An integrated circuit includes a substrate layer and a resistor bank in a polysilicon layer disposed on the substrate layer. The resistor bank includes a plurality of resistor elements having a body portion extending in a longitudinal direction. A metal line is disposed in a metal layer above the polysilicon layer to extend transverse to the longitudinal direction and across the body portion of a group of the plurality of resistor elements, thereby forming a first region of the resistor bank and a second region of the resistor bank. The first region is separated from the second region by the metal line. A resistor device having a predetermined resistance includes a subset of the resistor elements in the group electrically coupled together in the second region. The resistor device also includes first and second terminals located in the same first or second region of the resistor bank.

A semiconductor device includes: a standard cell array including a plurality of standard cells, each of the plurality of standard cells; a plurality of power supply lines configured to provide a power supply voltage and extending in a first direction; a capacitor structure including electrode structures included in each of a plurality of dielectric layers formed on the standard cell array, the capacitor structure having vias connecting the electrode structures; and contacts electrically connecting the capacitor structure and the standard cell array to each other. Each of the plurality of standard cells provides a unit capacitor circuit having capacitance that is based on a connection structure of active regions and gates of first and second transistors thereof.

An integrated circuit including first and second macroblocks arranged in a first direction, and a plurality of cells between the first macroblock and the second macroblock, the plurality of cells including at least one first ending cell adjacent to the first macroblock and having a first width in the first direction, at least one second ending cell adjacent to the second macroblock and having a second width different from the first width in the first direction, and at least one standard cell between the at least one first ending cell and the at least one second ending cell may be provided.

A layout structure of a capacitance cell using vertical nanowire (VNW) FETs is provided. The capacitance cell includes a plurality of first-conductivity type VNW FETs lining up in the X direction, provided between a first power supply interconnect and a second power supply interconnect. The plurality of first-conductivity type VNW FETs include at least one first VNW FET having a top and a bottom connected with the first power supply interconnect and a gate connected with the second power supply interconnect.

Disclosed is a method for designing an integrated circuit, wherein the integrated circuit is to be structured in cells, wherein the cells are to comprise functional cells and spare cells. The method comprises: a) designing at least one functional cell; and b) placing a plurality of functional cells on associated pattern positions of an, in particular regular, pattern matrix designed for the functional cells. The method further comprises c) placing, on at least one of the remaining pattern positions of the pattern matrix and instead of at least one spare cell conceivable for the at least one of the remaining pattern positions of the pattern matrix, a gate-based decoupling cell, and alternatively or in addition, d) placing, in at least one gap between pattern positions of the matrix pattern and instead of at least one filler cell conceivable for the at least one gap between pattern positions of the pattern matrix, a gate-based decoupling cell.

An integrated circuit including first and second macroblocks arranged in a first direction, and a plurality of cells between the first macroblock and the second macroblock, the plurality of cells including at least one first ending cell adjacent to the first macroblock and having a first width in the first direction, at least one second ending cell adjacent to the second macroblock and having a second width different from the first width in the first direction, and at least one standard cell between the at least one first ending cell and the at least one second ending cell may be provided.

Disclosed is a method for designing an integrated circuit, wherein the integrated circuit is to be structured in cells, wherein the cells are to comprise functional cells and spare cells. The method comprises: a) designing at least one functional cell; and b) placing a plurality of functional cells on associated pattern positions of an, in particular regular, pattern matrix designed for the functional cells. The method further comprises c) placing, on at least one of the remaining pattern positions of the pattern matrix and instead of at least one spare cell conceivable for the at least one of the remaining pattern positions of the pattern matrix, a gate-based decoupling cell, and alternatively or in addition, d) placing, in at least one gap between pattern positions of the matrix pattern and instead of at least one filler cell conceivable for the at least one gap between pattern positions of the pattern matrix, a gate-based decoupling cell.

A layout structure of a capacitance cell using vertical nanowire (VNW) FETs is provided. The capacitance cell includes a plurality of first-conductivity type VNW FETs lining up in the X direction, provided between a first power supply interconnect and a second power supply interconnect. The plurality of first-conductivity type VNW FETs include at least one first VNW FET having a top and a bottom connected with the first power supply interconnect and a gate connected with the second power supply interconnect.

An integrated circuit including first and second macroblocks arranged in a first direction, and a plurality of cells between the first macroblock and the second macroblock, the plurality of cells including at least one first ending cell adjacent to the first macroblock and having a first width in the first direction, at least one second ending cell adjacent to the second macroblock and having a second width different from the first width in the first direction, and at least one standard cell between the at least one first ending cell and the at least one second ending cell may be provided.

An integrated circuit including first and second macroblocks arranged in a first direction, and a plurality of cells between the first macroblock and the second macroblock, the plurality of cells including at least one first ending cell adjacent to the first macroblock and having a first width in the first direction, at least one second ending cell adjacent to the second macroblock and having a second width different from the first width in the first direction, and at least one standard cell between the at least one first ending cell and the at least one second ending cell may be provided.