A first conductive structure forms gate electrodes of a first transistor of a first transistor type and a first transistor of a second transistor type. A second conductive structure forms a gate electrode of a second transistor of the first transistor type. A third conductive structure forms a gate electrode of a second transistor of the second transistor type. A fourth conductive structure forms a gate electrode of a third transistor of the first transistor type. A fifth conductive structure forms a gate electrode of a third transistor of the second transistor type. A sixth conductive structure forms gate electrodes of a fourth transistor of the first transistor type and a fourth transistor of the second transistor type. The second and third transistors of the first transistor type and the second and third transistors of the second transistor type are electrically connected to form a cross-coupled transistor configuration.

A method is provided, and including operations as below: forming multiple active areas extending in a first direction; forming multiple conductive patterns extending in a second direction different from the first direction and arranged in a first layer above the active areas; forming multiple gates extending parallel to the conductive patterns; and forming a first set of conductive lines extending in the first direction and arranged in three first metal tracks that are in a second layer above the first layer, wherein one of the first set of conductive lines is arranged in a middle track of the three first metal tracks, coupled to one of the gates and overlap a first shallow trench region between two of the active areas.

A method includes fabricating a first-voltage underlayer power rail conductively connecting to the source region of a first-type transistor and fabricating a second-voltage underlayer power rail conductively connecting to the source region of a second-type transistor. Each of the first-voltage and second-voltage underlayer power rails extends in a first direction. The method also includes patterning a first connection layer to form a first-voltage power rail and a second-voltage power rail extending in the second direction which is perpendicular to the first direction. The first-voltage power rail is directly connected with the first-voltage underlayer power rail through a first via-connector and the second-voltage power rail is directly connected with the second-voltage underlayer power rail through a second via-connector.

A method is provided, and including operations as below: forming multiple active areas extending in a first direction; forming multiple conductive patterns extending in a second direction different from the first direction and arranged in a first layer above the active areas; forming multiple gates extending parallel to the conductive patterns; and forming a first set of conductive lines extending in the first direction and arranged in three first metal tracks that are in a second layer above the first layer, wherein one of the first set of conductive lines is arranged in a middle track of the three first metal tracks, coupled to one of the gates and overlap a first shallow trench region between two of the active areas.

An integrated circuit includes a first-voltage underlayer power rail and a second-voltage underlayer power rail extending in a first direction below a first connection layer. A first-type transistor and a second-type transistor are underneath the first connection layer. The source region of the first-type transistor is connected to the first-voltage underlayer power rail, and the source region of the second-type transistor is connected to the second-voltage underlayer power rail. The integrated circuit also includes a first-voltage power rail, a second-voltage power rail, and a signal conducting line, each of which extends in a second direction in the first connection layer. The first-voltage power rail is connected to the first-voltage underlayer power rail, and the second-voltage power rail is connected to the second-voltage underlayer power rail. The signal conducting line is conductively connected to either a terminal-conductor or a gate-conductor.

An integrated circuit includes a first standard cell including a first first-type transistor, a first second-type transistor, a third second-type transistor, and a third first-type transistor, a second standard cell including a second first-type transistor, a second second-type transistor, a fourth second-type transistor and a fourth first-type transistor, a plurality of wiring layers which are disposed on the first and second standard cells and includes a first wiring layer, a second wiring layer, and a third wiring layer sequentially stacked. A source contact of the first first-type transistor and a source contact of the second first-type transistor are electrically connected through a first power rail of the plurality of wiring layers, and a source contact of the third first-type transistor and a source contact of the fourth first-type transistor are electrically connected through a second power rail of the plurality of wiring layers.

A semiconductor device includes a substrate having a first active region disposed in a first region of a substrate and a second active region disposed in a second region of the substrate. A first gate stack is disposed over the first active region and a second gate stack is disposed over the second active region, the first and second gate stacks having elongated shapes oriented in a first direction. A first metal layer is disposed over the first gate stack and the second gate stack. The first metal layer includes first metal layer structures oriented in a second direction orthogonal to the first direction. A second metal layer disposed over the first metal layer. The second metal layer includes second metal layer structures oriented in the first direction. A third metal layer is disposed over the second metal layer. The third metal layer includes a third metal layer structures oriented in the second direction.

An integrated circuit includes a first power rail on a back-side of a substrate, and extending in a first direction, a first and second flip-flop, and a first conductor on a first metal layer and extending in a second direction. The first flip-flop includes a first region that includes a first inverter, a second inverter having a first output pin, and a first input pin. The second flip-flop includes a second region that abuts the first region at a first boundary, and includes a third inverter, a fourth inverter having a second output pin, and a second input pin. The first conductor overlaps the first boundary, and electrically couples the first output pin and the second output pin together. The first and second flip-flop are on a front-side of the substrate. The first input pin is offset from the first boundary in the second direction.

An apparatus and method for efficiently routing power signals across a semiconductor die. In various implementations, an integrated circuit includes, at a first node that receives a power supply reference, a first micro through silicon via (TSV) that traverses through a silicon substrate layer to a backside metal layer. The integrated circuit includes, at a second node that receives the power supply reference, a second micro TSV that physically contacts at least one source region. The integrated circuit includes a first power rail that connects the first micro TSV to the second micro TSV. This power rail replaces contacts between the micro TSVs and a second power rail such as the frontside metal zero (M0) layer. Each of the first power rail, the second power rail, and the backside metal layer provides power connection redundancy that increases charge sharing, improves wafer yield, and reduces voltage droop.

A method includes a first set of active areas extending in a first direction and separated from each other along a second direction in a cell; first and second gate s that cross the first set of active areas along the second direction, the first gate being shared by a first transistor of a first type and a second transistor of a second type and the second gate being shared by a third transistor of the first type and a fourth transistor of the second type; and a set of conductive lines arranged in three metal tracks in the cell and coupling at least one of terminals of the first to fourth transistors to another one of the terminals of the first to fourth transistor. The first transistor is turned off to electrically disconnect a source/drain terminal of the first transistor from a source/drain terminal of the fourth transistor.