Abstract: A linear-shaped core structure of a first material is formed on an underlying material. A layer of a second material is conformally deposited over the linear-shaped core structure and exposed portions of the underlying material. The layer of the second material is etched so as to leave a filament of the second material on each sidewall of the linear-shaped core structure, and so as to remove the second material from the underlying material. The linear-shaped core structure of the first material is removed so as to leave each filament of the second material on the underlying material. Each filament of the second material provides a mask for etching the underlying material. Each filament of the second material can be selectively etched further to adjust its size, and to correspondingly adjust a size of a feature to be formed in the underlying material.

Abstract: At least nine linear-shaped conductive structures (LCS's) are positioned in accordance with a first pitch. Five of the at least nine LCS's collectively form three transistors of a first transistor type and three transistors of a second transistor type. Transistors of the first transistor type are collectively separated from transistors of the second transistor type by an inner region. Two transistors of the first transistor type and two transistors of the second transistor type are cross-coupled transistors. Each of four LCS's corresponding to the cross-coupled transistors has a respective electrical connection area located within the inner region. The two LCS's corresponding to the two transistors of the first transistor type of the cross-coupled transistors have electrical connections areas that are not aligned with each other. The four LCS's corresponding to the cross-coupled transistors include at least two different inner extension distances beyond their respective electrical connection areas.

Abstract: An integrated circuit includes a gate electrode level region that includes a plurality of linear-shaped conductive structures. Each of the plurality of linear-shaped conductive structures is defined to extend lengthwise in a first direction. Some of the plurality of linear-shaped conductive structures form one or more gate electrodes of corresponding transistor devices. A local interconnect conductive structure is formed between two of the plurality of linear-shaped conductive structures so as to extend in the first direction along the two of the plurality of linear-shaped conductive structures.

Abstract: A rectangular-shaped interlevel connection layout structure is defined to electrically connect a first layout structure in a first chip level with a second layout structure in a second chip level. The rectangular-shaped interlevel connection layout structure is defined by an as-drawn cross-section having at least one dimension larger than a corresponding dimension of either the first layout structure, the second layout structure, or both the first and second layout structures. A dimension of the rectangular-shaped interlevel connection layout structure can exceed a normal maximum size in one direction in exchange for a reduced size in another direction. The rectangular-shaped interlevel connection layout structure can be placed in accordance with a gridpoint of a virtual grid defined by two perpendicular sets of virtual lines. Also, the first and/or second layout structures can be spatially oriented and/or placed in accordance with one or both of the two perpendicular sets of virtual lines.

Abstract: Problematic open areas are identified in a semiconductor wafer layout. The problematic open areas have a size variation relative to one or more neighboring open areas of the layout sufficient to cause adverse microloading variation. In one embodiment, the adverse microloading variation is controlled by shifting a number of layout features to interdict the problematic open areas. In another embodiment, the adverse microloading variation is controlled by defining and placing a number of dummy layout features to shield actual layout features that neighbor the problematic open areas. In another embodiment, the adverse microloading variation is controlled by utilizing sacrificial layout features which are actually fabricated on the wafer temporarily to eliminate microloading variation, and which are subsequently removed from the wafer to leave behind the desired permanent structures.

Abstract: A first gate level feature forms gate electrodes of a first transistor of a first transistor type and a first transistor of a second transistor type. A second gate level feature forms a gate electrode of a second transistor of the first transistor type. A third gate level feature forms a gate electrode of a second transistor of the second transistor type. The gate electrodes of the second transistors of the first and second transistor types are positioned on opposite sides of a gate electrode track along which the gate electrodes of the first transistors of the first and second transistor types are positioned. The gate electrodes of the second transistors of the first and second transistor types are electrically connected to each other through an electrical connection that includes respective gate contacts and one or more conductive interconnect structures.

Abstract: A first linear-shaped conductive structure (LCS) forms a gate electrode (GE) of a first transistor of a first transistor type. A second LCS forms a GE of a first transistor of a second transistor type. A third LCS forms a GE of a fourth transistor of the first transistor type. A fourth LCS forms a GE of a fourth transistor of the second transistor type. Transistors of the first transistor type are collectively separated from transistors of the second transistor type by an inner region. Each of the first, second, third, and fourth LCS's has a respective electrical connection area. At least two of the electrical connection areas of the first, second, third, and fourth LCS's are located within the inner region. The first and fourth transistors of the first transistor type and the first and fourth transistors of the second transistor type form part of a cross-coupled transistor configuration.

