Abstract: The present disclosure describes an example method for routing a standard cell with multiple pins. The method can include modifying a dimension of a pin of the standard cell, where the pin is spaced at an increased distance from a boundary of the standard cell than an original position of the pin. The method also includes routing an interconnect from the pin to a via placed on a pin track located between the pin and the boundary and inserting a wire cut between the interconnect and a pin from an adjacent standard cell. The method further includes verifying that the wire cut separates the interconnect from the pin from the adjacent standard cell by at least a predetermined distance.

Abstract: An IC structure includes a first and a second active region, a first multi-gate structure, a first and a second rail. The first and second active region extend in a first direction and are located at a first level. The second active region is separated from the first active region in a second direction. The first multi-gate structure extends in the second direction, overlaps the first active region and the second active region, and is located at a second level different from the first level. The first rail extends in the first direction, overlaps a portion of the first active region, is configured to supply a first supply voltage, and is located at a third level. The second rail extends in the first direction, is located at the third level, is separated from the first rail in the second direction, and is configured to supply a second supply voltage.

Abstract: An integrated circuit includes a first diffusion area for a first type transistor. The first type transistor includes a first drain region and a first source region. A second diffusion area for a second type transistor is separated from the first diffusion area. The second type transistor includes a second drain region and a second source region. A gate electrode continuously extends across the first diffusion area and the second diffusion area in a routing direction. A first metallic structure is electrically coupled with the first source region. A second metallic structure is electrically coupled with the second drain region. A third metallic structure is disposed over and electrically coupled with the first and second metallic structures. A width of the first metallic structure is substantially equal to or larger than a width of the third metallic structure.

Abstract: In some embodiments, a flip-flop is disposed as an integrated circuit layout on a flip-flop region of a semiconductor substrate. The flip-flop includes a first clock inverter circuit that resides within the flip-flop region, and a second clock inverter circuit residing within the flip-flop region. The first clock inverter circuit and the second clock inverter circuit are disposed on a first line. Master switch circuitry is made up of a first plurality of devices which are circumscribed by a master switch perimeter that resides within the flip-flop region of the integrated circuit layout. The master switch circuitry and the first clock inverter circuit are disposed on a second line perpendicular to the first line. Slave switch circuitry is operably coupled to an output of the master switch circuitry. The slave switch circuitry is made up of a third plurality of devices that are circumscribed by a slave switch perimeter.

Abstract: A semiconductor device includes fins extending substantially parallel to a first direction, at least one of the fins being a dummy fin; and at least one of the fins being an active fin; and at least one gate structure formed over corresponding ones of the fins and extending substantially parallel to a second direction, the second direction being substantially perpendicular to the first direction; wherein the fins and the at least one gate structure are located in a cell region which includes an odd number of fins. In an embodiment, the cell region is substantially rectangular and has first and second edges which are substantially parallel to the first direction; and neither of the first and second edges overlaps any of the fins.

Abstract: A method of generating a layout diagram of an IC cell includes defining a boundary recess in a boundary of the cell by extending a first portion of the boundary along a first direction, extending a second portion of the boundary away from the first portion in a second direction perpendicular to the first direction, the second portion being contiguous with the first portion, and extending a third portion of the boundary away from the first portion in the second direction, the third portion being contiguous with the first portion. An active region is positioned in the cell by extending the active region away from the first portion in a third direction opposite to the second direction. The layout diagram is stored on a non-transitory computer-readable medium.

Abstract: In at least one cell region, a semiconductor device includes fins and at least one overlying gate structure. The fins (dummy and active) are substantially parallel to a first direction. Each gate structure is substantially parallel to a second direction (which is substantially perpendicular to the first direction). First and second active fins have corresponding first and second conductivity types. Each cell region, relative to the second direction, includes: a first active region which includes a sequence of three or more consecutive first active fins located in a central portion of the cell region; a second active region which includes one or more second active fins located between the first active region and a first edge of the cell region; and a third active region which includes one or more second active fins located between the first active region and a second edge of the cell region.

Abstract: An integrated circuit includes a cell layer, a first metal layer, and a first conductive via. The cell layer includes first and second cells, each of which is configured to perform a circuit function. The first metal layer is above the cell layer and includes a first conductive feature that extends from the first cell into the second cell and that is configured to receive a supply voltage. A first conductive via interconnects the cell layer and the metal layer.

Abstract: A flip-flop circuit includes a first latch, a second latch and a trigger circuit. The first latch is configured to set a first output signal based on at least a first input signal and a clock signal. The second latch is configured to set a second output signal based on a second input signal and the clock signal. The trigger circuit is coupled with the first latch and the second latch. The trigger circuit is configured to generate the second input signal based on at least the second output signal. The trigger circuit is configured to cause the second input signal to have a first voltage swing or a second voltage swing based on the first output signal and the second output signal. The first voltage swing is different from the second voltage swing.

Abstract: A method is applied to reconfigure a set of uncrowned standard cells in a layout of a semiconductor apparatus. Each uncrowned standard cell includes a standard first array. Each standard first array includes a first stacked arrangement of vias interspersed with first segments of corresponding M(i)˜M(N) metallization layers. The M(N) metallization layer includes second segments which connect corresponding first segments of the M(N) metallization layer in the first standard arrays. The method includes crowning each first standard array in the set with a corresponding second standard array, the latter including a second stacked arrangement of vias interspersed with corresponding first segments of corresponding M(N+1)˜M(N+Q) metallization layers. The crowning includes disposing vias in a VIA(N+1) layer so as to be substantially collinear (relative to a first direction), and not substantially collinear (relative to a substantially perpendicular second direction), with corresponding vias in the VIA(N) layer.

