Tela Innovations, Inc. Patent applications |
Patent application number | Title | Published |
20140246733 | Semiconductor Chip Including Integrated Circuit Defined Within Dynamic Array Section - A semiconductor chip includes four linear-shaped conductive structures that each form a gate electrode of corresponding transistor of a first transistor type and a gate electrode of a corresponding transistor of a second transistor type. First and second ones of the four linear-shaped conductive structures are positioned to have their lengthwise-oriented centerlines separated by a gate electrode pitch. Third and fourth ones of the four linear-shaped conductive structures are also positioned to have their lengthwise-oriented centerlines separated by the gate electrode pitch. The first and third ones of the four linear-shaped conductive structures are positioned to have their lengthwise-oriented centerlines co-aligned and are separated by a first end-to-end spacing. The second and fourth ones of the four linear-shaped conductive structures are positioned to have their lengthwise-oriented centerlines co-aligned and are separated by a second end-to-end spacing substantially equal in size to the first end-to-end spacing. | 09-04-2014 |
20140245245 | STANDARD CELLS HAVING TRANSISTORS ANNOTATED FOR GATE-LENGTH BIASING - Methods, layouts and chip design layouts that use annotations for communicating gate-length biasing amounts to post-layout tools are disclosed. One method includes receiving a chip design layout designed to includes select ones of a plurality of nominal cell layouts and an annotated cell layout. The chip design layout is defined by a plurality of layers and the plurality of nominal cell layouts define transistors, wherein each of the plurality of nominal cell layouts define nominal length transistors, and the annotated cell layout also defines transistors. The annotated cell layout is associated with an annotation layer that identifies a gate-length biasing to be applied to at least one transistor of the annotated cell layout. The gate-length biasing identifies an amount of change for a gate length and not width-sizing of a gate width of the at least one transistor of the annotated cell layout. The annotation layer is used to communicate design-specific directives that require implementation. The method uses a processor to process the chip design layout, with reference to the annotation layer, to apply the gate-length biasing to the annotated cell of the chip design layout. | 08-28-2014 |
20140239408 | SEMICONDUCTOR CHIP INCLUDING REGION HAVING CROSS-COUPLED TRANSISTOR CONFIGURATION WITH OFFSET ELECTRICAL CONNECTION AREAS ON GATE ELECTRODE FORMING CONDUCTIVE STRUCTURES AND AT LEAST TWO DIFFERENT INNER EXTENSION DISTANCES OF GATE ELECTRODE FORMING CONDUCTIVE STRUC - 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 second transistor of the first transistor type. A fourth LCS forms a GE of a second transistor of the second transistor type. Each of the first, second, third, and fourth LCS's has a respective electrical connection area. The electrical connection areas of the first and third LCS's are offset from each other. The GE of the first transistor of the first transistor type is electrically connected to the GE of the second transistor of the second transistor type. The GE of the second transistor of the first transistor type is electrically connected to the GE of the first transistor of the second transistor type. | 08-28-2014 |
20140223404 | Gate-Length Biasing for Digital Circuit Optimization - Methods and apparatus for a gate-length biasing methodology for optimizing integrated digital circuits are described. The gate-length biasing methodology that changes a nominal gate-length of a transistor to a biased gate-length, where the biased gate-length includes a bias length that is small compared to the nominal gate-length. | 08-07-2014 |
20140210015 | Integrated Circuit Within Semiconductor Chip Including Cross-Coupled Transistor Configuration - 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 a conductive interconnect structure. | 07-31-2014 |
20140197543 | Enforcement of Semiconductor Structure Regularity for Localized Transistors and Interconnect - 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. | 07-17-2014 |
20140175565 | Integrated Circuit Cell Library for Multiple Patterning - A method is disclosed for defining a multiple patterned cell layout for use in an integrated circuit design. A layout is defined for a level of a cell in accordance with a dynamic array architecture so as to include a number of layout features. The number of layout features are linear-shaped and commonly oriented. The layout is split into a number of sub-layouts for the level of the cell. Each of the number of layout features in the layout is allocated to any one of the number of sub-layouts. Also, the layout is split such that each sub-layout is independently fabricatable. The sub-layouts for the level of the cell are stored on a computer readable medium. | 06-26-2014 |
20140167185 | Methods, Structures, and Designs for Self-Aligning Local Interconnects Used in Integrated Circuits - 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. | 06-19-2014 |
20140167183 | Coarse Grid Design Methods and Structures - A layer of a mask material is deposited on a substrate. A beam of energy is scanned across the mask material in a rasterized linear pattern and in accordance with a scan pitch that is based on a pitch of conductive structure segments to be formed on the substrate. The beam of energy is defined to transform the mask material upon which the beam of energy is incident into a removable state. During scanning the beam of energy across the mask material, the beam of energy is turned on at locations where a conductive structure is to be formed on the substrate, and the beam of energy is turned off at locations where a conductive structure is not to be formed on the substrate. | 06-19-2014 |
20140167117 | Methods for Cell Boundary Encroachment and Layouts Implementing the Same - A semiconductor device is disclosed to include a plurality of cells. Each of the cells has a respective outer cell boundary defined to circumscribe the cell in an orthogonal manner. Also, each of the cells includes circuitry for performing one or more logic functions. This circuitry includes a plurality of conductive features defined in one or more levels of the cell. One or more of the conductive features in at least one level of a given cell is an encroaching feature positioned to encroach by an encroachment distance into an exclusion zone. The exclusion zone occupies an area within the cell defined by an exclusion distance extending perpendicularly inward into the given cell from a first segment of the outer cell boundary. The exclusion distance is based on a design rule distance representing a minimum separation distance required between conductive features in adjacently placed cells on the semiconductor device. | 06-19-2014 |
20140159772 | Circuitry and Layouts for XOR and XNOR Logic - An exclusive-or circuit includes a pass gate controlled by a second input node. The pass gate is connected to pass through a version of a logic state present at a first input node to an output node when so controlled. A transmission gate is controlled by the first input node. The transmission gate is connected to pass through a version of the logic state present at the second input node to the output node when so controlled. Pullup logic is controlled by both the first and second input nodes. The pullup logic is connected to drive the output node low when both the first and second input nodes are high. An exclusive-nor circuit is defined similar to the exclusive-or circuit, except that the pullup logic is replaced by pulldown logic which is connected to drive the output node high when both the first and second input nodes are high. | 06-12-2014 |
20140035152 | Methods for Cell Phasing and Placement in Dynamic Array Architecture and Implementation of the Same - 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. | 02-06-2014 |
20140030890 | Super-Self-Aligned Contacts and Method for Making the Same - A number of first hard mask portions are formed on a dielectric layer to vertically shadow a respective one of a number of underlying gate structures. A number of second hard mask filaments are formed adjacent to each side surface of each first hard mask portion. A width of each second hard mask filament is set to define an active area contact-to-gate structure spacing. A first passage is etched between facing exposed side surfaces of a given pair of neighboring second hard mask filaments and through a depth of the semiconductor wafer to an active area. A second passage is etched through a given first hard mask portion and through a depth of the semiconductor wafer to a top surface of the underlying gate structure. An electrically conductive material is deposited within both the first and second passages to respectively form an active area contact and a gate contact. | 01-30-2014 |
20130256898 | Optimizing Layout of Irregular Structures in Regular Layout Context - A plurality of regular wires are formed within a given chip level, each having a linear-shape with a length extending in a first direction and a width extending in a second direction perpendicular to the first direction. The plurality of regular wires are positioned according to a fixed pitch such that a distance as measured in the second direction between lengthwise centerlines of any two regular wires is an integer multiple of the fixed pitch. At least one irregular wire is formed within the given chip level and within a region bounded by the plurality of regular wires. Each irregular wire has a linear-shape with a length extending in the first direction and a width extending in the second direction. A distance as measured in the second direction between lengthwise centerlines of any irregular wire and any regular wire is not equal to an integer multiple of the fixed pitch. | 10-03-2013 |
20130254734 | Standard Cells having transistors annotated for gate-length biasing - A standard cell library is disclosed. The standard cell library contains cells wherein at least one transistor in at least one cell is annotated for gate length biasing. Gate length biasing includes the modification of the gate length, so as to change the speed or power consumption of the modified gate length. The standard cell library is one used in the manufacturing of semiconductor devices (e.g., that result as semiconductor chips), by way of fabricating features defined on one or more layouts of geometric shapes. The annotations serve to identify which ones of the transistor gate features are to be modified before using the geometric shapes for manufacturing the semiconductor device. | 09-26-2013 |
20130254732 | Enforcement of Semiconductor Structure Regularity for Localized Transistors and Interconnect - 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. | 09-26-2013 |
20130214361 | Integrated Circuit Including Cross-Coupled Transistors Having Gate Electrodes Formed Within Gate Level Feature Layout Channels With Gate Contact Position and Offset Specifications - 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. | 08-22-2013 |
20130130511 | Coarse Grid Design Methods and Structures - A layer of a mask material is deposited on a substrate. A beam of energy is scanned across the mask material in a rasterized linear pattern and in accordance with a scan pitch that is based on a pitch of conductive structure segments to be formed on the substrate. The beam of energy is defined to transform the mask material upon which the beam of energy is incident into a removable state. During scanning the beam of energy across the mask material, the beam of energy is turned on at locations where a conductive structure is to be formed on the substrate, and the beam of energy is turned off at locations where a conductive structure is not to be formed on the substrate. | 05-23-2013 |
20130014073 | STANDARD CELLS HAVING TRANSISTORS ANNOTATED FOR GATE-LENGTH BIASING - A standard cell library is disclosed. The standard cell library contains cells wherein at least one transistor in at least one cell is annotated for gate length biasing. Gate length biasing includes the modification of the gate length, so as to change the speed or power consumption of the modified gate length. The standard cell library is one used in the manufacturing of semiconductor devices (e.g., that result as semiconductor chips), by way of fabricating features defined on one or more layouts of geometric shapes. The annotations serve to identify which ones of the transistor gate features are to be modified before using the geometric shapes for manufacturing the semiconductor device. | 01-10-2013 |
20130014072 | STANDARD CELLS HAVING TRANSISTORS ANNOTATED FOR GATE-LENGTH BIASING - A standard cell library is disclosed. The standard cell library contains cells wherein at least one transistor in at least one cell is annotated for gate length biasing. Gate length biasing includes the modification of the gate length, so as to change the speed or power consumption of the modified gate length. The standard cell library is one used in the manufacturing of semiconductor devices (e.g., that result as semiconductor chips), by way of fabricating features defined on one or more layouts of geometric shapes. The annotations serve to identify which ones of the transistor gate features are to be modified before using the geometric shapes for manufacturing the semiconductor device. | 01-10-2013 |
20130014071 | STANDARD CELLS HAVING TRANSISTORS ANNOTATED FOR GATE-LENGTH BIASING - A standard cell library is disclosed. The standard cell library contains cells wherein at least one transistor in at least one cell is annotated for gate length biasing. Gate length biasing includes the modification of the gate length, so as to change the speed or power consumption of the modified gate length. The standard cell library is one used in the manufacturing of semiconductor devices (e.g., that result as semiconductor chips), by way of fabricating features defined on one or more layouts of geometric shapes. The annotations serve to identify which ones of the transistor gate features are to be modified before using the geometric shapes for manufacturing the semiconductor device. | 01-10-2013 |
20120306025 | Integrated Circuit Including Cross-Coupled Transistors with Two Transistors of Different Type Having Gate Electrodes Formed by Common Gate Level Feature with Shared Diffusion Regions on Opposite Sides of Common Gate Level Feature - A semiconductor device includes first and second p-type diffusion regions, and first and second n-type diffusion regions that are each electrically connected to a common node. Each of a number of conductive features within a gate electrode level region is fabricated from a respective originating rectangular-shaped layout feature, with a centerline of each originating rectangular-shaped layout feature aligned in a parallel manner. The conductive features respectively form gate electrodes of first and second PMOS transistor devices, and first and second NMOS transistor devices. Widths of the first and second p-type diffusion regions are substantially equal, such that the first and second PMOS transistor devices have substantially equal widths. Widths of the first and second n-type diffusion regions are substantially equal, such that the first and second NMOS transistor devices have substantially equal widths. The first and second PMOS and first and second NMOS transistor devices form a cross-coupled transistor configuration. | 12-06-2012 |
20120273841 | Methods for Cell Phasing and Placement in Dynamic Array Architecture and Implementation of the Same - 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. | 11-01-2012 |
20120144360 | Scalable Meta-Data Objects - A method is disclosed for defining an integrated circuit. The method includes generating a digital data file that includes both electrical connection information and physical topology information for a number of circuit components. The method also includes operating a computer to execute a layout generation program. The layout generation program reads the electrical connection and physical topology information for each of the number of circuit components from the digital data file and automatically creates one or more layout structures necessary to form each of the number of circuit components in a semiconductor device fabrication process, such that the one or more layout structures comply with the physical topology information read from the digital data file. The computer is also operated to store the one or more layout structures necessary to form each of the number of circuit components in a digital format on a computer readable medium. | 06-07-2012 |
20120118854 | Methods for linewidth modification and apparatus implementing the same - 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. | 05-17-2012 |
