Integrated circuits including an integrated standard cell structure are provided. In an embodiment, an integrated circuit includes a first transistor gated by a first input and connected to a first power supply rail and an output, a second transistor gated by a second input and connected to the first power supply rail and the output, a floating third transistor and a fourth transistor that are connected to the first power supply rail and a third power supply rail, a fifth transistor gated by the first input and connected to a second power supply rail, a sixth transistor gated by the second input and connected to the second power supply rail, a seventh transistor gated by the second input and connected to the fifth transistor and the output, and an eighth transistor gated by the first input and connected to the sixth transistor and the output.

Placement methods described in this disclosure provide placement and routing rules where a system implementing the automatic placement and routing (APR) method arranges standard cell structures in a vertical direction that is perpendicular to the fins but parallel to the cell height. Layout methods described in this disclosure also improve device density and further reduce cell height by incorporating vertical power supply lines into standard cell structures. Pin connections can be used to electrically connect the power supply lines to standard cell structures, thus improving device density and performance. The APR process is also configured to rotate standard cells to optimize device layout.

A semiconductor device includes a substrate having cell areas and power areas that are alternately arranged in a second direction. Gate structures extend in the second direction. The gate structures are spaced apart from each other in a first direction perpendicular to the second direction. Junction layers are arranged at both sides of each gate structure. The junction layers are arranged in the second direction such that each of the junction layer has a flat portion that is proximate to the power area. Cutting patterns are arranged in the power areas. The cutting patterns extend in the first direction such that each of the gate structures and each of the junction layers in neighboring cell areas are separated from each other by the cutting pattern.

A semiconductor device includes a substrate, a front side circuit disposed over a front surface of the substrate, and a backside power delivery circuit disposed over a back surface and including a back side power supply wiring coupled to a first potential. The front side circuit includes semiconductor fins and a first front side insulating layer covering bottom portions of the semiconductor fins, a plurality of buried power supply wirings embedded in the first front side insulating layer, the plurality of buried power supply wirings including a first buried power supply wiring and a second buried power supply wiring, and a power switch configured to electrically connect and disconnect the first buried power supply wiring and the second buried power supply wiring. The second buried power supply wiring is connected to the back side power supply wiring by a first through-silicon via passing through the substrate.

An integrated circuit includes a cell layer including a first cell and a second cell, a first metal layer over the cell layer and having a first conductive feature, a second metal layer over the first metal layer and having a second conductive feature, and a first via between the first metal layer and the second metal layer and connecting the first conductive feature to the second conductive feature. The first conductive feature spans over a boundary between the first and second cells, and has a lengthwise direction along a first direction. The second conductive feature spans over the boundary between the first and second cells, and has a lengthwise direction along a second direction that is perpendicular to the first direction.

A method includes: providing a cell of a first group that supplies a first potential from a backside of a substrate, multiple cells of a second group, and two cells of a third group that supply a second potential from the backside; determining a distance in a row direction between the cell of the first group and each of the two cells of the third group; determining a placement of the cell of the first group, the two cells of the third group, and each of the cells of the second group; and counting a number of pins of the cells of the second group. The cell of the first group is located between the two cells of the third group. Each of the cells of the second group is located between the two cells of the third group.

An integrated circuit includes a gated circuit configured to operate on a first or second voltage, a header circuit, a first power rail and a second power rail on a back-side of a wafer, a third power rail on the back-side of the wafer, and a fourth power rail on a front-side of the wafer. The first and second power rail extend in a first direction, and are separated from each other in a second direction. The third power rail is between the first and second power rail in the second direction. The third power rail is configured to supply the second voltage to the gated circuit. The fourth power rail includes a first set of conductors extending in the second direction. Each of the first set of conductors is configured to supply a third voltage to the header circuit, and is separated from each other in the first direction.

An IC device includes first and second cells adjacent each other and over a substrate. The first cell includes a first IO pattern along a first track among a plurality of tracks in a first metal layer, the plurality of tracks elongated along a first axis and spaced from each other along a second axis. The second cell includes a plurality of conductive patterns along corresponding different tracks among the plurality of tracks in the first metal layer, each of the plurality of conductive patterns being an IO pattern of the second cell or a floating conductive pattern. The first metal layer further includes a first connecting pattern along the first track and connects the first IO pattern and a second IO pattern of the second cell. The second IO pattern is one of the plurality of conductive patterns of the second cell and is along the first track.

A semiconductor device includes: a standard cell including a plurality of active patterns extending in a first direction, a gate structure intersecting the plurality of active patterns and extending in a second direction, and source/drain regions respectively provided on the plurality of active patterns positioned on both sides of the gate structure; a plurality of signal lines extending on the standard cell in the first direction, arranged in the second direction, and electrically connected to the standard cell; and first and second power straps extending on the standard cell in the first direction, electrically connected to some of the source/drain regions, and supplying power to the standard cell, wherein each of the first and second power straps is provided on the standard cell while provided on the same line as any one of the plurality of signal lines in the first direction.

An integrated circuit according to some example embodiments of inventive concepts includes a substrate including a well including dopants of a first conductivity type, a first device region on the well, the first device region extending in a first direction parallel to the substrate, and a first isolation element inside the well, the first isolation element extending in the first direction. The first isolation element includes a first power rail configured to receive a power source voltage, and a first doping region between the first power rail and the well, the first doping region configured to transfer the power source voltage from the first power rail to the well, and including dopants of the first conductivity type.