Abstract: A circuit includes an input circuit, a level shifter circuit, an output circuit and a feedback circuit. The input circuit is coupled to a first voltage supply, and configured to receive a first input signal, and to generate a second input signal. The level shifter circuit is coupled to the input circuit, and configured to receive an enable signal, the first input signal or the second input signal, and to generate a first signal responsive to the enable signal or the first input signal. The output circuit is coupled to the level shifter circuit, and is configured to receive the first signal, and to generate an output signal or a set of feedback signals responsive to the first signal. The feedback circuit is coupled to the level shifter circuit and output circuit, and is configured to receive the enable signal or the set of feedback signals.

Abstract: A circuit includes a slave latch including a first input and an output, the first input being coupled to a master latch, and a retention latch including a second input coupled to the output. The master latch and the slave latch are configured to operate in a first power domain having a first power supply voltage level, the retention latch is configured to operate in a second power domain having a second power supply voltage level different from the first power supply voltage level, and the circuit further includes a level shifter configured to shift a signal level from one of the first power supply voltage level or the second power supply voltage level to the other of the first power supply voltage level or the second power supply voltage level.

Abstract: In some embodiments, a first cell layout and a second cell layout are provided and combined into a third cell layout. Each of the first cell layout and the second cell layout includes a higher power line, a lower power line, an output pin, at least one up transistor and at least one down transistor formed to electrically couple the output pin to the higher power line and the output pin to the lower power line, respectively. The at least one up transistor and the at least one down transistor of the second cell layout include a gate line. For the combining, the gate line is non-selectively electrically coupled to the output pin of the first cell layout to form a first node. A design layout in which the third cell layout is used at different locations is generated.

Abstract: An IC structure includes a cell, a first rail and a second rail. The cell includes a first and a second active region and a first gate structure. The first and second active region extend in a first direction and is located at a first level. The second active region is separated from the first active region in a second direction. The first gate structure extends in the second direction, overlaps the first and second active region, and is located at a second level. The first rail extends in the first direction, overlaps the first active region, is configured to supply a first supply voltage, and is located at a third level. The second rail extends in the first direction, overlaps the second active region, is located at the third level, separated from the first rail in the second direction, and is configured to supply a second supply voltage.

Abstract: A flip-flop circuit includes a first latch, a second latch and a trigger circuit. The first latch is configured to set a first output signal based on a first input signal and a clock signal. The second latch is configured to set a second output signal based on a second input signal and the clock signal. The trigger circuit is coupled with the first latch and the second latch. The trigger circuit is configured to generate the second input signal based on at least the second output signal. The trigger circuit is configured to cause the second input signal to have different voltage swings based on the first output signal and the second output signal. The trigger circuit includes a logic circuit coupled to at least the first latch or the second latch. The logic circuit is configured to output the second output signal.

Abstract: In some embodiments, a flip-flop is disposed as an integrated circuit layout on a flip-flop region of a semiconductor substrate. The flip-flop includes a first clock inverter circuit that resides within the flip-flop region, and a second clock inverter circuit residing within the flip-flop region. The first clock inverter circuit and the second clock inverter circuit are disposed on a first line. Master switch circuitry is made up of a first plurality of devices which are circumscribed by a master switch perimeter that resides within the flip-flop region of the integrated circuit layout. The master switch circuitry and the first clock inverter circuit are disposed on a second line perpendicular to the first line. Slave switch circuitry is operably coupled to an output of the master switch circuitry. The slave switch circuitry is made up of a third plurality of devices that are circumscribed by a slave switch perimeter.

Abstract: A semiconductor standard cell of a flip-flop circuit includes semiconductor fins extending substantially parallel to each other along a first direction, electrically conductive wirings disposed on a first level and extending substantially parallel to each other along the first direction, and gate electrode layers extending substantially parallel to a second direction substantially perpendicular to the first direction and formed on a second level different from the first level. The flip-flop circuit includes transistors made of the semiconductor fins and the gate electrode layers, receives a data input signal, stores the data input signal, and outputs a data output signal indicative of the stored data in response to a clock signal, the clock signal is the only clock signal received by the semiconductor standard cell, and the data input signal, the clock signal, and the data output signal are transmitted among the transistors through at least the electrically conductive wirings.

Abstract: A semiconductor structure is disclosed. The semiconductor structure includes: a first standard cell; and a second standard cell; wherein a cell width of the first standard cell along a first direction is substantially the same as a cell width of the second standard cell along the first direction, and a cell height of the first standard cell along a second direction perpendicular to the first direction is substantially greater than a cell height of the second standard cell along the second direction.

Abstract: A semiconductor device includes a plurality of standard cells. The plurality of standard cells include a first group of standard cells arranged in a first row extending in a row direction and a second group of standard cells arranged in a second row extending in the row direction. The first group of standard cells and the second group of standard cells are arranged in a column direction. A cell height of the first group of standard cells in the column direction is different from a cell height of the second group of standard cells in the column direction.

Abstract: An integrated circuit includes a cell layer, a first metal layer, and a first conductive via. The cell layer includes first and second cells, each of which is configured to perform a circuit function. The first metal layer is above the cell layer and includes a first conductive feature that extends from the first cell into the second cell and that is configured to receive a supply voltage. A first conductive via interconnects the cell layer and the metal layer.