20110278681 | Methods, Structures, and Designs for Self-Aligning Local Interconnects used in Integrated Circuits - 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. | 11-17-2011 |
20110198761 | Methods for Multi-Wire Routing and Apparatus Implementing Same - A rectangular interlevel connector array (RICA) is defined in a semiconductor chip. To define the RICA, a virtual grid for interlevel connector placement is defined to include a first set of parallel virtual lines that extend across the layout in a first direction, and a second set of parallel virtual lines that extend across the layout in a second direction perpendicular to the first direction. A first plurality of interlevel connector structures are placed at respective gridpoints in the virtual grid to form a first RICA. The first plurality of interlevel connector structures of the first RICA are placed to collaboratively connect a first conductor channel in a first chip level with a second conductor channel in a second chip level. A second RICA can be interleaved with the first RICA to collaboratively connect third and fourth conductor channels that are respectively interleaved with the first and second conductor channels. | 08-18-2011 |
20110175144 | Integrated Circuit Device Including Dynamic Array Section with Gate Level Having Linear Conductive Features on at Least Three Side-by-Side Lines and Uniform Line End Spacings - An integrated circuit device includes a dynamic array section that includes a gate electrode level region that has linear conductive features defined in accordance with a gate level virtual grate. Each of at least three consecutively positioned virtual lines of the gate level virtual grate has at least one linear conductive feature defined thereon. A first virtual line of the at least three virtual lines has two linear conductive segments defined thereon and separated by a first end-to-end spacing. A second virtual line of the at least three virtual lines has another two linear conductive segments defined thereon and separated by a second end-to-end spacing. A size of the first end-to-end spacing as measured along the first virtual line is substantially equal to a size of the second end-to-end spacing as measured along the second virtual line. | 07-21-2011 |
20110161909 | Methods for Designing Semiconductor Device with Dynamic Array Section - A method is provided for designing an integrated circuit device. The method includes placing four transistors of a first transistor type and four transistors of a second transistor type within a gate electrode level. Each of the transistors includes a respective linear-shaped gate electrode segment positioned to extend lengthwise in a first direction. The transistors of the first and second transistor types are placed according to a substantially equal centerline-to-centerline spacing as measured perpendicular to the first direction. A first linear conductive segment is placed to electrically connect the gate electrodes of the first transistors of the first and second transistor types. A second linear conductive segment is placed to electrically connect the gate electrodes of the fourth transistors of the first and second transistor types. A third linear conductive segment is placed beside either the first or second linear conductive segment. | 06-30-2011 |
20110156167 | Methods for Consumption of Timing Margin to Reduce Power Utilization in Integrated Circuitry and Device Implementing the Same - A circuit is defined to operate in accordance with a common control signal. The circuit includes a plurality of transistors that have respective timing margins relative to the common control signal. Some of the plurality of transistors are defined differently from another of the plurality of transistors with regard to either transistor channel width, transistor channel length, transistor threshold voltage, or a combination thereof. The different definition of any given one of the plurality of transistors causes a reduction of either transistor power consumption, transistor current leakage, or a combination thereof, in exchange for a corresponding reduction in timing margin while maintaining a positive timing margin. | 06-30-2011 |
20110108891 | Semiconductor Device with Dynamic Array Sections Defined and Placed According to Manufacturing Assurance Halos - An integrated circuit device includes a plurality of dynamic array sections, each of which includes three or more linear conductive segments formed within its gate electrode level in a parallel manner to extend lengthwise in a first direction. An adjoining pair of dynamic array sections are positioned to have co-located portions of outer peripheral boundary segments extending in the first direction. At least one of the linear conductive segments within the gate electrode level of a given dynamic array section is a non-gate linear conductive segment that does not form a gate electrode of a transistor. The non-gate linear conductive segment of either of the adjoining pair of dynamic array sections spans the co-located portion of outer peripheral boundary segment toward the other of the adjoining pair of dynamic array sections, and is contained within gate electrode level manufacturing assurance halo portions of the adjoining pair of dynamic array sections. | 05-12-2011 |
20110108890 | Semiconductor Device with Dynamic Array Sections Defined and Placed According to Manufacturing Assurance Halos - An integrated circuit device includes a plurality of dynamic array sections, each of which includes three or more linear conductive segments formed within its gate electrode level in a parallel manner to extend lengthwise in a first direction. An adjoining pair of dynamic array sections are positioned to have co-located portions of outer peripheral boundary segments extending perpendicular to the first direction. Some of the three or more linear conductive segments within the gate electrode levels of the adjoining pair of dynamic array sections are co-aligned in the first direction and separated by an end-to-end spacing that spans the co-located portions of outer peripheral boundary segments of the adjoining pair of dynamic array sections. Each of these end-to-end spacings is sized to ensure that each gate electrode level manufacturing assurance halo portion of the first adjoining pair of dynamic array sections is devoid of the co-aligned linear conductive segments. | 05-12-2011 |
20110084312 | Methods for Cell Boundary Encroachment and Layouts Implementing the Same - A semiconductor device is disclosed to include a plurality of cells. Each of the cells has a respective outer cell boundary defined to circumscribe the cell in an orthogonal manner. Also, each of the cells includes circuitry for performing one or more logic functions. This circuitry includes a plurality of conductive features defined in one or more levels of the cell. One or more of the conductive features in at least one level of a given cell is an encroaching feature positioned to encroach by an encroachment distance into an exclusion zone. The exclusion zone occupies an area within the cell defined by an exclusion distance extending perpendicularly inward into the given cell from a first segment of the outer cell boundary. The exclusion distance is based on a design rule distance representing a minimum separation distance required between conductive features in adjacently placed cells on the semiconductor device. | 04-14-2011 |
20100306719 | Integrated Circuit Cell Library with Cell-Level Process Compensation Technique (PCT) Application and Associated Methods - A layout of cells is generated to satisfy a netlist of an integrated circuit. Cell-level process compensation technique (PCT) processing is performed on a number of levels of one or more cells in the layout to generate a PCT processed version of the one more cells in the layout. An as-fabricated aerial image of each PCT processed cell level is generated to facilitate evaluation of PCT processing adequacy. Cell-level circuit extraction is performed on the PCT processed version of each cell using the generated as-fabricated aerial images. The cell-level PCT processing and cell-level circuit extraction are performed before placing and routing of the layout on a chip. The PCT processed version of the one or more cells and corresponding as-fabricated aerial images are stored in a cell library. | 12-02-2010 |
20100287518 | Cell Circuit and Layout with Linear Finfet Structures - A cell circuit and corresponding layout is disclosed to include linear-shaped diffusion fins defined to extend over a substrate in a first direction so as to extend parallel to each other. Each of the linear-shaped diffusion fins is defined to project upward from the substrate along their extent in the first direction. A number of gate level structures are defined to extend in a conformal manner over some of the number of linear-shaped diffusion fins. Portions of each gate level structure that extend over any of the linear-shaped diffusion fins extend in a second direction that is substantially perpendicular to the first direction. Portions of each gate level structure that extend over any of the linear-shaped diffusion fins form gate electrodes of a corresponding transistor. The diffusion fins and gate level structures can be placed in accordance with a diffusion fin virtual grate and a gate level virtual grate, respectively. | 11-11-2010 |
20100277202 | Circuitry and Layouts for XOR and XNOR Logic - An exclusive-or circuit includes a pass gate controlled by a second input node. The pass gate is connected to pass through a version of a logic state present at a first input node to an output node when so controlled. A transmission gate is controlled by the first input node. The transmission gate is connected to pass through a version of the logic state present at the second input node to the output node when so controlled. Pullup logic is controlled by both the first and second input nodes. The pullup logic is connected to drive the output node low when both the first and second input nodes are high. An exclusive-nor circuit is defined similar to the exclusive-or circuit, except that the pullup logic is replaced by pulldown logic which is connected to drive the output node high when both the first and second input nodes are high. | 11-04-2010 |
20100258879 | Channelized Gate Level Cross-Coupled Transistor Device with Cross-Coupled Transistor Gate Electrode Connections Made Using Linear First Interconnect Level above Gate Electrode Level - A semiconductor device includes first and second p-type diffusion regions, and first and second n-type diffusion regions that are each electrically connected to a common node. Conductive features 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 respectively 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 second NMOS transistor devices are electrically connected in part by a first conductor within a first interconnect level. The gate electrodes of the second PMOS and first NMOS transistor devices are electrically connected in part by a second conductor within the first interconnect level. The first PMOS, second PMOS, first NMOS, and second NMOS transistor devices define a cross-coupled transistor configuration having commonly oriented gate electrodes. | 10-14-2010 |
20100252896 | Methods, Structures, and Designs for Self-Aligning Local Interconnects used in Integrated Circuits - Methods, structures and designs for self-aligned local interconnects are provided. The method includes designing diffusion regions to be in a substrate. Some of a plurality of gates are designed to be active gates and some of the plurality of gates are designed to be formed over isolation regions. The method includes designing the plurality of gates in a regular and repeating alignment along a same direction, and each of the plurality of gates are designed to have dielectric spacers. The method also includes designing a local interconnect layer between or adjacent to the plurality of gates. The local interconnect layer is conductive and disposed over the substrate to allow electrical contact and interconnection with or to some of the diffusion regions of the active gates. The local interconnect layer is self-aligned by the dielectric spacers of the plurality of gates. | 10-07-2010 |
20100252893 | Channelized Gate Level Cross-Coupled Transistor Device with Cross-Coupled Transistors Defined on Three Gate Electrode Tracks with Crossing Gate Electrode Connections - A semiconductor device includes conductive features that are each defined within any one gate level channel 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 second and third gate electrode tracks, respectively. 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. | 10-07-2010 |
20100252892 | Channelized Gate Level Cross-Coupled Transistor Device with Different Width PMOS Transistors and Different Width NMOS Transistors - A semiconductor device includes first and second p-type diffusion regions, and first and second n-type diffusion regions that are each electrically connected to a common node. Conductive features 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 respectively form gate electrodes of first and second PMOS transistor devices, and first and second NMOS transistor devices. Widths of the first and second p-type diffusion regions are different, such that the first and second PMOS transistor devices have different widths. Widths of the first and second n-type diffusion regions are different, such that the first and second NMOS transistor devices have different widths. The first and second PMOS and first and second NMOS transistor devices form a cross-coupled transistor configuration. | 10-07-2010 |
20100252891 | Linear Gate Level Cross-Coupled Transistor Device with Equal Width PMOS Transistors and Equal Width NMOS Transistors - A semiconductor device includes first and second p-type diffusion regions, and first and second n-type diffusion regions that are each electrically connected to a common node. Each of a number of conductive features within a gate electrode level region is fabricated from a respective originating rectangular-shaped layout feature, with a centerline of each originating rectangular-shaped layout feature aligned in a parallel manner. The conductive features respectively form gate electrodes of first and second PMOS transistor devices, and first and second NMOS transistor devices. Widths of the first and second p-type diffusion regions are substantially equal, such that the first and second PMOS transistor devices have substantially equal widths. Widths of the first and second n-type diffusion regions are substantially equal, such that the first and second NMOS transistor devices have substantially equal widths. The first and second PMOS and first and second NMOS transistor devices form a cross-coupled transistor configuration. | 10-07-2010 |
20100252890 | Linear Gate Level Cross-Coupled Transistor Device with Non-Overlapping PMOS Transistors and Non-Overlapping NMOS Transistors Relative to Direction of Gate Electrodes - A semiconductor device includes a cross-coupled transistor configuration formed by first and second PMOS transistors defined over first and second p-type diffusion regions, and by first and second NMOS transistors defined over first and second n-type diffusion regions, with each diffusion region electrically connected to a common node. Gate electrodes of the PMOS and NMOS transistors are formed by conductive features which extend in only a first parallel direction. The first and second p-type diffusion regions are formed in a spaced apart manner, such that no single line of extent that extends perpendicular to the first parallel direction intersects both the first and second p-type diffusion regions. The first and second n-type diffusion regions are formed in a spaced apart manner, such that no single line of extent that extends perpendicular to the first parallel direction intersects both the first and second n-type diffusion regions. | 10-07-2010 |
20100252889 | Linear Gate Level Cross-Coupled Transistor Device with Contiguous p-type Diffusion Regions and Contiguous n-type Diffusion Regions - A semiconductor device includes a substrate having a plurality of diffusion regions defined therein to form first and second p-type diffusion regions, and first and second n-type diffusion regions, with each of these diffusion regions electrically connected to a common node. The first p-type active area and the second p-type active area are contiguously formed together. The first n-type active area and the second n-type active area are contiguously formed together. Each of a number of conductive features within a gate electrode level region of the semiconductor device is fabricated from a respective originating rectangular-shaped layout feature. A centerline of each originating rectangular-shaped layout feature is aligned in a parallel manner. A first PMOS transistor gate electrode is electrically connected to a second NMOS transistor gate electrode, and a second PMOS transistor gate electrode is electrically connected to a first NMOS transistor gate electrode. | 10-07-2010 |
