A semiconductor device that includes a first wiring, a second wiring, and a first number of first resistance elements that are connected in parallel between the first wiring and the second wiring, and each of which has a negative first temperature coefficient. The semiconductor device further includes a second number of second resistance elements that are connected in parallel to the first resistance elements, each of which has a positive second temperature coefficient, the second temperature coefficient having an absolute value larger than an absolute value of the first temperature coefficient. The second number is smaller than the first number.

A system and method for forming a resistor system is provided. An embodiment comprises a resistor formed in a U-shape. The resistor may comprise multiple layers of conductive materials, with a dielectric layer filling the remainder of the U-shape. The resistor may be integrated with a dual metal gate manufacturing process or may be integrated with multiple types of resistors.

An integrated circuit that can include a driver having a first driver output, and a first resistance coupled between a first node coupled to the first driver output and a second node. The first resistance can include a process resistor including a first material having a first temperature coefficient, and an interconnect resistor configured to provide at least 20% of the first resistance and including a second material having a second temperature coefficient which changes resistance in an opposite direction with temperature as compared to the first temperature coefficient. A first terminal of the interconnect resistor is directly connected to a first terminal of the process resistor.

A semiconductor structure containing at least two metal resistor structures having different resistivities is provided and includes a first metal resistor structure located on a portion of a dielectric-containing substrate. The first metal resistor structure includes, from bottom to top, a first nitridized dielectric surface layer portion having a first nitrogen content, a first metal layer portion and a first nitridized metal surface layer. A second metal resistor structure is located on a second portion of the dielectric-containing substrate and spaced apart from the first metal resistor structure. The second metal resistor structure includes, from bottom to top, a second nitridized dielectric surface layer portion having a second nitrogen content, a second metal layer portion and a second nitridized metal surface layer. The second nitrogen content of the second nitridized dielectric surface layer portion differs from the first nitrogen content of the first nitridized dielectric surface layer portion.

A semiconductor device comprising a semiconductor substrate and a composite capacitor structure on the semiconductor substrate, wherein the composite capacitor structure comprises a capacitor stack comprising a lower and an upper capacitor, respectively comprising first and second dielectric materials, wherein the first and second dielectric materials are different materials and/or have different thicknesses from each other. This can minimize the voltage dependence of the capacitance of the composite capacitor structure. It is also possible to provide a composite capacitor structure on the semiconductor substrate, wherein the composite capacitor structure comprises at least a first and a second capacitor stack, each comprising a lower and an upper capacitor. The capacitors can be MIM capacitors.

An integrated circuit comprises a semiconductor substrate having a surface. A lateral resistor is arranged in a first plane parallel to the surface of the substrate. A vertical reference resistor comprises a layer arranged in a second plane parallel to the surface of the substrate and deeper than the first plane. This layer is doped to promote current flow in the second plane. The vertical reference resistor further comprises a first trench and a second trench coupled between the layer and the surface of the substrate. The first and second trenches are arranged in a vertical direction orthogonal to the first and the second planes and are doped to impede current flow in the vertical direction. A cross-section of the first and second trenches is two-fold rotationally symmetric around the vertical direction, and the lateral resistor and the first and second trenches have the same temperature coefficient.

Some embodiments include a resistor that may be used in audio conversion for an ADC. The resistor may be made up of an n-well as well as a p-well polysilicons. The n-well and p-well polysilicons may include a shallow trench isolator. The n-well and p-well components may be in series with other n-well or p-well components respectively. Similarly, multiple n-well components which are in series, may be in parallel with multiple p-well components.

A passive element package includes a first substrate, first passive elements disposed on the first substrate, a second substrate disposed on the first passive elements, second passive elements disposed on the second substrate, and a sealant that seals the first passive elements and the second passive elements. The passive element package can reduce the size of a semiconductor module that includes the passive element package.

A semiconductor component has a semiconductor body zone, a first electrically conductive layer adjacent to the semiconductor body zone, a first dielectric layer with first dielectric properties and a second dielectric layer with second dielectric properties. The first dielectric properties differ from the second dielectric properties. The first dielectric layer and the second dielectric layer are arranged between the semiconductor body zone and the first electrically conductive layer. A second electrically conductive layer is applied between the first dielectric layer and the second dielectric layer. A first voltage divider is switched between the first electrically conductive layer and the semiconductor body zone. The second electrically conductive layer is electrically conductively connected only to the voltage divider.

The present disclosure relates to semiconductor structures and, more particularly, to interconnect reliability structures and methods of manufacture. The structure includes: a plurality of resistors; and a voltmeter configured to sense a relative difference in resistance of the plurality of resistors indicative of at least one of a via-depletion and line-depletion.