Abstract: A method for forming a mask layout is described. A plurality of phase shapes are formed on either side of a critical feature of a design layout of an intergrated circuit chip having a plurality of critical features. A plurality of transition edges are identified from the edges of each phase shape. Each transition edge is parallel to critical feature. A transition space is identified as defined by one of the group including two transition edges and one transition edge. A transition polygon is formed by closing each transition space with at least one closing edge. Each transition polygon is transformed into a printing assist feature. A mask layout is formed from the printing assist features and critical features.

Abstract: Aspects of the invention include a computer-implemented method of designing a photomask. In one embodiment, the method comprises: simulating a first photomask patterning process using a first photomask design to create simulated contours; comparing the simulated contours to a desired design; identifying regions not common to the simulated contours and the desired design; creating desired target shapes for a second photomask patterning process subsequent to the first photomask patterning process based upon the identified regions; and providing the desired target shapes for forming of a second photomask design based upon the desired target shapes.

Abstract: Aspects of the invention include a computer-implemented method of designing a photomask. In one embodiment, the method comprises: simulating a first photomask patterning process using a first photomask design to create simulated contours; comparing the simulated contours to a desired design; identifying regions not common to the simulated contours and the desired design; creating desired target shapes for a second photomask patterning process subsequent to the first photomask patterning process based upon the identified regions; and providing the desired target shapes for forming of a second photomask design based upon the desired target shapes.

Abstract: A method of designing a mask for projecting an image of an integrated circuit design in lithographic processing, wherein the integrated circuit layout has a plurality of segments of critical width. The method comprises creating a first mask design by aligning mask features used to assist in projecting critical width segments with the critical width segments of the integrated circuit design, such that the first mask design meets predetermined manufacturability design rules, and creating a second mask design by aligning mask features with the critical width segments of the integrated circuit design, such that the second mask design meets predetermined lithographic design rules in regions local to the critical width segments.

Abstract: A method for mask layout formation including forming a plurality of phase shapes on either side of a critical feature of a design layout of an integrated circuit chip having a plurality of critical features, wherein each phase shape has an edge; identifying a plurality of transition edges from the edges, wherein each transition edge is parallel to a critical feature; identifying a transition space defined by one of a group including two transition edges, wherein the space is external to all phase shapes, and one transition edge, wherein the space is external to all phase shapes; forming a transition polygon by closing each transition space with at least one closing edge, wherein each closing edge is perpendicular to the plurality of transition edges; transforming each transition polygon into a printing assist feature; and forming a first mask layout or a second mask layout from the printing assist features and the critical features.

Abstract: Integrated circuits and methods of manufacture and design thereof are disclosed. For example, a method of manufacturing includes depositing a gate material over a semiconductor substrate, and depositing a first resist layer over the gate material. A first mask is used to pattern the first resist layer to form first and second resist features. The first resist features include pattern for gate lines of the semiconductor device and the second resist features include printing assist features. A second mask is used to form a resist template; the second mask removes the second resist features.

Abstract: A method of designing a mask for projecting an image of an integrated circuit design in lithographic processing, wherein the integrated circuit layout has a plurality of segments of critical width. The method comprises creating a first mask design by aligning mask features used to assist in projecting critical width segments with the critical width segments of the integrated circuit design, such that the first mask design meets predetermined manufacturability design rules, and creating a second mask design by aligning mask features with the critical width segments of the integrated circuit design, such that the second mask design meets predetermined lithographic design rules in regions local to the critical width segments.

Abstract: A method for designing a mask for fabricating an integrated circuit is provided wherein a mask layout that requires coloring, such as for alternating phase shift, double-exposure and double-exposure-etch masks, is organized into uncolored hierarchical design units. Prior to modification by OPC, each hierarchical design unit is locally colored. OPC is then performed on the locally colored hierarchical design unit. The local coloring information for the hierarchically arranged OPC-modified design unit may be discarded. After OPC modification, the uncolored OPC-modified design units may be placed within the mask layout, and the flattened data may be colored. Thus, turnaround time for mask design is significantly improved since the numerically intensive OPC is performed on the hierarchical data, avoiding the need to perform OPC on flattened data, whereas the less intensive global coloring is performed on flattened data.

Abstract: A method of designing a mask for projecting an image of an integrated circuit design in lithographic processing, wherein the integrated circuit layout has a plurality of segments of critical width. The method comprises creating a first mask design by aligning mask features used to assist in projecting critical width segments with the critical width segments of the integrated circuit design, such that the first mask design meets predetermined manufacturability design rules, and creating a second mask design by aligning mask features with the critical width segments of the integrated circuit design, such that the second mask design meets predetermined lithographic design rules in regions local to the critical width segments.