20100237430 | Channelized Gate Level Cross-Coupled Transistor Device with Equal Width PMOS Transistors and Equal Width NMOS Transistors - A semiconductor device includes first and second p-type diffusion regions, and first and second n-type diffusion regions that are each electrically connected to a common node. Gate electrodes are formed from 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 gate electrodes include gate electrodes of first and second PMOS transistor devices, and first and second NMOS transistor devices. Widths of the first and second p-type diffusion regions are substantially equal, such that the first and second PMOS transistor devices have substantially equal widths. Widths of the first and second n-type diffusion regions are substantially equal, such that the first and second NMOS transistor devices have substantially equal widths. The first and second PMOS and first and second NMOS transistor devices form a cross-coupled transistor configuration. | 09-23-2010 |
20100237429 | Channelized Gate Level Cross-Coupled Transistor Device with Non-Overlapping PMOS Transistors and Non-Overlapping NMOS Transistors Relative to Direction of Gate Electrodes - First and second PMOS transistors are defined over first and second p-type diffusion regions. First and second NMOS transistors are defined over first and second n-type diffusion regions. Each diffusion region is electrically connected to a common node. Gate electrodes are formed from 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 first and second p-type diffusion regions are formed in a spaced apart manner, such that no single line of extent that extends perpendicular to the first parallel direction intersects both the first and second p-type diffusion regions. The first and second n-type diffusion regions are formed in a spaced apart manner, such that no single line of extent that extends perpendicular to the first parallel direction intersects both the first and second n-type diffusion regions. | 09-23-2010 |
20100237428 | Channelized Gate Level Cross-Coupled Transistor Device with Non-Overlapping PMOS Transistors and Overlapping NMOS Transistors Relative to Direction of Gate Electrodes - First and second p-type diffusion regions, and first and second n-type diffusion regions are formed in a semiconductor device. Each diffusion region is electrically connected to a common node. Gate electrodes are formed from 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 first and second p-type diffusion regions are formed in a spaced apart manner relative to the first parallel direction, such that no single line of extent that extends across the substrate perpendicular to the first parallel direction intersects both the first and second p-type diffusion regions. At least a portion of the first n-type diffusion region and at least a portion of the second n-type diffusion region are formed over a common line of extent that extends across the substrate perpendicular to the first parallel direction. | 09-23-2010 |
20100237427 | Channelized Gate Level Cross-Coupled Transistor Device with Contiguous p-type Diffusion Regions and Contiguous n-type Diffusion Regions - A semiconductor device includes a substrate having a plurality of diffusion regions defined therein to form first and second p-type diffusion regions, and first and second n-type diffusion regions, with each of these diffusion regions electrically connected to a common node. The first p-type active area and the second p-type active area are contiguously formed together. The first n-type active area and the second n-type active area are contiguously formed together. Gate electrodes are formed from conductive features that are each defined within any one gate level channel. Each gate level channel is uniquely associated with and defined along one of a number of parallel oriented gate electrode tracks. A first PMOS transistor gate electrode is electrically connected to a second NMOS transistor gate electrode, and a second PMOS transistor gate electrode is electrically connected to a first NMOS transistor gate electrode. | 09-23-2010 |
20100237426 | Linear Gate Level Cross-Coupled Transistor Device with Cross-Coupled Transistor Gate Electrode Connections Made Using Linear First Interconnect Level above Gate Electrode Level - A semiconductor device includes first and second p-type diffusion regions, and first and second n-type diffusion regions that are each electrically connected to a common node. Each of a number of conductive features within a gate electrode level region is fabricated from a respective originating rectangular-shaped layout feature having a centerline aligned parallel to a first direction. The conductive features respectively form gate electrodes of first and second PMOS transistor devices, and first and second NMOS transistor devices. Gate electrodes of the first PMOS and second NMOS transistor devices are electrically connected in part by a first conductor within a first interconnect level. Gate electrodes of the second PMOS and first NMOS transistor devices are electrically connected in part by a second conductor within the first interconnect level. The first PMOS, second PMOS, first NMOS, and second NMOS transistor devices define a cross-coupled transistor configuration having commonly oriented gate electrodes. | 09-23-2010 |
20100187634 | Channelized Gate Level Cross-Coupled Transistor Device with Cross-Coupled Transistors Defined on Four Gate Electrode Tracks with Crossing Gate Electrode Connections - 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, second PMOS, first NMOS, and second NMOS transistor devices respectively extend along different gate electrode tracks. 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. | 07-29-2010 |
20100187633 | Channelized Gate Level Cross-Coupled Transistor Device with Cross-Coupled Transistors Defined on Two Gate Electrode Tracks with Crossing Gate Electrode Connections - 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. | 07-29-2010 |
20100187632 | Channelized Gate Level Cross-Coupled Transistor Device with Complimentary Pairs of Cross-Coupled Transistors Defined by Physically Separate Gate Electrodes within Gate Electrode Level - A semiconductor device includes first and second p-type diffusion regions, and first and second n-type diffusion regions that are each electrically connected to a common node. Conductive features 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 respectively 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 second NMOS transistor devices are electrically connected. However, the first PMOS and second NMOS transistor devices are physically separate within the gate electrode level region. The gate electrodes of the second PMOS and first NMOS transistor devices are electrically connected. However, the second PMOS and first NMOS transistor devices are physically separate within the gate electrode level region. | 07-29-2010 |
20100187631 | Channelized Gate Level Cross-Coupled Transistor Device with Constant Gate Electrode Pitch - A semiconductor device includes first and second p-type diffusion regions, and first and second n-type diffusion regions that are each electrically connected to a common node. A gate electrode level region is formed in accordance with a virtual grate defined by virtual lines that extend in only a first parallel direction, such that an equal perpendicular spacing exists between adjacent ones of the virtual lines. Conductive features are each defined within any one gate level channel that is uniquely associated with and defined along one of a number of virtual lines of the virtual grate. 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 second NMOS transistor devices are electrically connected, and the gate electrodes of the second PMOS and first NMOS transistor devices are electrically connected. | 07-29-2010 |
20100187630 | Channelized Gate Level Cross-Coupled Transistor Device with Connection Between Cross-Coupled Transistor Gate Electrodes Made Utilizing Interconnect Level Other than Gate Electrode Level - A semiconductor device includes first and second p-type diffusion regions, and first and second n-type diffusion regions that are each electrically connected to a common node. Conductive features 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 respectively 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 second NMOS transistor devices are electrically connected. The gate electrodes of the second PMOS and first NMOS transistor devices are electrically connected. The electrical connection between the gate electrodes of the first PMOS and second NMOS transistor devices is formed in part by one or more electrical conductors present within at least one interconnect level above the gate electrode level region. | 07-29-2010 |
20100187628 | Channelized Gate Level Cross-Coupled Transistor Device with Overlapping PMOS Transistors and Non-Overlapping NMOS Transistors Relative to Direction of Gate Electrodes - First and second PMOS transistors are defined over first and second p-type diffusion regions. First and second NMOS transistors are defined over first and second n-type diffusion regions. Each diffusion region is electrically connected to a common node. Gate electrodes are formed from 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. At least a portion of each of the first and second p-type diffusion regions are formed over a first common line of extent that extends perpendicular to the first parallel direction. The first and second n-type diffusion regions are formed in a spaced apart manner relative to the first parallel direction, such that no single line of extent that extends across the substrate perpendicular to the first parallel direction intersects both the first and second n-type diffusion regions. | 07-29-2010 |
20100187627 | Channelized Gate Level Cross-Coupled Transistor Device with Overlapping PMOS Transistors and Overlapping NMOS Transistors Relative to Direction of Gate Electrodes - A semiconductor device includes a cross-coupled transistor configuration formed by first and second PMOS transistors defined over first and second p-type diffusion regions, and by first and second NMOS transistors defined over first and second n-type diffusion regions, with each diffusion region electrically connected to a common node. Gate electrodes of the PMOS and NMOS transistors are formed by conductive features that are each defined within any one gate level channel. At least a portion of the first p-type diffusion region and at least a portion of the second p-type diffusion region are formed over a first common line of extent that extends perpendicular to the first parallel direction. Also, at least a portion of the first n-type diffusion region and at least a portion of the second n-type diffusion region are formed over a second common line of extent that extends perpendicular to the first parallel direction. | 07-29-2010 |
20100187626 | Channelized Gate Level Cross-Coupled Transistor Device with Direct Electrical Connection of Cross-Coupled Transistors to Common Diffusion Node - Each of first and second PMOS transistors, and first and second NMOS transistors has a respective diffusion terminal with a direct electrical connection to a common node, and has a respective gate electrode defined within any one gate level channel. Each gate level channel is uniquely associated with and defined along one of a number of parallel oriented gate electrode tracks. The first PMOS transistor gate electrode is electrically connected to the second NMOS transistor electrode. The second PMOS transistor gate electrode is electrically connected to the first NMOS transistor gate electrode. The first and second PMOS transistors, and the first and second NMOS transistors together define a cross-coupled transistor configuration having commonly oriented gate electrodes formed from respective rectangular-shaped layout features. | 07-29-2010 |
20100187625 | Linear Gate Level Cross-Coupled Transistor Device with Cross-Coupled Transistors Defined on Four Gate Electrode Tracks with Crossing Gate Electrode Connections - A semiconductor device includes conductive features within a gate electrode level region that are each fabricated from respective originating rectangular-shaped layout features having its centerline aligned parallel to a first direction. 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, second PMOS, first NMOS, and second NMOS transistor devices respectively extend along different gate electrode tracks. 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. | 07-29-2010 |
20100187624 | Linear Gate Level Cross-Coupled Transistor Device with Cross-Coupled Transistors Defined on Three Gate Electrode Tracks with Crossing Gate Electrode Connections - A semiconductor device includes conductive features within a gate electrode level region that are each fabricated from respective originating rectangular-shaped layout features having its centerline aligned parallel to a first direction. 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 second and third gate electrode tracks, respectively. 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. | 07-29-2010 |
20100187623 | Linear Gate Level Cross-Coupled Transistor Device with Cross-Coupled Transistors Defined on Two Gate Electrode Tracks with Crossing Gate Electrode Connections - A semiconductor device includes conductive features within a gate electrode level region that are each fabricated from a respective originating rectangular-shaped layout feature having a centerline aligned parallel to a first direction. 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. | 07-29-2010 |
20100187622 | Linear Gate Level Cross-Coupled Transistor Device with Complimentary Pairs of Cross-Coupled Transistors Defined by Physically Separate Gate Electrodes within Gate Electrode Level - A semiconductor device includes first and second p-type diffusion regions, and first and second n-type diffusion regions that are each electrically connected to a common node. Each of a number of conductive features within a gate electrode level region is fabricated from a respective originating rectangular-shaped layout feature having a centerline aligned parallel to a first direction. The conductive features respectively 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 second NMOS transistor devices are electrically connected. However, the first PMOS and second NMOS transistor devices are physically separate within the gate electrode level region. The gate electrodes of the second PMOS and first NMOS transistor devices are electrically connected. However, the second PMOS and first NMOS transistor devices are physically separate within the gate electrode level region. | 07-29-2010 |
20100187621 | Linear Gate Level Cross-Coupled Transistor Device with Constant Gate Electrode Pitch - A semiconductor device includes first and second p-type diffusion regions, and first and second n-type diffusion regions that are each electrically connected to a common node. A gate electrode level region is formed in accordance with a virtual grate defined by virtual lines that extend in only a first parallel direction, such that an equal perpendicular spacing exists between adjacent ones of the virtual lines. Each of a number of conductive features within the gate electrode level region is fabricated from a respective originating rectangular-shaped layout feature having a centerline aligned with a virtual line of the virtual grate. 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 second NMOS transistor devices are electrically connected, and the gate electrodes of the second PMOS and first NMOS transistor devices are electrically connected. | 07-29-2010 |
20100187620 | Linear Gate Level Cross-Coupled Transistor Device with Connection Between Cross-Coupled Transistor Gate Electrodes Made Utilizing Interconnect Level Other than Gate Electrode Level - A semiconductor device includes first and second p-type diffusion regions, and first and second n-type diffusion regions that are each electrically connected to a common node. Each of a number of conductive features within a gate electrode level region is fabricated from a respective originating rectangular-shaped layout feature having a centerline aligned parallel to a first direction. The conductive features respectively 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 second NMOS transistor devices are electrically connected. The gate electrodes of the second PMOS and first NMOS transistor devices are electrically connected. The electrical connection between the gate electrodes of the first PMOS and second NMOS transistor devices is formed in part by one or more electrical conductors present within at least one interconnect level above the gate electrode level region. | 07-29-2010 |
