Abstract: A process of generating design rules, OPC rules and optimizing illumination source models for an integrated circuit layout, to form short lines, terminated lines and crossovers between adjacent parallel route tracks, may include the steps of generating a set of template structures which use a set of characteristic design rules, and performing a plurality of source mask optimization (SMO) operations on the set of template structures with different values for the design rules in each SMO operation. In a first embodiment, the SMO operations are run using a predetermined set of values for each of the design rules, spanning a desired range of design rule values. In a second embodiment, the SMO operations are performed in a conditional iterative process in which values of the design rules are adjusted after each iteration based on results of the iteration.

Abstract: Mask or reticle methods and structures having pattern feature segments formed at oblique angles to each other. When illuminated using off-axis illumination techniques, a mask or reticle according to the present teachings can result in a more accurately reproduced feature within a photosensitive layer.

Abstract: A method and apparatus for designing a lithography mask set which provides polygon features of a desired size at advanced technology nodes, for example, using live features and dummy features. A dummy feature can be formed within a confined space by specifying an allowable dummy feature length even though the feature length may result in contact between the dummy feature and the live feature. After specifying the dummy feature length, a pattern generation (PG) extract can be performed to pull back the dummy feature away from the live feature by an allowable distance. The PG exact process can result in a shorter dummy feature which has a length which is shorter than can be specified directly by design rules, but which passes rule checking.

Abstract: Exemplary embodiments provide a method for laying out an IC design and the IC design layout. The IC design layout can include one or more gate features placed on an active region including a first pitch (p1) between any two adjacent gate features. Additionally, the IC design layout can include a printable-gate-assist feature placed adjacent to at least one side of the active region, and placed parallel to and at a second pitch (p2) from one first gate feature of the one or more gate features. In various embodiments, a printable-gate-extension feature can be drawn in the design to extend a second gate feature to match a length with a longer neighboring gate feature of the one or more gate features.

Abstract: A method of forming an IC including MOS transistors includes using a gate mask to form a first active gate feature having a line width W1 over an active area and a neighboring dummy feature having a line width 0.8W1 to 1.3W1. The neighboring dummy feature has a first side adjacent to the first active gate feature, and a nearest gate level feature on a second side opposite the first side. The neighboring dummy feature defines a gate pitch based on a distance to the first active gate feature or the neighboring dummy feature maintains a gate pitch in a gate array including the first active gate feature. The spacing between the neighboring dummy feature and the nearest gate level feature (i) maintains the gate pitch or (ii) provides a SRAF enabling distance that is ?2 times the gate pitch and the gate mask includes a SRAF over the SRAF distance.

Abstract: An integrated circuit constructed according to an arrangement of logic blocks, with one or more logic blocks including transistors of a different threshold voltage than in other logic blocks. Spacing between neighboring active regions of different threshold voltages is minimized by constraining the angle of implant for the threshold adjust implant, and by constraining the thickness of the mask layer used with that implant. These constraints ensure adequate implant of dopant into the channel region while blocking the implant into channel regions not subject to the threshold adjust, while avoiding shadowing from the mask layer. Efficiency is attained by constraining the direction of implant to substantially perpendicular to the run of the gate electrodes in the implanted regions.

Abstract: A method of forming an IC includes forming a first and a second gate portion using a poly mask. The first portion includes a first active poly gate having a line width W1 over an end of a first active area framed by a first active area edge and a first adjacent active field poly feature having a line width 0.8W1 to 1.3W1 in a first field region. The first field poly feature has a horizontal portion and a first extension portion along a gate width direction extending over the first active area edge having a first minimum spacing (S1). The second gate portion includes a second active poly gate over an end of a second active area framed by a second active area edge electrically connected to a second field poly feature in a second field region having a horizontal portion and a second extension portion along a gate width direction extending over the second active area edge having a second minimum spacing (S2). A dummy field poly feature is between the second active poly gate and the second field poly feature.

Abstract: Exemplary embodiments provide a method for laying out an integrated circuit (“IC”) design and the IC design layout. In one embodiment, the IC design layout can include a first feature placed on a first intersecting point of a grid. The placed first feature can define a local grid area. The local grid area can further include a plurality of local intersecting points having an outer perimeter spaced from any outermost local intersecting point in a spacing ranging from a length of a grid side to a length of a grid diagonal of a grid unit. A second feature can either be restrictively placed on any local intersecting point of the local grid area, or be randomly placed on any location outside the outer perimeter of the local grid area.

Abstract: The present disclosure is directed a method for preparing photomask patterns. The method comprises receiving drawn pattern data for a design database. The drawn pattern data describes first device features and second device features, the second device features being associated with design specifications for providing a desired connectivity of the first device features to the second device features. At least a first plurality of the first device features have drawn patterns that will not result in sufficient coverage to effect the desired connectivity. Photomask patterns are formed for the first device features, wherein the photomask patterns for the first plurality of the first device features will result in the desired coverage. Integrated circuit devices formed using the principles of the present disclosure are also taught.

Abstract: In accordance with the invention, there are methods of making an integrated circuit, an integrated circuit device, and a computer readable medium. A method can comprise forming a first layer over a semiconductor substrate, forming a first mask layer over the semiconductor substrate, and using the first mask layer to pattern first features. The method can also include forming a second mask layer over the first features, using the second mask layer to pattern portions of the first features, removing the second mask layer, and removing the first mask layer.