Abstract: A global placement grating (GPG) is defined for a chip level to include a set of parallel and evenly spaced virtual lines. At least one virtual line of the GPG is positioned to intersect each contact that interfaces with the chip level. A number of subgratings are defined. Each subgrating is a set of equally spaced virtual lines of the GPG that supports a common layout shape run length thereon. The layout for the chip level is partitioned into subgrating regions. Each subgrating region has any one of the defined subgratings allocated thereto. Layout shapes placed within a given subgrating region in the chip level are placed in accordance with the subgrating allocated to the given subgrating region. Non-standard layout shape spacings at subgrating region boundaries can be mitigated by layout shape stretching, layout shape insertion, and/or subresolution shape insertion, or can be allowed to exist in the final layout.

Abstract: A linear-shaped core structure of a first material is formed on an underlying material. A layer of a second material is conformally deposited over the linear-shaped core structure and exposed portions of the underlying material. The layer of the second material is etched so as to leave a filament of the second material on each sidewall of the linear-shaped core structure, and so as to remove the second material from the underlying material. The linear-shaped core structure of the first material is removed so as to leave each filament of the second material on the underlying material. Each filament of the second material provides a mask for etching the underlying material. Each filament of the second material can be selectively etched further to adjust its size, and to correspondingly adjust a size of a feature to be formed in the underlying material.

Abstract: A semiconductor chip region includes a first conductive structure (CS) that forms a gate electrode (GE) of a first transistor of a first transistor type (TT) and a GE of a first transistor of a second TT, a second CS that forms a GE of a second transistor of the first TT, a third CS that forms a GE of a second transistor of the second TT, a fourth CS that forms a GE of a third transistor of the first TT, a fifth CS that forms a GE of a third transistor of the second TT, another CS that forms a GE of a fourth transistor of the first TT, and another CS that forms a GE of a fourth transistor of the second TT. The second and third transistors of the first and second TT's have a common diffusion terminal electrical connection and specified gate electrode electrical connections.

Abstract: A semiconductor chip includes a region that includes a first conductive structure (CS) that forms a gate electrode (GE) of a first transistor of a first transistor type. The region includes a second CS that forms a GE of a second transistor of the first transistor type and a GE of a first transistor of a second transistor type. The region includes another CS that forms a GE of a second transistor of the second transistor type. The GE's of the first and second transistors of the first transistor type are separated by a gate pitch. The GE's of the first and second transistors of the second transistor type are separated by the gate pitch. The first CS has a total length that is greater than one-half of the total length of the second CS. The second and third CS's have at least one respective end aligned with each other.

Abstract: Problematic open areas are identified in a semiconductor wafer layout. The problematic open areas have a size variation relative to one or more neighboring open areas of the layout sufficient to cause adverse microloading variation. In one embodiment, the adverse microloading variation is controlled by shifting a number of layout features to interdict the problematic open areas. In another embodiment, the adverse microloading variation is controlled by defining and placing a number of dummy layout features to shield actual layout features that neighbor the problematic open areas. In another embodiment, the adverse microloading variation is controlled by utilizing sacrificial layout features which are actually fabricated on the wafer temporarily to eliminate microloading variation, and which are subsequently removed from the wafer to leave behind the desired permanent structures.

Abstract: A semiconductor device includes conductive features that are each defined within any one gate level channel that is uniquely associated with and defined along one of a number of parallel gate electrode tracks. The conductive features form gate electrodes of first and second PMOS transistor devices, and first and second NMOS transistor devices. The gate electrodes of the first PMOS and first NMOS transistor devices extend along a first gate electrode track. The gate electrodes of the second PMOS and second NMOS transistor devices extend along a second gate electrode track. A first set of interconnected conductors electrically connect the gate electrodes of the first PMOS and second NMOS transistor devices. A second set of interconnected conductors electrically connect the gate electrodes of the second PMOS and first NMOS transistor devices. The first and second sets of interconnected conductors traverse across each other within different levels of the semiconductor device.