20100187619 | Linear Gate Level Cross-Coupled Transistor Device with Different Width PMOS Transistors and Different Width NMOS Transistors - A semiconductor device includes first and second p-type diffusion regions, and first and second n-type diffusion regions that are each electrically connected to a common node. Each of a number of conductive features within a gate electrode level region is fabricated from a respective originating rectangular-shaped layout feature, with a centerline of each originating rectangular-shaped layout feature aligned in a parallel manner. The conductive features respectively form gate electrodes of first and second PMOS transistor devices, and first and second NMOS transistor devices. Widths of the first and second p-type diffusion regions are different, such that the first and second PMOS transistor devices have different widths. Widths of the first and second n-type diffusion regions are different, such that the first and second NMOS transistor devices have different widths. The first and second PMOS and first and second NMOS transistor devices form a cross-coupled transistor configuration. | 07-29-2010 |
20100187618 | Linear Gate Level Cross-Coupled Transistor Device with Overlapping PMOS Transistors and Non-Overlapping NMOS Transistors Relative to Direction of Gate Electrodes - A semiconductor device includes a cross-coupled transistor configuration formed by first and second PMOS transistors defined over first and second p-type diffusion regions, and by first and second NMOS transistors defined over first and second n-type diffusion regions, with each diffusion region electrically connected to a common node. Gate electrodes of the PMOS and NMOS transistors are formed by conductive features which extend in only a first parallel direction. At least a portion of each of the first and second p-type diffusion regions are formed over a first common line of extent that extends perpendicular to the first parallel direction. The first and second n-type diffusion regions are formed in a spaced apart manner relative to the first parallel direction, such that no single line of extent that extends across the substrate perpendicular to the first parallel direction intersects both the first and second n-type diffusion regions. | 07-29-2010 |
20100187617 | Linear Gate Level Cross-Coupled Transistor Device with Non-Overlapping PMOS Transistors and Overlapping NMOS Transistors Relative to Direction of Gate Electrodes - First and second p-type diffusion regions, and first and second n-type diffusion regions are formed in a semiconductor device. Each diffusion region is electrically connected to a common node. Gate electrodes of cross-coupled transistors are defined to extend over the diffusion regions in only a first parallel direction, with each gate electrode fabricated from a respective originating rectangular-shaped layout feature. The first and second p-type diffusion regions are formed in a spaced apart manner relative to the first parallel direction, such that no single line of extent that extends across the substrate perpendicular to the first parallel direction intersects both the first and second p-type diffusion regions. At least a portion of the first n-type diffusion region and at least a portion of the second n-type diffusion region are formed over a common line of extent that extends across the substrate perpendicular to the first parallel direction. | 07-29-2010 |
20100187616 | Linear Gate Level Cross-Coupled Transistor Device with Overlapping PMOS Transistors and Overlapping NMOS Transistors Relative to Direction of Gate Electrodes - A semiconductor device includes a cross-coupled transistor configuration formed by first and second PMOS transistors defined over first and second p-type diffusion regions, and by first and second NMOS transistors defined over first and second n-type diffusion regions, with each diffusion region electrically connected to a common node. Gate electrodes of the PMOS and NMOS transistors are formed by conductive features which extend in only a first parallel direction. At least a portion of the first p-type diffusion region and at least a portion of the second p-type diffusion region are formed over a first common line of extent that extends perpendicular to the first parallel direction. Also, at least a portion of the first n-type diffusion region and at least a portion of the second n-type diffusion region are formed over a second common line of extent that extends perpendicular to the first parallel direction. | 07-29-2010 |
20100187615 | Linear Gate Level Cross-Coupled Transistor Device with Direct Electrical Connection of Cross-Coupled Transistors to Common Diffusion Node - Each of first and second PMOS transistors, and first and second NMOS transistors has a respective diffusion terminal with a direct electrical connection to a common node, and has a respective gate electrode formed from an originating rectangular-shaped layout feature. Centerlines of the originating rectangular-shaped layout features are aligned to be parallel with a first direction. The first PMOS transistor gate electrode is electrically connected to the second NMOS transistor electrode. The second PMOS transistor gate electrode is electrically connected to the first NMOS transistor gate electrode. The first and second PMOS transistors, and the first and second NMOS transistors together define a cross-coupled transistor configuration having commonly oriented gate electrodes formed from respective rectangular-shaped layout features. | 07-29-2010 |
20100096671 | Cell of Semiconductor Device Having Gate Electrode Conductive Structures Formed from Rectangular Shaped Gate Electrode Layout Features and At Least Eight Transistors - A cell of a semiconductor device includes a substrate portion formed to include a plurality of diffusion regions, including at least one p-type diffusion region and at least one n-type diffusion region separated from each other by one or more non-active regions. The cell includes a gate electrode level including a number of conductive features defined to extend in only a first parallel direction. Each of the conductive features within the gate electrode level is fabricated from a respective originating rectangular-shaped layout feature. Some of the conductive features form respective PMOS and/or NMOS transistor devices. A total number of the PMOS and NMOS transistor devices in the cell is greater than or equal to eight. The cell also includes a number of interconnect levels formed above the gate electrode level. | 04-22-2010 |
20100037195 | Layout of Cell of Semiconductor Device Having Linear Shaped Gate Electrode Layout Features Defined with Minimum End-to-End Spacing and Having Equal Number of PMOS and NMOS Transistors and Having Corresponding p-type and n-type Diffusion Regions Separated by Central Inactive Region - A cell layout of a semiconductor device includes a diffusion level layout including a plurality of diffusion region layout shapes, including p-type and n-type diffusion regions separated by a central inactive region. The cell layout also includes a gate electrode level layout for the entire cell defined to include linear-shaped layout features placed to extend in only a first parallel direction. Adjacent linear-shaped layout features that share a common line of extent in the first parallel direction are separated from each other by an end-to-end spacing that is substantially equal and minimized across the gate electrode level layout. Linear-shaped layout features within the gate electrode level layout extend over one or more of the p-type and/or n-type diffusion regions to form PMOS and NMOS transistor devices. A number of the PMOS transistor devices is equal to a number of the NMOS transistor devices in the cell. | 02-11-2010 |
20100037194 | Layout of Cell of Semiconductor Device Having Linear Shaped Gate Electrode Layout Features Defined with Minimum End-to-End Spacing and Having Equal Number of PMOS and NMOS Transistors - A cell layout of a semiconductor device includes a diffusion level layout including a plurality of diffusion region layout shapes, including p-type and n-type diffusion regions. The cell layout also includes a gate electrode level layout defined to include linear-shaped layout features placed to extend in only a first parallel direction. Adjacent linear-shaped layout features that share a common line of extent in the first parallel direction are separated from each other by an end-to-end spacing that is substantially equal across the gate electrode level layout and that is minimized to an extent allowed by a semiconductor device manufacturing capability. Linear-shaped layout features within the gate electrode level layout extend over one or more of the p-type and/or n-type diffusion regions to form PMOS and NMOS transistor devices. A number of the PMOS transistor devices is equal to a number of the NMOS transistor devices in the cell. | 02-11-2010 |
20100032726 | Semiconductor Device Portion Having Sub-193 Nanometers -Sized Gate Electrode Conductive Structures Formed from Linear Shaped Gate Electrode Layout Features Defined Along At Least Four Gate Electrode Tracks with Minimum End-to-End Spacing and Having Corresponding Non-Symmetric Diffusion Regions - A semiconductor device includes a substrate portion including a plurality of diffusion regions defined in a non-symmetrical manner relative to a virtual bisecting line. A gate electrode level region above the substrate portion includes a number of conductive features that extend in only a first parallel direction. Adjacent conductive features that share a common line of extent in the first parallel direction are fabricated from respective originating layout features separated by an equal and minimal sized end-to-end spacing. Conductive features are defined along at least four different virtual lines of extent in the first parallel direction. A width of the conductive features within a photolithographic interaction radius is less than a wavelength of light of 193 nanometers as used in a photolithography process for their fabrication. The photolithographic interaction radius is five times the wavelength of light used in the photolithography process. | 02-11-2010 |
20100032724 | Cell of Semiconductor Device Having Sub-193 Nanometers-Sized Gate Electrode Conductive Structures Formed from Rectangular Shaped Gate Electrode Layout Features and Equal Number of PMOS and NMOS Transistors - A cell of a semiconductor device includes a substrate portion formed to include a plurality of diffusion regions, including at least one p-type diffusion region and at least one n-type diffusion region separated from each other by non-active regions. The cell includes a gate electrode level including a number of conductive features defined to extend in only a first parallel direction. Each of the conductive features within the gate electrode level is fabricated from a respective originating rectangular-shaped layout feature. A width size of the conductive features within a five wavelength photolithographic interaction radius within the gate electrode level is less than a wavelength of light of 193 nanometers. Some of the conductive features form respective PMOS and/or NMOS transistor devices. The cell includes an equal number of PMOS and NMOS transistor devices. The cell also includes a number of interconnect levels formed above the gate electrode level. | 02-11-2010 |
20100032723 | Semiconductor Device Portion Having Sub-Wavelength-Sized Gate Electrode Conductive Structures Formed from Linear Shaped Gate Electrode Layout Features Defined with Minimum End-to-End Spacing and Having At Least Eight Transistors - A semiconductor device includes a substrate portion having a plurality of diffusion regions defined therein. A gate electrode level region is formed above the substrate portion to include conductive features defined to extend in only a first parallel direction. Adjacent ones of the conductive features that share a common line of extent in the first parallel direction are fabricated from respective originating layout features that are separated from each other by an end-to-end spacing having a substantially equal and minimum size across the gate electrode level region. A width of the conductive features is less than a wavelength of light used in a photolithography process for their fabrication. Some of the conductive features extend over the plurality of diffusion regions to form PMOS or NMOS transistor devices. A total number of the PMOS and NMOS transistor devices in the gate electrode level region is greater than or equal to eight. | 02-11-2010 |
20100032722 | Semiconductor Device Portion Having Gate Electrode Conductive Structures Formed from Linear Shaped Gate Electrode Layout Features Defined with Minimum End-to-End Spacing and Having At Least Eight Transistors - A semiconductor device includes a substrate portion having a plurality of diffusion regions defined therein. The semiconductor device includes a gate electrode level region including a number of conductive features defined to extend in only a first parallel direction. Adjacent ones of the number of conductive features that share a common line of extent in the first parallel direction are fabricated from respective originating layout features that are separated from each other by an end-to-end spacing having a size that is substantially equal across the gate electrode level region and is minimized to an extent allowed by a semiconductor device manufacturing capability. Some of the conductive features within the gate electrode level region extend over the plurality of diffusion regions to form PMOS or NMOS transistor devices. A total number of the PMOS and NMOS transistor devices in the gate electrode level region is greater than or equal to eight. | 02-11-2010 |
20100032721 | Semiconductor Device Portion Having Sub-193 Nanometers -Sized Gate Electrode Conductive Structures Formed from Linear Shaped Gate Electrode Layout Features Defined with Minimum End-to-End Spacing and Having Equal Number of PMOS and NMOS Transistors - A semiconductor device includes a substrate portion having a plurality of diffusion regions defined therein. A gate electrode level region is formed above the substrate portion to include conductive features defined to extend in only a first parallel direction. Adjacent ones of the conductive features that share a common line of extent are fabricated from respective originating layout features separated from each other by an end-to-end spacing of substantially equal and minimum size across the gate electrode level region. A width of the conductive features within a 5 wavelength photolithographic interaction radius is less than a 193 nanometer wavelength of light used in a photolithography process for their fabrication. Some conductive features extend over the plurality of diffusion regions to form PMOS or NMOS transistor devices. A number of the PMOS transistor devices is equal to a number of the NMOS transistor devices in the gate electrode level region. | 02-11-2010 |
20100031211 | Methods for Controlling Microloading Variation in Semiconductor Wafer Layout and Fabrication - 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. | 02-04-2010 |
20100025736 | Cell of Semiconductor Device Having Gate Electrode Conductive Structures Formed from Linear Shaped Gate Electrode Layout Features Defined with Minimum End-to-End Spacing and At Least Eight Transistors - A cell of a semiconductor device includes a diffusion level including a plurality of diffusion regions separated by inactive regions. The cell also includes a gate electrode level including conductive features defined to extend in only a first parallel direction. Adjacent ones of the conductive features that share a common line of extent in the first parallel direction are fabricated from respective originating layout features that are separated from each other by an end-to-end spacing having a size that is substantially equal across the gate electrode level region and is minimized to an extent allowed by a semiconductor device manufacturing capability. Some of the conductive features form respective PMOS and/or NMOS transistor devices. A total number of the PMOS and NMOS transistor devices in the cell is greater than or equal to eight. The cell also includes a number of interconnect levels formed above the gate electrode level. | 02-04-2010 |
20100025735 | Cell of Semiconductor Device Having Sub-193 Nanometers-Sized Gate Electrode Conductive Structures Formed from Linear Shaped Gate Electrode Layout Features Defined with Minimum End-to-End Spacing and Equal Number of PMOS and NMOS Transistors - A cell of a semiconductor device includes a diffusion level including a plurality of diffusion regions separated by inactive regions. The cell includes a gate electrode level including conductive features defined to extend in only a first parallel direction. Adjacent conductive features that share a common line of extent in the first parallel direction are fabricated from respective originating layout features that are separated from each other by an end-to-end spacing having a size that is substantially equal and minimized across the gate electrode level region. Some of the conductive features form respective PMOS and/or NMOS transistor devices. A number of the PMOS transistor devices is equal to a number of the NMOS transistor devices in the cell. A width of the conductive features within a five wavelength photolithographic interaction radius is less than a wavelength of light of 193 nanometers as used in a photolithography process for their fabrication. | 02-04-2010 |
