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 describing device circuit features and dummy features. The dummy features have first target patterns. Mask pattern data is generated for the dummy features, wherein one or more of the dummy features have second target patterns that are different from the first target patterns. The mask pattern data is corrected for proximity effects.

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: The present disclosure is directed to a method for preparing photomask patterns for a lithography process that employs a plurality of photomasks. The method comprises receiving data describing a drawn pattern. An edge of the drawn pattern is identified that can be defined using a first photomask and a second photomask, and the first photomask is chosen for patterning the edge. Patterns are formed for the first photomask and the second photomask, wherein the first photomask pattern is formed to pattern the edge, and the second photomask pattern is formed to have a wing adjacent to the edge for protecting the edge from double patterning. A process for patterning an integrated circuit device is also disclosed.

Abstract: In accordance with the invention, there is a method of designing a lithography mask. The method can comprise generating initial phase photomask data and initial trim photomask data from a first set of data from a first drawn layer and/or layout and a second set of data from a second drawn layer, combining the initial phase photomask data with the first set of data to form a combined layer, inspecting for gaps in the combined layer, and processing the gaps in the combined layer.

Abstract: The present application is directed a method for preparing a mask pattern database for proximity correction. The method comprises receiving data from a design database. Mask pattern data describing a first photomask pattern for forming first device features is generated. The first photomask pattern is to be corrected for proximity effects in a proximity correction process. A second set of data is accessed comprising information about second device features, wherein at least a portion of the second set of data is relevant to the proximity correction process. The second set of data is manipulated so as to improve the proximity correction process, as compared with the same proximity correction process in which the second set of data was included in the mask pattern database without being manipulated. At least a portion of the mask pattern data and at least a portion of the manipulated second set of data is included in the mask pattern database.

Abstract: Generating two-tone phase shift photomasks that satisfy lithography and photomask constraints is accomplished using an iterative algorithm which successively identifies violations of the constraints, relaxes or removes constraints, and alters layout polygons associated with the violations, to produce a phase assignment configuration which meets the lithography and photomask constraints or identifies a subset of the layout polygons for which no viable solution can be found.

Abstract: The present application is directed a method for preparing a mask pattern database for proximity correction. The method comprises receiving data from a design database. Mask pattern data describing a first photomask pattern for forming first device features is generated. The first photomask pattern is to be corrected for proximity effects in a proximity correction process. A second set of data is accessed comprising information about second device features, wherein at least a portion of the second set of data is relevant to the proximity correction process. The second set of data is manipulated so as to improve the proximity correction process, as compared with the same proximity correction process in which the second set of data was included in the mask pattern database without being manipulated. At least a portion of the mask pattern data and at least a portion of the manipulated second set of data is included in the mask pattern database.

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 describing device circuit features and dummy features. The dummy features have first target patterns. Mask pattern data is generated for the dummy features, wherein one or more of the dummy features have second target patterns that are different from the first target patterns. The mask pattern data is corrected for proximity effects.

Abstract: In accordance with the invention, there is a method of designing a lithography mask. The method can comprise generating initial phase photomask data and initial trim photomask data from a first set of data from a first drawn layer and/or layout and a second set of data from a second drawn layer, combining the initial phase photomask data with the first set of data to form a combined layer, inspecting for gaps in the combined layer, and processing the gaps in the combined layer.

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: The present disclosure is directed a method for, preparing a photomask pattern. The method comprises receiving drawn pattern data from a design database. The drawn pattern data describes two or more adjacent feature ends that are positioned at different locations along a y-axis. A photomask pattern is formed for patterning the feature ends, wherein the photomask pattern will result in the feature ends being positioned at the same location along the y-axis.

Abstract: The present disclosure is directed to a method for preparing photomask patterns for a lithography process that employs a plurality of photomasks. The method comprises receiving data describing a drawn pattern. An edge of the drawn pattern is identified that can be defined using a first photomask and a second photomask, and the first photomask is chosen for patterning the edge. Patterns are formed for the first photomask and the second photomask, wherein the first photomask pattern is formed to pattern the edge, and the second photomask pattern is formed to have a wing adjacent to the edge for protecting the edge from double patterning. A process for patterning an integrated circuit device is also disclosed.

Abstract: The present application is directed to methods of forming a phase pattern for an integrated circuit feature described in a design database as having a first target dimension. In one embodiment, the method comprises determining whether forming a phase pattern for the integrated circuit feature described in the design database will result in one or more phase blocks of the same phase type being positioned in relative proximity so as to result in a low contrast condition, selecting a second target dimension that will avoid the low contrast condition if the low contrast condition will result, and forming the phase pattern for an integrated circuit feature having the second target dimension. Systems for forming phase patterns and photomasks comprising the phase patterns of the present application are also disclosed.

Abstract: Correcting a mask pattern includes accessing a record associated with an uncorrected pattern that comprises segments. The record associates each segment with a correction grid of a number of correction grids, where each correction grid comprises points. A segment is selected, and an optimal correction for the segment is determined. A correction grid associated with the segment is determined. The segment is snapped to a subset of points of the associated correction grid, where the subset of points is proximate to the optimal correction, to form a corrected pattern of a mask pattern.

Abstract: Correcting a mask pattern includes accessing a record associated with an uncorrected pattern that comprises segments. The record associates each segment with a correction grid of a number of correction grids, where each correction grid comprises points. A segment is selected, and an optimal correction for the segment is determined. A correction grid associated with the segment is determined. The segment is snapped to a subset of points of the associated correction grid, where the subset of points is proximate to the optimal correction, to form a corrected pattern of a mask pattern.

Abstract: The number of good IC (Integrated Circuit) chips per wafer or time to print a wafer is optimized by examining a number of prospective chip-to-wafer offsets, and, for each offset, a number of prospective arrangements of reticle exposures (shot maps). Integrating such a shot map optimization sub-system with a reticle layout (frame generation) sub-system permits creation of an optimal shot map for an IC chip of known size. These two sub-systems can also be used iteratively to explore a range of possible chip sizes, presenting the results in a simple graphical form. The instant invention integrates shot map optimization, frame generation and chip size optimization/visualization into a single system, providing the chip designer with insight into the impact of chip size on manufacturability.