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 first multi-gate field effect transistor (FET) disposed over a substrate, the first multi-gate FET including a first active region; and a second multi-gate FET disposed over the first multi-gate FET, the second multi-gate FET including a second active region. The first active region and the second active region are not fully projected in a vertical direction perpendicular to the substrate.

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 keep out area between the interconnect and a pin from an adjacent standard cell. The method further includes verifying that the keep out area separates the interconnect from the pin from the adjacent standard cell by at least a predetermined distance.

Abstract: A method for designing an integrated circuit includes steps of selecting a power rail of a cell, determining that a clearance distance for an electrical connection to or around the power rail is not sufficient to fit the electrical connection, selecting a power rail portion of the power rail for modification, and modifying a shape of the power rail portion to provide a clearance distance sufficient to fit the electrical connection. As clearance distances between features in an interconnection structure of an integrated circuit become smaller, manufacturing becomes more difficult and error-prone. Increasing clearance distances improves manufacturability of an integrated circuit. Modifying the shape of an integrated circuit power rail increases clearance distance to and/or around a power rail.

Abstract: An integrated circuit is disclosed, including a first conductive pattern and a second conductive pattern that are disposed in a first layer and extend in a first direction, at least one first conductive segment disposed in a second layer different from the first layer, and at least one via disposed between the first layer and the second layer. The at least one via is coupled between the at least one first conductive segment and one or both of the first conductive pattern and the second conductive pattern, at an output node of the integrated circuit. The at least one via comprises a tapered shape with a width that decreases from a first width to a second width narrower than the first width. The first width of the at least one via is greater than widths of the first conductive pattern and the second conductive pattern.

Abstract: A device includes gates and a first conductive segment. A first distance is present between a first gate of the gates and the first conductive segment. A second distance is present between a second gate of the gates and the first conductive segment. The first distance is greater than the second distance.

Abstract: An integrated circuit includes a semiconductor substrate, an isolation region extending into, and overlying a bulk portion of, the semiconductor substrate, a buried conductive track comprising a portion in the isolation region, and a transistor having a source/drain region and a gate electrode. The source/drain region or the gate electrode is connected to the buried conductive track.

Abstract: A system for preparing an integrated circuit device design includes a memory for storing a plurality of preliminary integrated circuit design files; a processor for retrieving a preliminary integrated circuit design file from the memory; locating vertical abutments between adjacent device cell designs, identifying internal metal cuts on the adjacent device cell designs; determining and evaluating a horizontal spacing between the internal metal cuts a spacing threshold; and if the threshold is note met, shifting one cell horizontally relative to the other cell design by a predetermined distance to define a modified device layout, repeating the determining, evaluating, and shifting operations until the spacing threshold is satisfied; and identifying a next vertical abutment between and repeating the identifying, determining, shifting operations until the spacing threshold has been satisfied for all vertical abutments.

Abstract: A semiconductor device includes a substrate having an active region, a first gate structure over a top surface of the substrate, a second gate structure over the top surface of the substrate, a pair of first spacers on each sidewall of the first gate structure, a pair of second spacers on each sidewall of the second gate structure, an insulating layer over at least the first gate structure, a first conductive feature over the active region and a second conductive feature over the substrate. Further, the second gate structure is adjacent to the first gate structure and a top surface of the first conductive feature is coplanar with a top surface of the second conductive feature.

Abstract: A method includes reserving a routing track within a cell, the cell includes signal lines for connection to elements within the cell, the cell further includes a plurality of routing tracks, the reserved routing track is one of the plurality of routing tracks, and the reserved routing track is free of the signal lines. The method includes placing the cell in a chip-level layout, wherein the chip-level layout includes a plurality of power rails. The method includes determining whether any of the plurality of power rails overlaps with any of the plurality of routing tracks other than the reserved routing track. The method includes adjusting a position of the cell in the chip-level layout in response to a determination that at least one power rail of the plurality of power rails overlaps with at least one routing track of the plurality of routing tracks other than the reserved routing track.