20100025734 | Cell of Semiconductor Device Having Sub-Wavelength-Sized Gate Electrode Conductive Structures Formed from Linear Shaped Gate Electrode Layout Features Defined with Minimum End-to-End Spacing and Equal Number of PMOS and NMOS Transistors - A cell of a semiconductor device includes a diffusion level including a plurality of diffusion regions separated by inactive regions. The cell also includes a gate electrode level including conductive features defined to extend in only a first parallel direction. Adjacent ones of the conductive features that share a common line of extent in the first parallel direction are fabricated from respective originating layout features that are separated from each other by an end-to-end spacing having a size that is substantially equal and minimized across the gate electrode level. Some of the conductive features form respective PMOS and/or NMOS transistor devices. A number of the PMOS transistor devices is equal to a number of the NMOS transistor devices in the cell. A width of the conductive features in the gate electrode level is less than a wavelength of light used in a photolithography process for their fabrication. | 02-04-2010 |
20100025733 | Cell of Semiconductor Device Having Sub-193 Nanometers-Sized Gate Electrode Conductive Structures Formed from Linear Shaped Gate Electrode Layout Features Defined with Minimum End-to-End Spacing and At Least Eight Transistors - A cell of a semiconductor device includes a diffusion level including a plurality of diffusion regions separated by inactive regions. The cell includes a gate electrode level including conductive features defined to extend in only a first parallel direction. Adjacent conductive features that share a common line of extent in the first parallel direction are fabricated from respective originating layout features that are separated from each other by an end-to-end spacing having a size that is substantially equal and minimized across the gate electrode level region. Some of the conductive features form respective PMOS and/or NMOS transistor devices. A total number of the PMOS and NMOS transistor devices in the cell is greater than or equal to eight. A width of the conductive features within a five wavelength photolithographic interaction radius is less than a wavelength of light of 193 nanometers as used in a photolithography process for their fabrication. | 02-04-2010 |
20100025732 | Cell of Semiconductor Device Having Sub-Wavelength-Sized Gate Electrode Conductive Structures Formed from Linear Shaped Gate Electrode Layout Features Defined with Minimum End-to-End Spacing and At Least Eight Transistors - A cell of a semiconductor device includes a diffusion level including a plurality of diffusion regions separated by inactive regions. The cell also includes a gate electrode level including conductive features defined to extend in only a first parallel direction. Adjacent ones of the conductive features that share a common line of extent in the first parallel direction are fabricated from respective originating layout features that are separated from each other by an end-to-end spacing having a size that is substantially equal and minimized across the gate electrode level. Some of the conductive features form respective PMOS and/or NMOS transistor devices. A total number of the PMOS and NMOS transistor devices in the cell is greater than or equal to eight. A width of the conductive features in the gate electrode level is less than a wavelength of light used in a photolithography process for their fabrication. | 02-04-2010 |
20100025731 | Cell of Semiconductor Device Having Gate Electrode Conductive Structures Formed from Linear Shaped Gate Electrode Layout Features Defined with Minimum End-to-End Spacing and Equal Number of PMOS and NMOS Transistors - A cell of a semiconductor device includes a diffusion level including a plurality of diffusion regions separated by inactive regions. The cell also includes a gate electrode level including conductive features defined to extend in only a first parallel direction. Adjacent ones of the conductive features that share a common line of extent in the first parallel direction are fabricated from respective originating layout features that are separated from each other by an end-to-end spacing having a size that is substantially equal across the gate electrode level region and is minimized to an extent allowed by a semiconductor device manufacturing capability. Some of the conductive features form respective PMOS and/or NMOS transistor devices. A number of the PMOS transistor devices is equal to a number of the NMOS transistor devices in the cell. The cell also includes a number of interconnect levels formed above the gate electrode level. | 02-04-2010 |
20100023911 | Layout of Cell of Semiconductor Device Having Linear Shaped Gate Electrode Layout Features Defined with Minimum End-to-End Spacing and Having At Least Eight Transistors - A cell layout of a semiconductor device includes a diffusion level layout including a plurality of diffusion region layout shapes, including p-type and n-type diffusion regions. The cell layout also includes a gate electrode level layout defined to include linear-shaped layout features placed to extend in only a first parallel direction. Adjacent linear-shaped layout features that share a common line of extent in the first parallel direction are separated from each other by an end-to-end spacing that is substantially equal across the gate electrode level layout and that is minimized to an extent allowed by a semiconductor device manufacturing capability. Linear-shaped layout features within the gate electrode level layout extend over one or more of the p-type and/or n-type diffusion regions to form PMOS and NMOS transistor devices. A total number of the PMOS and NMOS transistor devices in the cell is greater than or equal to eight. | 01-28-2010 |
20100023908 | Layout of Cell of Semiconductor Device Having Linear Shaped Gate Electrode Layout Features Defined with Minimum End-to-End Spacing and Having At Least Eight Transistors and Having Corresponding p-type and n-type Diffusion Regions Separated by Central Inactive Region - A cell layout of a semiconductor device includes a diffusion level layout including a plurality of diffusion region layout shapes, including p-type and n-type diffusion regions separated by a central inactive region. The cell layout also includes a gate electrode level layout for the entire cell defined to include linear-shaped layout features placed to extend in only a first parallel direction. Adjacent linear-shaped layout features that share a common line of extent in the first parallel direction are separated from each other by an end-to-end spacing that is substantially equal and minimized across the gate electrode level layout. Linear-shaped layout features within the gate electrode level layout extend over one or more of the p-type and/or n-type diffusion regions to form PMOS and NMOS transistor devices. A total number of the PMOS and NMOS transistor devices in the cell is greater than or equal to eight. | 01-28-2010 |
20100023907 | Layout of Cell of Semiconductor Device Having Linear Shaped Gate Electrode Layout Features Defined Along At Least Four Gate Electrode Tracks with Minimum End-to-End Spacing and Having Corresponding p-type and n-type Diffusion Regions Separated by Central Inactive Region - A cell layout of a semiconductor device includes a diffusion level layout including a plurality of diffusion region layout shapes. The cell layout also includes a gate electrode level layout defined to include linear-shaped layout features placed to extend in only a first parallel direction. Adjacent linear-shaped layout features that share a common line of extent in the first parallel direction are separated from each other by an end-to-end spacing that is substantially equal across the gate electrode level layout and that is minimized to an extent allowed by a semiconductor device manufacturing capability. The gate electrode level layout includes linear-shaped layout features defined along at least four different lines of extent in the first parallel direction. The cell layout also includes a number of interconnect level layouts each defined to pattern conductive features within corresponding interconnect levels above the gate electrode level of the cell. | 01-28-2010 |
20100023906 | Layout of Cell of Semiconductor Device Having Linear Shaped Gate Electrode Layout Features Defined Along At Least Four Gate Electrode Tracks with Minimum End-to-End Spacing - A cell layout of a semiconductor device includes a diffusion level layout including a plurality of diffusion region layout shapes. The cell layout also includes a gate electrode level layout defined to include linear-shaped layout features placed to extend in only a first parallel direction. Adjacent linear-shaped layout features that share a common line of extent in the first parallel direction are separated from each other by an end-to-end spacing that is substantially equal across the gate electrode level layout and that is minimized to an extent allowed by a semiconductor device manufacturing capability. The gate electrode level layout includes linear-shaped layout features defined along at least four different lines of extent in the first parallel direction. The cell layout also includes a number of interconnect level layouts each defined to pattern conductive features within corresponding interconnect levels above the gate electrode level of the cell. | 01-28-2010 |
20100019288 | Cell of Semiconductor Device Having Sub-Wavelength-Sized Gate Electrode Conductive Structures Formed from Linear Shaped Gate Electrode Layout Features Defined Along At Least Four Gate Electrode Tracks with Minimum End-to-End Spacing - A cell of a semiconductor device is disclosed to include a diffusion level including a plurality of diffusion regions separated by inactive regions. The cell also includes a gate electrode level including conductive features defined to extend in only a first parallel direction. Adjacent ones of the conductive features that share a common line of extent in the first parallel direction are fabricated from respective originating layout features that are separated from each other by an end-to-end spacing having a size that is substantially equal across the gate electrode level region and is minimized to an extent allowed by a semiconductor device manufacturing capability. The gate electrode level includes conductive features defined along at least four different virtual lines of extent in the first parallel direction. A width of the conductive features is less than a wavelength of light used in a photolithography process for their fabrication. | 01-28-2010 |
20100019287 | Cell of Semiconductor Device Having Sub-193 Nanometers-Sized Gate Electrode Conductive Structures Formed from Linear Shaped Gate Electrode Layout Features Defined Along At Least Four Gate Electrode Tracks with Minimum End-to-End Spacing - A cell of a semiconductor device is disclosed to include a diffusion level including a plurality of diffusion regions separated by inactive regions. The cell also includes a gate electrode level including conductive features defined to extend in only a first parallel direction. Adjacent ones of the conductive features that share a common line of extent in the first parallel direction are fabricated from respective originating layout features that are separated from each other by an end-to-end spacing having a size that is substantially equal and minimized across the gate electrode level region. The gate electrode level includes conductive features defined along at least four different virtual lines of extent in the first parallel direction. A width of the conductive features within a five wavelength photolithographic interaction radius is less than a wavelength of light of 193 nanometers as used in a photolithography process for their fabrication. | 01-28-2010 |
20100019286 | Cell of Semiconductor Device Having Gate Electrode Conductive Structures Formed from Linear Shaped Gate Electrode Layout Features Defined Along At Least Four Gate Electrode Tracks with Minimum End-to-End Spacing - A cell of a semiconductor device is disclosed to include a diffusion level including a plurality of diffusion regions separated by inactive regions. The cell also includes a gate electrode level including a number of conductive features defined to extend in only a first parallel direction. Adjacent ones of the number of conductive features that share a common line of extent in the first parallel direction are fabricated from respective originating layout features that are separated from each other by an end-to-end spacing having a size that is substantially equal across the gate electrode level region and is minimized to an extent allowed by a semiconductor device manufacturing capability. The gate electrode level includes conductive features defined along at least four different virtual lines of extent in the first parallel direction. The cell also includes a number of interconnect levels formed above the gate electrode level. | 01-28-2010 |
20100019285 | Cell of Semiconductor Device Having Sub-193 Nanometers-Sized Gate Electrode Conductive Structures Formed from Rectangular Shaped Gate Electrode Layout Features and At Least Eight Transistors - A cell of a semiconductor device includes a substrate portion formed to include at least one p-type diffusion region and at least one n-type diffusion region separated by non-active regions. The cell includes a gate electrode level including a number of conductive features defined to extend in only a first parallel direction. Each of the conductive features within the gate electrode level is fabricated from a respective originating rectangular-shaped layout feature. A width size of the conductive features within a five wavelength photolithographic interaction radius within the gate electrode level is less than a wavelength of light of 193 nanometers. Some of the conductive features form respective PMOS and/or NMOS transistor devices. A total number of the PMOS and NMOS transistor devices in the cell is greater than or equal to eight. The cell also includes a number of interconnect levels formed above the gate electrode level. | 01-28-2010 |
20100019284 | Cell of Semiconductor Device Having Sub-Wavelength-Sized Gate Electrode Conductive Structures Formed from Rectangular Shaped Gate Electrode Layout Features and At Least Eight Transistors - A cell of a semiconductor device includes a substrate portion formed to include at least one p-type diffusion region and at least one n-type diffusion region separated by non-active regions. The cell includes a gate electrode level including a number of conductive features defined to extend in only a first parallel direction. Each of the conductive features within the gate electrode level is fabricated from a respective originating rectangular-shaped layout feature. A width of the conductive features is less than a wavelength of light used in a photolithography process for their fabrication. Some of the conductive features form respective PMOS and/or NMOS transistor devices. A total number of the PMOS and NMOS transistor devices in the cell is greater than or equal to eight. The cell also includes a number of interconnect levels formed above the gate electrode level. | 01-28-2010 |
20100019283 | Cell of Semiconductor Device Having Sub-Wavelength-Sized Gate Electrode Conductive Structures Formed from Rectangular Shaped Gate Electrode Layout Features and Equal Number of PMOS and NMOS Transistors - A cell of a semiconductor device includes a substrate portion including a plurality of diffusion regions, including at least one p-type diffusion region and at least one n-type diffusion region separated by one or more non-active regions. The cell includes a gate electrode level including a number of conductive features defined to extend in only a first parallel direction. Each of the conductive features is fabricated from a respective originating rectangular-shaped layout feature. A width of the conductive features is less than a wavelength of light used in a photolithography process for their fabrication. Some of the conductive features form respective PMOS and/or NMOS transistor devices. A number of the PMOS transistor devices is equal to a number of the NMOS transistor devices in the gate electrode level. The cell also includes a number of interconnect levels formed above the gate electrode level. | 01-28-2010 |