Abstract: Integrated circuits and methods of manufacture and design thereof are disclosed. For example, a method of manufacturing includes depositing a gate material over a semiconductor substrate, and depositing a first resist layer over the gate material. A first mask is used to pattern the first resist layer to form first and second resist features. The first resist features include pattern for gate lines of the semiconductor device and the second resist features include printing assist features. A second mask is used to form a resist template; the second mask removes the second resist features.

Abstract: A method for designing alternating phase shift masks is provided, in which narrow phase shapes located between densely spaced design shapes are colored to allow a maximum amount of light transmission. After assigning and ensuring binary legalization of the phase shapes, the narrow phase shapes are assigned a color, such as 0° phase shift, that allows the more light transmission than the alternate or opposite color (e.g. 180° phase shift), which helps avoid printing errors such as resist scumming between closely spaced shapes, and maximizes the lithographic process window.

Abstract: A method for designing a mask for fabricating an integrated circuit is provided wherein a mask layout that requires coloring, such as for alternating phase shift, double-exposure and double-exposure-etch masks, is organized into uncolored hierarchical design units. Prior to modification by OPC, each hierarchical design unit is locally colored. OPC is then performed on the locally colored hierarchical design unit. The local coloring information for the hierarchically arranged OPC-modified design unit may be discarded. After OPC modification, the uncolored OPC-modified design units may be placed within the mask layout, and the flattened data may be colored. Thus, turnaround time for mask design is significantly improved since the numerically intensive OPC is performed on the hierarchical data, avoiding the need to perform OPC on flattened data, whereas the less intensive global coloring is performed on flattened data.

Abstract: A method of designing an alternating phase shifting mask for projecting an image of an integrated circuit design having a plurality of essentially parallel segments of critical width comprises creating essentially parallel alternating phase shifting regions aligned with the critical width segments and extending beyond ends of at least some of the critical width segments, enclosing the integrated circuit layout and the alternating phase shifting regions within a boundary, extending the alternating phase shifting regions to an edge of the boundary, and thereafter creating an alternating phase shifting mask based on the alternating phase shifting regions.

Abstract: A method of designing a mask for projecting an image of an integrated circuit design in lithographic processing, wherein the integrated circuit layout has a plurality of segments of critical width. The method comprises creating a first mask design by aligning mask features used to assist in projecting critical width segments with the critical width segments of the integrated circuit design, such that the first mask design meets predetermined manufacturability design rules, and creating a second mask design by aligning mask features with the critical width segments of the integrated circuit design, such that the second mask design meets predetermined lithographic design rules in regions local to the critical width segments.

Abstract: A method of designing lithographic masks is provided where mask segments used in a model-based optical proximity correction (MBOPC) scheme are adaptively refined based on local image information, such as image intensity, gradient and curvature. The values of intensity, gradient and curvature are evaluated locally at predetermined evaluation points associated with each segment. An estimate of the image intensity between the local evaluation points is preferably obtained by curve fitting based only on values at the evaluation points. The decision to refine a segment is based on the deviation of the simulated image threshold contour from the target image threshold contour. The output mask layout will provide an image having improved fit to the target image, without a significant increase in computation cost.

Abstract: A method of designing an alternating phase shifting mask for projecting an image of an integrated circuit design having a plurality of essentially parallel segments of critical width comprises creating essentially parallel alternating phase shifting regions aligned with the critical width segments and extending beyond ends of at least some of the critical width segments, enclosing the integrated circuit layout and the alternating phase shifting regions within a boundary, extending the alternating phase shifting regions to an edge of the boundary, and thereafter creating an alternating phase shifting mask based on the alternating phase shifting regions.

Abstract: A method of designing lithographic masks is provided where mask segments used in a model-based optical proximity correction (MBOPC) scheme are adaptively refined based on local image information, such as image intensity, gradient and curvature. The values of intensity, gradient and curvature are evaluated locally at predetermined evaluation points associated with each segment. An estimate of the image intensity between the local evaluation points is preferably obtained by curve fitting based only on values at the evaluation points. The decision to refine a segment is based on the deviation of the simulated image threshold contour from the target image threshold contour. The output mask layout will provide an image having improved fit to the target image, without a significant increase in computation cost.