Abstract: A method for manufacturing a semiconductor device to which corresponds a layout diagram stored on a non-transitory computer-readable medium. The method includes generating the layout diagram using an electronic design system (EDS), the EDS including at least one processor and at least one memory including computer program code for one or more programs are configured to cause the EDS to execute the generating. Testing the semiconductor device. Revising, the layout diagram, based on testing results indicative of selected standard functional cells in the layout diagram which merit modification or replacement. Programming one or more of the ECO cells which correspond to the one or more selected standard functional cells resulting in one or more programmed ECO cells. Routing the one or more programmed ECO cells correspondingly to at least one of the selected standard functional cells or to one or more other ones of the standard functional cells.

Abstract: An integrated circuit device includes: an integrated circuit module; a first field-effect transistor coupled between the integrated circuit module and a first reference voltage, and controlled by a first controlled signal; and a second field-effect transistor coupled between the integrated circuit module and the first reference voltage; wherein the second field-effect transistor is a complementary field-effect transistor of the first field-effect transistor, and the first field-effect transistor and the second field-effect transistor are configured to generate a second reference voltage for the integrated circuit module according to the first control signal.

Abstract: A method includes positioning a first active region adjacent to a pair of second active regions in an initial integrated circuit (IC) layout diagram of an initial cell, to align side edges of the first active region and corresponding side edges of each second active region of the pair of second active regions along a cell height direction. The first active region forms, together with the initial cell, a modified cell having a modified IC layout diagram. The side edges of the first active region and the corresponding side edges of each second active region extend along the cell height direction. A height dimension of the first active region in the cell height direction is less than half of a height dimension of each second active region of the pair of second active regions in the cell height direction. The positioning the first active region is executed by a processor.

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: An integrated circuit includes a first active region, a second active region, a third active region, a first contact and a second contact. The first active region and the second active region are separated from each other in a first direction, and are located on a first level. The third active region is located on the first level and is separated from the second active region in a second direction different from the first direction. The first contact extends in the second direction, overlaps the first active region, and is located on a second level different from the first level. The second contact extends in the first direction and the second direction, overlaps the first contact and the third active region, is electrically coupled to the first contact, and is located on a third level different from the first level and the second level.

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 keep out area between the interconnect and a pin from an adjacent standard cell. The method further includes verifying that the keep out area separates the interconnect from the pin from the adjacent standard cell by at least a predetermined distance.

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 substrate having an active region, a first gate structure over a top surface of the substrate, a second gate structure over the top surface of the substrate, a pair of first spacers on each sidewall of the first gate structure, a pair of second spacers on each sidewall of the second gate structure, an insulating layer over at least the first gate structure, a first conductive feature over the active region and a second conductive feature over the substrate. Further, the second gate structure is adjacent to the first gate structure and a top surface of the first conductive feature is coplanar with a top surface of the second conductive feature.

Abstract: A system (including a processor and memory with computer program code) configured to execute a method which includes generating a layout diagram including: generating first and second active area patterns on opposite sides of (and having long axes parallel to) a first symmetry axis; generating non-overlapping first, second and third conductive patterns (having long axes perpendicular to the first symmetry axis) which overlap the first and second active area patterns; centering the first conductive pattern between the second and third conductive patterns; generating a first cut-pattern for, and which overlaps, central regions of the second and third conductive patterns; centering the first cut-pattern relative to the first symmetry axis; generating a fourth conductive pattern over an area bounded by the first cut-pattern; and expanding the fourth conductive pattern to substantially overlap a portion of the first conductive pattern and a portion of the second or third conductive patterns.

Abstract: An integrated circuit includes a plurality of gate electrode structures extending along a first direction and having a predetermined spatial resolution measurable along a second direction orthogonal to the first direction. The plurality of gate electrode structures includes a first gate electrode structure having a first portion and a second portion separated in the first direction, and a second gate electrode structure having a third portion and a fourth portion separated in the first direction. The integrated circuit further includes a conductive feature including a first section electrically connected to the second portion, wherein the first section extends in the second direction, a second section electrically connected to the third portion, wherein the second section extends in the second direction, and a third section electrically connecting the first section and the second section, the third section extends in a third direction angled with respect to the first and second directions.