20100019282 | Cell of Semiconductor Device Having Sub-193 Nanometers-Sized Gate Electrode Conductive Structures Formed from Rectangular Shaped Gate Electrode Layout Features Defined Along At Least Four Gate Electrode Tracks - A cell of a semiconductor device is disclosed to include a diffusion level including a plurality of diffusion regions separated by inactive regions. The cell also includes a gate electrode level including a number of conductive features defined to extend in only a first parallel direction. Each of the conductive features within the gate electrode level is fabricated from a respective originating rectangular-shaped layout feature. The gate electrode level includes conductive features defined along at least four different virtual lines of extent in the first parallel direction. A width size of the conductive features within a five wavelength photolithographic interaction radius within the gate electrode level is less than a wavelength of light of 193 nanometers. The cell also includes a number of interconnect levels formed above the gate electrode level. | 01-28-2010 |
20100019281 | Cell of Semiconductor Device Having Sub-Wavelength-Sized Gate Electrode Conductive Structures Formed from Rectangular Shaped Gate Electrode Layout Features Defined Along At Least Four Gate Electrode Tracks - A cell of a semiconductor device is disclosed to include a diffusion level including a plurality of diffusion regions separated by inactive regions. The cell also includes a gate electrode level including a number of conductive features defined to extend in only a first parallel direction. Each of the conductive features within the gate electrode level is fabricated from a respective originating rectangular-shaped layout feature. The gate electrode level includes conductive features defined along at least four different virtual lines of extent in the first parallel direction. A width of the conductive features within the gate electrode level is measured perpendicular to the first parallel direction and is less than a wavelength of light used in a photolithography process to fabricate the conductive features. The cell also includes a number of interconnect levels formed above the gate electrode level. | 01-28-2010 |
20100019280 | Cell of Semiconductor Device Having Gate Electrode Conductive Structures Formed from Rectangular Shaped Gate Electrode Layout Features Defined Along At Least Four Gate Electrode Tracks - A cell of a semiconductor device is disclosed to include a diffusion level including a plurality of diffusion regions separated by inactive regions. The cell also includes a gate electrode level including a number of conductive features defined to extend in only a first parallel direction. Each of the conductive features within the gate electrode level is fabricated from a respective originating rectangular-shaped layout feature. The gate electrode level includes conductive features defined along at least four different virtual lines of extent in the first parallel direction. The cell also includes a number of interconnect levels formed above the gate electrode level. | 01-28-2010 |
20100017772 | Layout of Cell of Semiconductor Device Having Rectangular Shaped Gate Electrode Layout Features and At Least Eight Transistors with Corresponding p-type and n-type Diffusion Regions Separated by Central Inactive Region - A layout of a cell of a semiconductor device is disclosed to include a diffusion level layout including a plurality of diffusion region layout shapes, including a p-type and an n-type diffusion region separated by a central inactive region. The layout of the cell includes a gate electrode level layout corresponding to an entire gate level of the cell. The gate electrode layout includes a number of linear-shaped layout features placed to extend in only a first parallel direction. Each of the number of the linear-shaped layout features within the gate electrode level layout of the restricted layout region is rectangular-shaped. Linear-shaped layout features within the gate electrode level layout extend over one or more of the p-type and/or n-type diffusion regions to form PMOS and NMOS transistor devices. A total number of the PMOS and NMOS transistor devices in the cell is greater than or equal to eight. | 01-21-2010 |
20100017771 | Layout of Cell of Semiconductor Device Having Rectangular Shaped Gate Electrode Layout Features and At Least Eight Transistors - A layout of a cell of a semiconductor device is disclosed to include a diffusion level layout including a plurality of diffusion region layout shapes, including p-type and n-type diffusion regions. The layout of the cell also includes a gate electrode level layout defined to include a number of linear-shaped layout features placed to extend in only a first parallel direction. Each of the number of the linear-shaped layout features within the gate electrode level layout of the restricted layout region is rectangular-shaped. Linear-shaped layout features within the gate electrode level layout extend over one or more of the p-type and/or n-type diffusion regions to form PMOS and NMOS transistor devices. A total number of the PMOS and NMOS transistor devices in the cell is greater than or equal to eight. | 01-21-2010 |
20100017770 | Layout of Cell of Semiconductor Device Having Rectangular Shaped Gate Electrode Layout Features and Equal Number of PMOS and NMOS Transistors with Corresponding p-type and n-type Diffusion Regions Separated by Central Inactive Region - A layout of a cell of a semiconductor device is disclosed to include a diffusion level layout including a plurality of diffusion region layout shapes, including a p-type and an n-type diffusion region separated by a central inactive region. The layout of the cell includes a gate electrode level layout corresponding to an entire gate level of the cell. The gate electrode layout includes a number of linear-shaped layout features placed to extend in only a first parallel direction. Each of the number of the linear-shaped layout features within the gate electrode level layout of the restricted layout region is rectangular-shaped. Linear-shaped layout features within the gate electrode level layout extend over one or more of the p-type and/or n-type diffusion regions to form PMOS and NMOS transistor devices. A number of the PMOS transistor devices is equal to a number of the NMOS transistor devices in the cell. | 01-21-2010 |
20100017769 | Layout of Cell of Semiconductor Device Having Rectangular Shaped Gate Electrode Layout Features and Equal Number of PMOS and NMOS Transistors - A layout of a cell of a semiconductor device is disclosed to include a diffusion level layout including a plurality of diffusion region layout shapes, including p-type and n-type diffusion regions. The layout of the cell also includes a gate electrode level layout is defined to include a number of linear-shaped layout features placed to extend in only a first parallel direction. Each of the number of the linear-shaped layout features within the gate electrode level layout of the restricted layout region is rectangular-shaped. Linear-shaped layout features within the gate electrode level layout extend over one or more of the p-type and/or n-type diffusion regions to form PMOS and NMOS transistor devices. A number of the PMOS transistor devices is equal to a number of the NMOS transistor devices in the cell. | 01-21-2010 |
20100017768 | Layout of Cell of Semiconductor Device Having Rectangular Shaped Gate Electrode Layout Features Defined Along At Least Four Gate Electrode Tracks with Corresponding p-type and n-type Diffusion Regions Separated by Central Inactive Region - A layout of a cell of a semiconductor device is disclosed to include a diffusion level layout including a plurality of diffusion region layout shapes to be formed within a portion of a substrate, including a p-type diffusion region layout shape and an n-type diffusion region layout shape separated by a central inactive region. The layout of the cell also includes a gate electrode level layout defined to include a number of linear-shaped layout features placed to extend in only a first parallel direction. Each of the number of the linear-shaped layout features within the gate electrode level layout of the restricted layout region is rectangular-shaped. The gate electrode level layout includes linear-shaped layout features defined along at least four different lines of extent in the first parallel direction. The gate electrode level layout corresponds to an entire gate electrode level of the cell. | 01-21-2010 |
20100017767 | Layout of Cell of Semiconductor Device Having Rectangular Shaped Gate Electrode Layout Features Defined Along At Least Four Gate Electrode Tracks - A layout of a cell of a semiconductor device is disclosed to include a diffusion level layout including a plurality of diffusion region layout shapes. The layout of the cell also includes a gate electrode level layout is defined to include a number of linear-shaped layout features placed to extend in only a first parallel direction. Each of the number of the linear-shaped layout features within the gate electrode level layout of the restricted layout region is rectangular-shaped. The gate electrode level layout includes linear-shaped layout features defined along at least four different lines of extent in the first parallel direction. The layout of the cell also includes a number of interconnect level layouts each of which is defined to pattern conductive features within corresponding interconnect levels above the gate electrode level. | 01-21-2010 |
20100017766 | Semiconductor Device Layout Including Cell Layout Having Restricted Gate Electrode Level Layout with Linear Shaped Gate Electrode Layout Features Defined with Minimum End-to-End Spacing and At Least Eight Transistors - A restricted layout region includes a diffusion level layout including diffusion region layout shapes that define at least one p-type diffusion region and at least one n-type diffusion region separated by a central inactive region. A gate electrode level layout is defined above the substrate portion to include linear-shaped layout features placed to extend in only a first parallel direction. Adjacent linear-shaped layout features that share a common line of extent in the first parallel direction are separated from each other by an end-to-end spacing that is substantially equal across the gate electrode level layout and that is minimized to an extent allowed by a semiconductor device manufacturing capability. A total number of PMOS and NMOS transistor devices in the restricted layout region is greater than or equal to eight. The restricted layout region corresponds to an entire gate electrode level of a cell layout. | 01-21-2010 |
20100012986 | Cell of Semiconductor Device Having Gate Electrode Conductive Structures Formed from Rectangular Shaped Gate Electrode Layout Features and Equal Number of PMOS and NMOS Transistors - A cell of a semiconductor device includes a substrate portion formed to include a plurality of diffusion regions, including at least one p-type diffusion region and at least one n-type diffusion region separated from each other by one or more non-active regions. The cell includes a gate electrode level including a number of conductive features defined to extend in only a first parallel direction. Each of the conductive features within the gate electrode level is fabricated from a respective originating rectangular-shaped layout feature. Some of the conductive features form respective PMOS and/or NMOS transistor devices. A number of the PMOS transistor devices is equal to a number of the NMOS transistor devices in the gate electrode level of the cell. The cell also includes a number of interconnect levels formed above the gate electrode level. | 01-21-2010 |
20100012985 | Semiconductor Device Portion Having Sub-193 Nanometers -Sized Gate Electrode Conductive Structures Formed from Linear Shaped Gate Electrode Layout Features Defined with Minimum End-to-End Spacing and Having At Least Eight Transistors - A semiconductor device includes a substrate portion having a plurality of diffusion regions defined therein. A gate electrode level region is formed above the substrate portion to include conductive features defined to extend in only a first parallel direction. Adjacent ones of the conductive features that share a common line of extent are fabricated from respective originating layout features separated from each other by an end-to-end spacing of substantially equal and minimum size across the gate electrode level region. A width of the conductive features within a 5 wavelength photolithographic interaction radius is less than a 193 nanometer wavelength of light used in a photolithography process for their fabrication. Some conductive features extend over the plurality of diffusion regions to form PMOS or NMOS transistor devices. A total number of the PMOS and NMOS transistor devices in the gate electrode level region is greater than or equal to eight. | 01-21-2010 |
20100012984 | Semiconductor Device Portion Having Sub-Wavelength-Sized Gate Electrode Conductive Structures Formed from Linear Shaped Gate Electrode Layout Features Defined with Minimum End-to-End Spacing and Having Equal Number of PMOS and NMOS Transistors - A semiconductor device includes a substrate portion having a plurality of diffusion regions defined therein. A gate electrode level region is formed above the substrate portion to include conductive features defined to extend in only a first parallel direction. Adjacent ones of the conductive features that share a common line of extent in the first parallel direction are fabricated from respective originating layout features that are separated from each other by an end-to-end spacing having a substantially equal and minimum size across the gate electrode level region. A width of the conductive features is less than a wavelength of light used in a photolithography process for their fabrication. Some of the conductive features extend over the plurality of diffusion regions to form PMOS or NMOS transistor devices. A number of the PMOS transistor devices is equal to a number of the NMOS transistor devices in the gate electrode level region. | 01-21-2010 |
20100012983 | Semiconductor Device Portion Having Gate Electrode Conductive Structures Formed from Linear Shaped Gate Electrode Layout Features Defined with Minimum End-to-End Spacing and Having Equal Number of PMOS and NMOS Transistors - A semiconductor device includes a substrate portion having a plurality of diffusion regions defined therein. The semiconductor device includes a gate electrode level region including a number of conductive features defined to extend in only a first parallel direction. Adjacent ones of the number of conductive features that share a common line of extent in the first parallel direction are fabricated from respective originating layout features that are separated from each other by an end-to-end spacing having a size that is substantially equal across the gate electrode level region and is minimized to an extent allowed by a semiconductor device manufacturing capability. Some of the conductive features within the gate electrode level region extend over the plurality of diffusion regions to form PMOS or NMOS transistor devices. A number of the PMOS transistor devices is equal to a number of the NMOS transistor devices in the gate electrode level region. | 01-21-2010 |
20100012982 | Semiconductor Device Portion Having Sub-Wavelength-Sized Gate Electrode Conductive Structures Formed from Linear Shaped Gate Electrode Layout Features Defined Along At Least Four Gate Electrode Tracks with Minimum End-to-End Spacing and Having Corresponding Non-Symmetric Diffusion Regions - A semiconductor device includes a substrate portion having a plurality of diffusion regions defined therein in a non-symmetrical manner relative to a virtual line defined to bisect the substrate portion. The semiconductor device includes a gate electrode level region including a number of conductive features defined to extend in only a first parallel direction. Adjacent ones of the conductive features that share a common line of extent in the first parallel direction are fabricated from respective originating layout features separated by an end-to-end spacing having a size that is substantially equal across the gate electrode level region and is minimized to an extent allowed by a semiconductor device manufacturing capability. Conductive features are defined along at least four different virtual lines of extent in the first parallel direction. A width of the conductive features is less than a wavelength of light used in a photolithography process for their fabrication. | 01-21-2010 |