Abstract: In accordance with various embodiments, semiconductor devices and methods of forming semiconductor devices having non-rectangular active regions are provided. An exemplary method includes using a first mask to form a plurality of first features over a non-rectangular shaped active region and at least one ghost feature, wherein the plurality of first features extend beyond an edge of the non-rectangular shaped active region. The method further includes using a second mask to remove a portion of the plurality of first features extending beyond the edge of the non-rectangular shaped active region and the at least one ghost feature.

Abstract: Components in integrated circuits (ICs) are fabricated as small as possible to minimize sizes of the ICs and thus reduce manufacturing costs per IC. Metal interconnect lines are formed on minimum pitches possible using available photolithographic printers. Minimum pitches possible for contacts and vias are larger than minimum pitches possible for metal interconnect lines, thus preventing dense rectilinear grid configurations for contacts and vias. The instant invention is an integrated circuit, and a method of fabricating an integrated circuit, wherein metal interconnect lines are formed on a minimum pitch possible using a photolithographic printer. Contacts and vias are arranged to provide connections to components and metal interconnect lines, as required by the integrated circuit, in configurations that are compatible with the minimum pitch for contacts and vias, including semi-dense arrays.

Abstract: In accordance with an embodiment of the invention, there is a method of designing a lithography mask. The method can comprise determining a maximum width of a shifter, wherein the maximum width corresponds to a width of a shifter for a first set of features and determining whether the shifter having the maximum width can be placed in a shifter space for a second set of features. The method can also comprise incrementally decreasing the width of the shifter to be placed into the shifter space for the second set of features when the shifter having the maximum width cannot be placed in the shifter space for a feature in the second set of features until an acceptable shifter width can be determined or until the shifter width is reduced to a predetermined minimum shifter width.

Abstract: An improved method for optimizing layer registration during lithography in the fabrication of a semiconductor device is disclosed. In one example, the method comprises optimizing contact layer registration of an SRAM device having a plurality of transistors having active and gate region features extending generally along a channel length (X) direction and a channel width (Y) direction, respectively. The method comprises aligning a contact layer to a gate layer in the channel length direction (X), using gate layer overlay marks to control the alignment of the contact layer in the channel length direction (X) of the semiconductor device. The method further includes aligning the contact layer to an active layer in the channel width direction (Y), using active layer overlay marks to control the alignment of the contact layer in the channel width direction (Y) of the semiconductor device.

Abstract: A method of patterning a plurality of polysilicon structures includes forming a polysilicon layer over a semiconductor body, and patterning the polysilicon layer to form a first polysilicon structure using a first patterning process that reduces line-edge roughness (LER). The method further includes patterning the polysilicon layer to form a second polysilicon structure using a second patterning process that is different from the first patterning process after performing the first patterning process.

Abstract: Provide is a method of making a mask layout, an integrated circuit device made by a method, a computer readable medium, and a mask for forming contact holes. The method can comprise patterning a first feature along a first axis, determining a first set of areas adjacent to the first feature, wherein each of the areas in the first set of areas is within a first angle away from the first axis, and wherein each of the areas in the first set of areas is within a first distance away from the first feature, and patterning a second feature in at least one of the first set of areas so as to form a mask layout, wherein each of the first feature and the second feature are one of a virtual feature and a real feature.

Abstract: According to various embodiments, two-print two-etch methods and devices are disclosed that can be used to form features, such as ghost features, on a substrate. The disclosed methods can be incorporated into, for example, altPSM, attPSM, and binary lithographic method for making semiconductor devices. a method of forming a semiconductor device is provided. The exemplary methods can include defining a plurality of first features and at least one ghost feature on a photosensitive layer by exposing a first mask to a light, wherein the first mask comprises a plurality of phase shift areas that change a phase of the light. A portion of a layer disposed under the photosensitive layer can be removed by etching to form the plurality of first features and the at least one ghost feature. One or more structures not requiring phase shifting can then be defined on the photosensitive layer by exposing a second mask to the light, wherein the second mask removes the at least one ghost feature.

Abstract: Exemplary embodiments provide a method for laying out an integrated circuit (“IC”) design and the IC design layout. In one embodiment, the IC design layout can include a first feature placed on a first intersecting point of a grid. The placed first feature can define a local grid area. The local grid area can further include a plurality of local intersecting points having an outer perimeter spaced from any outermost local intersecting point in a spacing ranging from a length of a grid side to a length of a grid diagonal of a grid unit. A second feature can either be restrictively placed on any local intersecting point of the local grid area, or be randomly placed on any location outside the outer perimeter of the local grid area.

Abstract: Exemplary embodiments provide a method for laying out an IC design and the IC design layout. The IC design layout can include one or more gate features placed on an active region including a first pitch (p1) between any two adjacent gate features. Additionally, the IC design layout can include a printable-gate-assist feature placed adjacent to at least one side of the active region, and placed parallel to and at a second pitch (p2) from one first gate feature of the one or more gate features. In various embodiments, a printable-gate-extension feature can be drawn in the design to extend a second gate feature to match a length with a longer neighboring gate feature of the one or more gate features.

Abstract: According to various embodiments, the present teachings include various methods for forming a semiconductor device, computer readable medium for forming a semiconductor device, mask sets for forming a semiconductor device, and a semiconductor device made according to various methods. For example, a method can comprise forming a first feature and a second feature on a substrate by exposing a first mask to a first beam, wherein the second feature is disposed adjacent to the first feature, exposing a second mask to a second beam, and removing the second feature from the substrate.