An integrated circuit includes a first conductive pattern in a first conductive layer, a second conductive pattern in a second conductive layer over the first conductive layer, and a via electrically connected with the first conductive pattern and the second conductive pattern to allow a first current flowing from the first conductive pattern to the second conductive pattern and a second current flowing from the second conductive pattern to the first conductive pattern to pass through at different times. The via is placed on the first conductive pattern so that a path of the first current does not overlap with a path of the second current in the first conductive pattern.

An integrated circuit includes a first standard cell including a first p-type transistor, a first n-type transistor, a first gate stack intersecting first and second active regions, first extended source/drain contacts on a first side of the first gate stack, a first normal source/drain contact on a second side of the first gate stack, a first gate via connected to the first gate stack, and a first source/drain via connected to the first normal source/drain contact, a second standard cell adjacent the first standard cell and including a second p-type transistor, a second n-type transistor, a second gate stack intersecting the first and second active regions, and a second gate via connected to the second gate stack, an input wiring connected to the first gate via, and an output wiring at a same level as the input wiring to connect the first source/drain via and the second gate via.

A semiconductor device includes first and second active patterns respectively on the first and second active regions of a substrate, a gate electrode on the first and second channel patterns, active contacts electrically connected to at least one of the first and second source/drain patterns, a gate contact electrically connected to the gate electrode, a first metal layer on the active and gate contacts and including a first and second power line, and first and second gate cutting patterns below the first and second power lines. The first active pattern may include first channel pattern between a pair of first source/drain patterns. The second active pattern may include a second channel pattern between a pair of second source/drain patterns. The first and second gate cutting patterns may cover the outermost side surfaces of the first and second channel patterns, respectively.

A method of forming an integrated circuit (IC) includes generating a netlist of a first circuit, generating a first cell layout of the first circuit, placing the first cell layout, by an automatic placement and routing (APR) tool, in a first region of a layout design. The first circuit is configured as a non-functional circuit. The first circuit includes a first pin and a second pin that are electrically disconnected from each other. Generating the netlist of the first circuit includes designating the first pin and the second pin as a first group of pins that are to be connected together. Placing the first cell layout by the APR tool includes connecting the first pin and the second pin in the first group of pins together thereby changing the first circuit to a second circuit. The second circuit is configured as a functional version of the first circuit.

An integrated circuit including a first standard cell placed continuously on a row having a first height and a row having a second height different from the first height. The integrated circuit also includes a second standard cell continuously placed on a row having the first height and a row having the second height, a plurality of first power lines formed on boundaries of the plurality of rows and configured to supply a first supply voltage to the standard cells, and a plurality of second power lines formed on boundaries of the plurality of rows and configured to supply a second supply voltage to the standard cells. A placement sequence of the power lines supplying a voltage to the first standard cell being different from a placement sequence of the power lines supplying a voltage to the second standard cell.

A layout structure of a standard cell using a complementary FET (CFET) is provided. First and second transistors that are three-dimensional transistors lie between first and second power supply lines as viewed in plan, the second transistor being formed above the first transistor in the depth direction. A first local interconnect is connected with the source or drain of the first transistor, and a second local interconnect is connected with the source or drain of the second transistor. The first and second local interconnects extend in the Y direction, overlap each other as viewed in plan, and both overlap the first and second power supply lines as viewed in plan.

An integrated circuit includes a first standard cell including a first p-type transistor, a first n-type transistor, a first gate stack intersecting first and second active regions, first extended source/drain contacts on a first side of the first gate stack, a first normal source/drain contact on a second side of the first gate stack, a first gate via connected to the first gate stack, and a first source/drain via connected to the first normal source/drain contact, a second standard cell adjacent the first standard cell and including a second p-type transistor, a second n-type transistor, a second gate stack intersecting the first and second active regions, and a second gate via connected to the second gate stack, an input wiring connected to the first gate via, and an output wiring at a same level as the input wiring to connect the first source/drain via and the second gate via.

An integrated circuit device includes a device layer having devices spaced in accordance with a predetermined device pitch, a first metal interconnection layer disposed above the device layer and coupled to the device layer, and a second metal interconnection layer disposed above the first metal interconnection layer and coupled to the first metal interconnection layer through a first via layer. The second metal interconnection layer has metal lines spaced in accordance with a predetermined metal line pitch, and a ratio of the predetermined metal line pitch to predetermined device pitch is less than 1.

A semiconductor device including first and second active regions extending in a first direction; a field region between the first and second active regions; a gate structure including an upper gate electrode overlapping the first active region and extending in a second direction crossing the first direction, and a lower gate electrode overlapping the second active region, extending in the second direction, and on a same line as the upper gate electrode; a gate isolation layer between the upper and lower gate electrodes; source/drain regions on respective sides of the upper gate electrode; a contact jumper crossing the upper gate electrode in the first active region and electrically connecting the source/drain regions; and a first upper contact extending in the second direction in the field region and overlapping the lower gate electrode and the gate isolation layer, wherein the upper gate electrode is a dummy gate electrode.

An integrated circuit device includes a device layer having devices spaced in accordance with a predetermined device pitch, a first metal interconnection layer disposed above the device layer and coupled to the device layer, and a second metal interconnection layer disposed above the first metal interconnection layer and coupled to the first metal interconnection layer through a first via layer. The second metal interconnection layer has metal lines spaced in accordance with a predetermined metal line pitch, and a ratio of the predetermined metal line pitch to predetermined device pitch is less than 1.