20100012981 | Semiconductor Device Portion Having Gate Electrode Conductive Structures Formed from Linear Shaped Gate Electrode Layout Features Defined Along At Least Four Gate Electrode Tracks with Minimum End-to-End Spacing and Having Corresponding Non-Symmetric Diffusion Regions - A semiconductor device includes a substrate portion having a plurality of diffusion regions defined therein in a non-symmetrical manner relative to a virtual line defined to bisect the substrate portion. The semiconductor device includes a gate electrode level region including a number of conductive features defined to extend in only a first parallel direction. Adjacent ones of the number of conductive features that share a common line of extent in the first parallel direction are fabricated from respective originating layout features that are separated from each other by an end-to-end spacing having a size that is substantially equal across the gate electrode level region and is minimized to an extent allowed by a semiconductor device manufacturing capability. The gate electrode level region includes conductive features defined along at least four different virtual lines of extent in the first parallel direction. | 01-21-2010 |
20100011333 | Semiconductor Device Layout Having Restricted Layout Region Including Linear Shaped Gate Electrode Layout Features Defined with Minimum End-to-End Spacing and At Least Eight Transistors - A restricted layout region includes a diffusion level layout including a number of diffusion region layout shapes to be formed within a substrate portion of a semiconductor device. The diffusion region layout shapes define at least one p-type diffusion region and at least one n-type diffusion region. A gate electrode level layout is defined above the substrate portion to include linear-shaped layout features placed to extend in only a first parallel direction. Adjacent linear-shaped layout features that share a common line of extent in the first parallel direction are separated from each other by an end-to-end spacing that is substantially equal across the gate electrode level layout and that is minimized to an extent allowed by a semiconductor device manufacturing capability. A total number of the PMOS transistor devices and the NMOS transistor devices in the restricted layout region of the semiconductor device is greater than or equal to eight. | 01-14-2010 |
20100011332 | Semiconductor Device Layout Having Restricted Layout Region Including Linear Shaped Gate Electrode Layout Features Defined with Minimum End-to-End Spacing and Equal Number of PMOS and NMOS Transistors - A restricted layout region includes a diffusion level layout that includes a number of diffusion region layout shapes to be formed within a portion of a substrate of a semiconductor device. The diffusion region layout shapes define at least one p-type diffusion region and at least one n-type diffusion region. A gate electrode level layout is defined above the portion of the substrate to include linear-shaped layout features placed to extend in only a first parallel direction. Adjacent linear-shaped layout features that share a common line of extent in the first parallel direction are separated from each other by an end-to-end spacing that is substantially equal across the gate electrode level layout and that is minimized to an extent allowed by a semiconductor device manufacturing capability. A number of PMOS transistor devices is equal to a number of NMOS transistor devices in the restricted layout region. | 01-14-2010 |
20100011331 | Semiconductor Device Layout Including Cell Layout Having Restricted Gate Electrode Level Layout with Linear Shaped Gate Electrode Layout Features Defined Along At Least Four Gate Electrode Tracks with Minimum End-to-End Spacing with Corresponding Non-Symmetric Diffusion Regions - A restricted layout region includes a diffusion level layout including p-type and n-type diffusion region layout shapes separated by a central inactive region. The diffusion region layout shapes are defined in a non-symmetrical manner relative to a centerline defined to bisect the diffusion level layout. A gate electrode level layout is defined to include linear-shaped layout features placed to extend in only a first parallel direction. Adjacent linear-shaped layout features that share a common line of extent in the first parallel direction are separated by an end-to-end spacing that is substantially equal across the gate electrode level layout and that is minimized to an extent allowed by a semiconductor device manufacturing capability. The gate electrode level layout includes linear-shaped layout features defined along at least four different lines of extent in the first parallel direction. The restricted layout region corresponds to an entire gate electrode level of a cell layout. | 01-14-2010 |
20100011330 | Semiconductor Device Layout Having Restricted Layout Region Including Linear Shaped Gate Electrode Layout Features Defined Along At Least Four Gate Electrode Tracks with Minimum End-to-End Spacing with Corresponding Non-Symmetric Diffusion Regions - A restricted layout region in a layout of a semiconductor device is disclosed to include a diffusion level layout including a plurality of diffusion region layout shapes. The plurality of diffusion region layout shapes are defined in a non-symmetrical manner relative to a centerline defined to bisect the diffusion level layout. A gate electrode level layout is defined to include linear-shaped layout features placed to extend in only a first parallel direction. Adjacent linear-shaped layout features that share a common line of extent in the first parallel direction are separated from each other by an end-to-end spacing that is substantially equal across the gate electrode level layout and that is minimized to an extent allowed by a semiconductor device manufacturing capability. The gate electrode level layout includes linear-shaped layout features defined along at least four different lines of extent in the first parallel direction. | 01-14-2010 |
20100011329 | Semiconductor Device Layout Including Cell Layout Having Restricted Gate Electrode Level Layout with Rectangular Shaped Gate Electrode Layout Features and Equal Number of PMOS and NMOS Transistors - A restricted layout region includes a diffusion level layout that includes a number of diffusion region layout shapes to be formed within a portion of a substrate of a semiconductor device. The diffusion region layout shapes define at least one p-type diffusion region and at least one n-type diffusion region. The restricted layout region includes a gate electrode level layout defined to include rectangular-shaped layout features placed to extend in only a first parallel direction. Some of the rectangular-shaped layout features form gate electrodes of respective PMOS transistor devices, and some of the rectangular-shaped layout features form gate electrodes of respective NMOS transistor devices. A number of the PMOS transistor devices is equal to a number of the NMOS transistor devices in the restricted layout region of the semiconductor device. Additionally, the restricted layout region corresponds to an entire gate electrode level of a cell layout. | 01-14-2010 |
20100011328 | Semiconductor Device Layout Including Cell Layout Having Restricted Gate Electrode Level Layout with Linear Shaped Gate Electrode Layout Features Defined with Minimum End-to-End Spacing and Equal Number of PMOS and NMOS Transistors - A restricted layout region includes a diffusion level layout including a number of diffusion region layout shapes that define at least one p-type diffusion region and at least one n-type diffusion region separated by a central inactive region. A gate electrode level layout is defined above the diffusion level layout to include linear-shaped layout features placed to extend in only a first parallel direction. Adjacent linear-shaped layout features that share a common line of extent in the first parallel direction are separated from each other by an end-to-end spacing that is substantially equal across the gate electrode level layout and that is minimized to an extent allowed by a semiconductor device manufacturing capability. A number of PMOS transistor devices is equal to a number of NMOS transistor devices in the restricted layout region. The restricted layout region corresponds to an entire gate electrode level of a cell layout. | 01-14-2010 |
20100011327 | Semiconductor Device Layout Having Restricted Layout Region Including Rectangular Shaped Gate Electrode Layout Features and At Least Eight Transistors - A restricted layout region includes a diffusion level layout including a number of diffusion region layout shapes to be formed within a portion of a substrate of a semiconductor device. The diffusion region layout shapes define at least one p-type diffusion region and at least one n-type diffusion region. The restricted layout region includes a gate electrode level layout defined to pattern conductive features within a gate electrode level above the portion of the substrate. The gate electrode level layout includes rectangular-shaped layout features placed to extend in only a first parallel direction. Some rectangular-shaped layout features form gate electrodes of respective PMOS transistor devices, and some rectangular-shaped layout features form gate electrodes of respective NMOS transistor devices. A total number of the PMOS transistor devices and the NMOS transistor devices in the restricted layout region of the semiconductor device is greater than or equal to eight. | 01-14-2010 |
20100006986 | Semiconductor Device Layout Including Cell Layout Having Restricted Gate Electrode Level Layout with Rectangular Shaped Gate Electrode Layout Features Defined Along At Least Four Gate Electrode Tracks with Corresponding Non-Symmetric Diffusion Regions - A restricted layout region is defined to include a diffusion level layout that includes a plurality of diffusion region layout shapes to be formed within a portion of a substrate of a semiconductor device. The plurality of diffusion region layout shapes are defined in a non-symmetrical manner relative to a centerline defined to bisect the diffusion level layout of the restricted layout region. The plurality of diffusion region layout shapes include a p-type diffusion region layout shape and an n-type diffusion region layout shape separated by a central inactive region. A gate electrode level layout is defined include a number of rectangular-shaped layout features placed to extend in only a first parallel direction, and defined along at least four different lines of extent in the first parallel direction. The restricted layout region corresponds to an entire gate electrode level of a cell layout. | 01-14-2010 |
20100006951 | Semiconductor Device Portion Having Sub-193 Nanometers -Sized Gate Electrode Conductive Structures Formed from Rectangular Shaped Gate Electrode Layout Features and Having Equal Number of PMOS and NMOS Transistors - A semiconductor device is disclosed as having a substrate portion that includes a plurality of diffusion regions that include at least one p-type diffusion region and at least one n-type diffusion region. A gate electrode level region is formed above the substrate portion to include a number of conductive features defined to extend in only a first parallel direction. Each of the conductive features within the gate electrode level region is fabricated from a respective originating rectangular-shaped layout feature. Within a five wavelength photolithographic interaction radius within the gate electrode level region, a width size of the conductive features is less than 193 nanometers, which is the wavelength of light used in a photolithography process to fabricate the conductive features. The conductive features within the gate electrode level region form an equal number of PMOS and NMOS transistor devices. | 01-14-2010 |
20100006950 | Semiconductor Device Portion Having Gate Electrode Conductive Structures Formed from Rectangular Shaped Gate Electrode Layout Features and Having At Least Eight Transistors - A semiconductor device includes a substrate portion that includes a plurality of diffusion regions that include at least one p-type diffusion region and at least one n-type diffusion region. A gate electrode level region is formed above the substrate portion to include a number of conductive features defined to extend in only a first parallel direction. Each of the conductive features within the gate electrode level region is fabricated from a respective originating rectangular-shaped layout feature. Some of the conductive features within the gate electrode level region extend over the p-type diffusion regions to form respective PMOS transistor devices. Also, some of the conductive features within the gate electrode level region extend over the n-type diffusion regions to form respective NMOS transistor devices. A total number of the PMOS transistor devices and the NMOS transistor devices in the gate electrode level region is greater than or equal to eight. | 01-14-2010 |
20100006948 | Semiconductor Device Portion Having Sub-193 Nanometers -Sized Gate Electrode Conductive Structures Formed from Rectangular Shaped Gate Electrode Layout Features and Having At Least Eight Transistors - A semiconductor device includes a substrate portion that includes a plurality of diffusion regions that include at least one p-type diffusion region and at least one n-type diffusion region. A gate electrode level region is formed above the substrate portion to include a number of conductive features defined to extend in only a first parallel direction. Each of the conductive features within the gate electrode level region is fabricated from a respective originating rectangular-shaped layout feature. Within a five wavelength photolithographic interaction radius within the gate electrode level region, a width size of the conductive features is less than 193 nanometers, which is the wavelength of light used in a photolithography process to fabricate the conductive features. A total number of the PMOS transistor devices and the NMOS transistor devices in the gate electrode level region is greater than or equal to eight. | 01-14-2010 |
20100006947 | Semiconductor Device Portion Having Sub-Wavelength-Sized Gate Electrode Conductive Structures Formed from Rectangular Shaped Gate Electrode Layout Features and Having At Least Eight Transistors - A semiconductor device includes a substrate portion that includes a plurality of diffusion regions that include at least one p-type diffusion region and at least one n-type diffusion region. A gate electrode level region is formed above the substrate portion to include a number of conductive features defined to extend in only a first parallel direction. Each of the conductive features within the gate electrode level region is fabricated from a respective originating rectangular-shaped layout feature. Each of the conductive features within the gate electrode level region has a width less than a wavelength of light used in a photolithography process to fabricate the conductive features. Conductive features within the gate electrode level region form respective PMOS transistor devices and respective NMOS transistor devices. A total number of the PMOS transistor devices and the NMOS transistor devices in the gate electrode level region is greater than or equal to eight. | 01-14-2010 |
20100006903 | Semiconductor Device Portion Having Sub-193 Nanometers-Sized Gate Electrode Conductive Structures Formed from Rectangular Shaped Gate Electrode Layout Features Defined Along At Least Four Gate Electrode Tracks and Having Corresponding Non-Symmetric Diffusion Regions - A semiconductor device includes a substrate portion having a plurality of diffusion regions defined in a non-symmetrical manner relative to a virtual line defined to bisect the substrate portion. A gate electrode level region is formed above the substrate portion to include a number of conductive features defined to extend in only a first parallel direction and fabricated from a respective originating rectangular-shaped layout feature. The gate electrode level region includes conductive features defined along at least four different virtual lines of extent in the first parallel direction. A width size of the conductive features within the gate electrode level region is measured perpendicular to the first parallel direction. Within a five wavelength photolithographic interaction radius within the gate electrode level region, the width size of the conductive features is less than 193 nanometers, which is the wavelength of light used in a photolithography process to fabricate the conductive features. | 01-14-2010 |
20100006902 | Semiconductor Device Portion Having Sub-Wavelength-Sized Gate Electrode Conductive Structures Formed from Rectangular Shaped Gate Electrode Layout Features Defined Along At Least Four Gate Electrode Tracks and Having Corresponding Non-Symmetric Diffusion Regions - A substrate portion of a semiconductor device is formed to include a plurality of diffusion regions that are defined in a non-symmetrical manner relative to a virtual line defined to bisect the substrate portion. A gate electrode level region is formed above the substrate portion to include a number of conductive features defined to extend in only a first parallel direction. Each of the number of conductive features within the gate electrode level region is fabricated from a respective originating rectangular-shaped layout feature. The conductive features within the gate electrode level region are defined along at least four different virtual lines of extent in the first parallel direction. A width size of the conductive features within the gate electrode level region is measured perpendicular to the first parallel direction and is less than a wavelength of light used in a photolithography process to fabricate the conductive features. | 01-14-2010 |