Abstract: A first gate level feature forms gate electrodes of a first transistor of a first transistor type and a first transistor of a second transistor type. A second gate level feature forms a gate electrode of a second transistor of the first transistor type. A third gate level feature forms a gate electrode of a second transistor of the second transistor type. The gate electrodes of the second transistors of the first and second transistor types are electrically connected to each other through an electrical connection formed by linear-shaped conductive structures. The gate electrodes of the second transistors of the first and second transistor types are positioned on opposite sides of a gate electrode track along which the gate electrodes of the first transistors of the first and second transistor types are positioned.

Abstract: A first gate level feature forms gate electrodes of a first transistor of a first transistor type and a first transistor of a second transistor type. A second gate level feature forms a gate electrode of a second transistor of the first transistor type. A third gate level feature forms a gate electrode of a second transistor of the second transistor type. The gate electrodes of the second transistors of the first and second transistor types are positioned on opposite sides of a gate electrode track along which the gate electrodes of the first transistors of the first and second transistor types are positioned. The gate electrodes of the second transistors of the first and second transistor types are electrically connected to each other through an electrical connection that includes respective gate contacts and one or more conductive interconnect structures.

Abstract: A semiconductor chip is defined to include a logic block area having a first chip level in which layout features are placed according to a first virtual grate, and a second chip level in which layout features are placed according to a second virtual grate. A rational spatial relationship exists between the first and second virtual grates. A number of cells are placed within the logic block area. Each of the number of cells is defined according to an appropriate one of a number of cell phases. The appropriate one of the number of cell phases causes layout features in the first and second chip levels of a given placed cell to be aligned with the first and second virtual grates as positioned within the given placed cell.

Abstract: A first linear-shaped conductive structure (LCS) forms gate electrodes (GE's) of a first transistor of a first transistor type and a first transistor of a second transistor type. A second LCS forms a GE of a second transistor of the first transistor type. A third LCS forms a GE of a second transistor of the second transistor type. A fourth LCS forms a GE of a third transistor of the first transistor type. A fifth LCS forms a GE of a third transistor of the second transistor type. A sixth LCS forms a GE of a fourth transistor of the first transistor type and a fourth transistor of the second transistor type. Transistors of the first transistor type are collectively separated from transistors of the second transistor type by an inner region. The second, third, fourth, and fifth LCS's have respective electrical connection areas arranged relative to the inner region.

Abstract: A first transistor has source and drain regions within a first diffusion fin. The first diffusion fin projects from a surface of a substrate. The first diffusion fin extends lengthwise in a first direction from a first end to a second end of the first diffusion fin. A second transistor has source and drain regions within a second diffusion fin. The second diffusion fin projects from the surface of the substrate. The second diffusion fin extends lengthwise in the first direction from a first end to a second end of the second diffusion fin. The second diffusion fin is positioned next to and spaced apart from the first diffusion fin. Either the first end or the second end of the second diffusion fin is positioned in the first direction between the first end and the second end of the first diffusion fin.

Abstract: A semiconductor chip is defined to include a logic block area having a first chip level in which layout features are placed according to a first virtual grate, and a second chip level in which layout features are placed according to a second virtual grate. A rational spatial relationship exists between the first and second virtual grates. A number of cells are placed within the logic block area. Each of the number of cells is defined according to an appropriate one of a number of cell phases. The appropriate one of the number of cell phases causes layout features in the first and second chip levels of a given placed cell to be aligned with the first and second virtual grates as positioned within the given placed cell.

Abstract: An integrated circuit includes at least four linear-shaped conductive structures formed to extend lengthwise in a parallel direction to each other and each respectively including a gate electrode portion and an extending portion that extends away from the gate electrode portion. The gate electrode portions of the linear-shaped conductive structures respectively form gate electrodes of different transistors, such that at least one of the linear-shaped conductive structures forms a gate electrode of a transistor of a first transistor type and does not form a gate electrode of any transistor of a second transistor type, and such that at least one of the linear-shaped conductive structures forms a gate electrode of a transistor of the second transistor type and does not form a gate electrode of any transistor of the first transistor type. Extending portions of the at least four linear-shaped conductive structures include at least two different extending portion lengths.