltage signal corresponding to the resistance. The converting circuit is coupled to the resistor, and is configured to convert the voltage signal to an output signal for determining the temperature. In one embodiment, the at least one metal line is made by copper.

A semiconductor device includes resistor layers, and a wiring layer which is disposed at least either above or below the resistor layers. The resistor layers include first resistor layers and second resistor layers each having a width in a first direction smaller than a width of the first resistor layer in a first direction. The wiring layer includes first overlapping regions in which the wiring layer overlaps with the first resistor layers in plan view and second overlapping regions in which the wiring layer overlaps with the second resistor layers in plan view. A value obtained by dividing a total value of areas of the second overlapping regions by a width of the second resistor layer is smaller than a value obtained by dividing a total value of areas of the first overlapping regions by a width of the first resistor layer.

A semiconductor device includes a target layer disposed on a substrate, and a crack sensor for detecting a crack generated in the target layer. The crack sensor includes a first conductive pattern positioned at a bottom surface of the target layer, a second conductive pattern positioned on a top surface of the target layer, the top surface being opposite to the bottom surface of the target layer, a plurality of resistors, and nodes. The plurality of resistors are connected in parallel to each other through the first conductive pattern and the second conductive pattern. Each of the plurality of resistors is disposed to substantially penetrate the target layer.

A metal oxide metal (MOM) capacitor and methods for fabricating the same are disclosed. The MOM capacitor includes a first metal layer having a first plurality of fingers, each of the first plurality of fingers configured to have alternating polarities. A high resistance (Hi-R) conductor layer is disposed adjacent the first metal layer in a plane parallel to the first metal layer.

A cost effective process flow for manufacturing semiconductor on insulator structures is parallel is provided. Each of the multiple semiconductor-on-insulator composite structures prepared in parallel comprises a charge trapping layer (CTL).