20100006901 | Semiconductor Device Portion Having Gate Electrode Conductive Structures Formed from Rectangular Shaped Gate Electrode Layout Features Defined Along At Least Four Gate Electrode Tracks and Having Corresponding Non-Symmetric Diffusion Regions - A semiconductor device includes a substrate portion having a plurality of diffusion regions defined therein. The plurality of diffusion regions are separated from each other by one or more non-active regions of the substrate portion. The plurality of diffusion regions are defined in a non-symmetrical manner relative to a virtual line defined to bisect the substrate portion. The semiconductor device includes a gate electrode level region formed above the substrate portion to include a number of conductive features defined to extend in only a first parallel direction. Each of the number of conductive features within the gate electrode level region is fabricated from a respective originating rectangular-shaped layout feature. The number of conductive features within the gate electrode level region includes conductive features defined along at least four different virtual lines of extent in the first parallel direction across the gate electrode level region. | 01-14-2010 |
20100006900 | Semiconductor Device Portion Having Sub-Wavelength-Sized Gate Electrode Conductive Structures Formed from Rectangular Shaped Gate Electrode Layout Features and Having Equal Number of PMOS and NMOS Transistors - A semiconductor device is disclosed as having a substrate portion that includes a plurality of diffusion regions that include at least one p-type diffusion region and at least one n-type diffusion region. A gate electrode level region is formed above the substrate portion to include a number of conductive features defined to extend in only a first parallel direction. Each of the conductive features within the gate electrode level region is fabricated from a respective originating rectangular-shaped layout feature. Each of the conductive features within the gate electrode level region has a width less than a wavelength of light used in a photolithography process to fabricate the conductive features. Conductive features within the gate electrode level region form respective PMOS transistor devices and respective NMOS transistor devices. A number of the PMOS transistor devices is equal to a number of the NMOS transistor devices in the gate electrode level region. | 01-14-2010 |
20100006899 | Semiconductor Device Portion Having Gate Electrode Conductive Structures Formed from Rectangular Shaped Gate Electrode Layout Features and Having Equal Number of PMOS and NMOS Transistors - A semiconductor device is disclosed as having a substrate portion that includes a plurality of diffusion regions that include at least one p-type diffusion region and at least one n-type diffusion region. A gate electrode level region is formed above the substrate portion to include a number of conductive features defined to extend in only a first parallel direction. Each of the conductive features within the gate electrode level region is fabricated from a respective originating rectangular-shaped layout feature. Some of the conductive features within the gate electrode level region extend over the p-type diffusion regions to form respective PMOS transistor devices. Also, some of the conductive features within the gate electrode level region extend over the n-type diffusion regions to form respective NMOS transistor devices. A number of the PMOS transistor devices is equal to a number of the NMOS transistor devices in the gate electrode level region. | 01-14-2010 |
20100006898 | Semiconductor Device Layout Including Cell Layout Having Restricted Gate Electrode Level Layout with Rectangular Shaped Gate Electrode Layout Features and At Least Eight Transistors - A restricted layout region includes a diffusion level layout that includes a number of diffusion region layout shapes to be formed within a portion of a substrate of a semiconductor device. The diffusion region layout shapes define at least one p-type diffusion region and at least one n-type diffusion region. The restricted layout region includes a gate electrode level layout defined to include rectangular-shaped layout features placed to extend in only a first parallel direction. Some of the rectangular-shaped layout features form gate electrodes of respective PMOS transistor devices, and some of the rectangular-shaped layout features form gate electrodes of respective NMOS transistor devices. A total number of the PMOS transistor devices and the NMOS transistor devices in the restricted layout region of the semiconductor device is greater than or equal to eight. Additionally, the restricted layout region corresponds to an entire gate electrode level of a cell layout. | 01-14-2010 |
20100006897 | Semiconductor Device Layout Having Restricted Layout Region Including Rectangular Shaped Gate Electrode Layout Features and Equal Number of PMOS and NMOS Transistors - A restricted layout region includes a diffusion level layout that includes a number of diffusion region layout shapes to be formed within a portion of a substrate of a semiconductor device. The diffusion region layout shapes define at least one p-type diffusion region and at least one n-type diffusion region. The restricted layout region includes a gate electrode level layout defined to pattern conductive features within a gate electrode level above the portion of the substrate. The gate electrode level layout includes rectangular-shaped layout features placed to extend in only a first parallel direction. Some of the rectangular-shaped layout features form gate electrodes of respective PMOS transistor devices, and some of the rectangular-shaped layout features form gate electrodes of respective NMOS transistor devices. A number of the PMOS transistor devices is equal to a number of the NMOS transistor devices in the restricted layout region of the semiconductor device. | 01-14-2010 |
20100001321 | Semiconductor Device Layout Having Restricted Layout Region Including Rectangular Shaped Gate Electrode Layout Features Defined Along At Least Four Gate Electrode Tracks with Corresponding Non-Symmetric Diffusion Regions - A restricted layout region in a layout of a semiconductor device is disclosed to include a diffusion level layout including a plurality of diffusion region layout shapes. The plurality of diffusion region layout shapes are defined in a non-symmetrical manner relative to a centerline defined to bisect the diffusion level layout. A gate electrode level layout is defined to include a number of linear-shaped layout features placed to extend in only a first parallel direction. Each of the number of the linear-shaped layout features within the gate electrode level layout of the restricted layout region is rectangular-shaped. The gate electrode level layout includes linear-shaped layout features defined along at least four different lines of extent in the first parallel direction. Each of a number of interconnect level layouts is defined to pattern conductive features within corresponding interconnect levels above the gate electrode level. | 01-07-2010 |
20090294981 | Methods for Defining and Using Co-Optimized Nanopatterns for Integrated Circuit Design and Apparatus Implementing Same - A set of layout nanopatterns is defined. Each layout nanopattern is defined by relative placements of a particular type of layout feature within a lithographic window of influence. A design space is defined as a set of layout parameters and corresponding value ranges that affect manufacturability of a layout. Layouts are created for the set of layout nanopatterns such that the created layouts cover the design space. The layouts for the set of layout nanopatterns are then optimized for manufacturability. A point in the design space is selected where the set of layout nanopatterns are co-optimized for manufacturability. A circuit layout is created based on the selected point in design space using the corresponding set of co-optimized layout nanopatterns. The optimized layouts for the set of layout nanopatterns and the associated circuit layout can be recorded in a digital format on a computer readable storage medium. | 12-03-2009 |
20090271753 | Methods for Cell Phasing and Placement in Dynamic Array Architecture and Implementation of the Same - 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. | 10-29-2009 |
20090152734 | Super-Self-Aligned Contacts and Method for Making the Same - A number of first hard mask portions are formed on a dielectric layer to vertically shadow a respective one of a number of underlying gate structures. A number of second hard mask filaments are formed adjacent to each side surface of each first hard mask portion. A width of each second hard mask filament is set to define an active area contact-to-gate structure spacing. A first passage is etched between facing exposed side surfaces of a given pair of neighboring second hard mask filaments and through a depth of the semiconductor wafer to an active area. A second passage is etched through a given first hard mask portion and through a depth of the semiconductor wafer to a top surface of the underlying gate structure. An electrically conductive material is deposited within both the first and second passages to respectively form an active area contact and a gate contact. | 06-18-2009 |
20090127636 | Diffusion Variability Control and Transistor Device Sizing Using Threshold Voltage Implant - A transistor is defined to include a substrate portion and a diffusion region defined in the substrate portion so as to provide an operable transistor threshold voltage. An implant region is defined within a portion of the diffusion region so as to transform the operable transistor threshold voltage of the diffusion region portion into an inoperably high transistor threshold voltage. A gate electrode is defined to extend over both the diffusion region and the implant region. A first portion of the gate electrode defined over the diffusion region forms a first transistor segment having the operable transistor threshold voltage. A second portion of the gate electrode defined over the implant region forms a second transistor segment having the inoperably high transistor threshold voltage. Therefore, a boundary of the implant region defines a boundary of the operable first transistor segment. | 05-21-2009 |
20090108360 | METHODS, STRUCTURES AND DESIGNS FOR SELF-ALIGNING LOCAL INTERCONNECTS USED IN INTEGRATED CIRCUITS - Methods, structures and designs for self-aligned local interconnects are provided. The method includes designing diffusion regions to be in a substrate. Some of a plurality of gates are designed to be active gates and some of the plurality of gates are designed to be formed over isolation regions. The method includes designing the plurality of gates in a regular and repeating alignment along a same direction, and each of the plurality of gates are designed to have dielectric spacers. The method also includes designing a local interconnect layer between or adjacent to the plurality of gates. The local interconnect layer is conductive and disposed over the substrate to allow electrical contact and interconnection with or to some of the diffusion regions of the active gates. The local interconnect layer is self-aligned by the dielectric spacers of the plurality of gates. | 04-30-2009 |
20090100396 | Methods and Systems for Process Compensation Technique Acceleration - Selected cells in a semiconductor chip layout are replaced with corresponding PCT pre-processed cells. Each PCT pre-processed cell represents a particular selected cell having been previously subjected to a cell-level-PCT-processing operation so as to include PCT-based cell layout adjustments. Following replacement of the selected cells in the semiconductor chip layout with corresponding PCT pre-processed cells, a chip-wide PCT processing operation is performed on the semiconductor chip layout for a given chip level. The presence of the PCT pre-processed cells in the semiconductor chip layout serves to accelerate the chip-wide PCT processing of the semiconductor chip layout. The chip-wide PCT processed semiconductor layout for the given chip level is recorded on a persistent storage medium. | 04-16-2009 |
20090037864 | Methods for Designing Semiconductor Device with Dynamic Array Section - A method is provided for designing a semiconductor chip having one or more functionally interfaced dynamic array sections. A virtual grate is laid out for conductive features used to define a gate electrode level of a dynamic array section. The virtual grate is defined by a framework of parallel lines defined at a substantially constant pitch. One or more conductive features are arranged along every line of the virtual grate. For each line of the virtual grate, a gap is defined between proximate ends of each pair of adjacent conductive features which are arranged along a common line of the virtual grate. Each gap is defined to maintain a substantially consistent separation between proximate ends of conductive features. Each conductive feature is defined to be devoid of a substantial change in direction, such that the conductive features remain substantially aligned to the framework of parallel lines of the virtual grate. | 02-05-2009 |
20090032967 | Semiconductor Device with Dynamic Array Section - A semiconductor chip is provided to include one or more distinct but functionally interfaced dynamic array sections. Each dynamic array section follows a dynamic array architecture that requires conductive features to be linearly defined along a virtual grate in each of a plurality of levels of the semiconductor chip. Each virtual grate is perpendicular to another virtual grate that is either a level above or a level below. Each virtual grate is defined by a framework of parallel lines spaced at a constant pitch. Some of the lines in the virtual grate are occupied by multiple conductive features. A substantially uniform gap can be maintained between proximate ends of adjacent conductive features that occupy a common line in the virtual grate. The substantially uniform gap between the proximate ends of adjacent conductive features can be maintained within each line in the virtual grate that is occupied by multiple conductive features. | 02-05-2009 |
20090032898 | Methods for Defining Dynamic Array Section with Manufacturing Assurance Halo and Apparatus Implementing the Same - A method is disclosed for defining a dynamic array section to be manufactured on a semiconductor chip. The method includes defining a peripheral boundary of the dynamic array section. The method also includes defining a manufacturing assurance halo outside the boundary of the dynamic array section. The method further includes controlling chip layout features within the manufacturing assurance halo to ensure that manufacturing of conductive features inside the boundary of the dynamic array section is not adversely affected by chip layout features within the manufacturing assurance halo. | 02-05-2009 |
20090014811 | Dynamic Array Architecture - A semiconductor device includes a substrate portion and a number of diffusion regions defined within the substrate portion. The diffusion regions are separated from each other by a non-active region of the substrate portion. The semiconductor device includes a number of linear gate electrode segments defined to extend over the substrate portion in a single common direction. In one embodiment, the diffusion regions are defined in a non-symmetrical manner relative to a centerline of the substrate portion. In another embodiment, the substrate portion corresponds to a region of the semiconductor device in which first and second cells are defined, and respectively include diffusion shapes of different size. In another embodiment, one or more of the diffusion regions is defined to have a periphery formed by more than four orthogonally related sides. | 01-15-2009 |
20080222587 | Integrated Circuit Cell Library for Multiple Patterning - A method is disclosed for defining a multiple patterned cell layout for use in an integrated circuit design. A layout is defined for a level of a cell in accordance with a dynamic array architecture so as to include a number of layout features. The number of layout features are linear-shaped and commonly oriented. The layout is split into a number of sub-layouts for the level of the cell. Each of the number of layout features in the layout is allocated to any one of the number of sub-layouts. Also, the layout is split such that each sub-layout is independently fabricatable. The sub-layouts for the level of the cell are stored on a computer readable medium. | 09-11-2008 |