Abstract: A method extends the use of phase shift techniques to complex layouts, and includes identifying a pattern, and automatically mapping the phase shifting regions for implementation of such features. The pattern includes small features having a dimension smaller than a first particular feature size, and at least one relatively large feature, the at least one relatively large feature and another feature in the pattern having respective sides separated by a narrow space. Phase shift regions are laid out including a first set of phase shift regions to define said small features, and a second set of phase shift regions to assist definition of said side of said relatively large feature. An opaque feature is used to define the relatively large feature, and a phase shift region in the second set is a sub-resolution window inside the perimeter of the opaque feature.

Abstract: Techniques provided for fabricating a device include forming a fabrication layout, such as a mask layout, for a physical design layer, such as a design for an integrated circuit, and identifying evaluation points on an edge of a polygon corresponding to the design layer for correcting proximity effects. Included are techniques that correct for proximity effects associated with an edge in a layout corresponding to the design layer.

Abstract: Mask shops typically use carbon to repair any clear defects identified on a mask, irrespective of the type of mask. However, carbon can have different characteristics than the original patterning material on the mask. Therefore, a mask that is repaired using carbon may not optically perform as if it were defect-free. An automated method of repairing a clear defect on an attenuated phase shifting mask (PSM) provides an optimized plug size/shape. In this method, a repair solution to the clear defect can be simulated, thereby allowing the repair decision for an attenuated PSM to be advantageously made at the same time that inspection is done and before actual repair. Simulation can include performing model-based OPC on the repair solution.

Abstract: A two-dimensional yield map for a device, such as an integrated circuit, in a fabrication facility is computed and associated with layout data for the device in a hierarchical and/or instance-based layout file. The device has a layout including a pattern characterizable by a combination of members of a set of basis shapes. A set of basis pre-images include yield map data representing an interaction of respective members of the set of basis shapes with a defect model. A yield map for the pattern is created by combining basis pre-images corresponding to basis shapes in the combination of members that characterize the pattern to provide a combination result. The output may be displayed as a two dimensional map to an engineer performing yield analysis, or otherwise processed.

Abstract: One embodiment of the present invention provides a system that controls rippling caused by optical proximity correction during an optical lithography process for manufacturing an integrated circuit. During operation, the system selects an evaluation point for a given segment, wherein the given segment is located on an edge in the layout of the integrated circuit. The system also selects a supplemental evaluation point for the given segment. Next, the system computes a deviation from a target location for the given segment at the evaluation point. The system also computes a supplemental deviation at the supplemental evaluation point. Next, the system adjusts a bias for the given segment, if necessary, based upon the deviation at the evaluation point. The system also calculates a ripple for the given segment based upon the deviation at the evaluation point and the supplemental deviation at the supplemental evaluation point.

Abstract: One embodiment of the invention provides a system that creates a phase-shifting mask for a photolithographic process used in fabricating an integrated circuit. The system starts by receiving a layout for the integrated circuit. The system then associates nodes with features in the layout, and generates arcs between the nodes. Next, the system generates a coloring for the nodes using two colors. The system then generates phase shifters for the phase-shifting mask and assigns different phases to the phase shifters based upon the coloring of the nodes.

Abstract: A lithography process model is generated to account for asymmetric printing of a feature of a target pattern to help better predict how the target pattern will print. The process model for one embodiment may be generated based on data generated from measurements of spacings between symmetrically defined features of printed test patterns to help predict edge offsets of the feature relative to the target pattern when printed and/or to help predict a dimension of the feature when printed. The process model may be used to help design, manufacture, and/or inspect a mask to help print the target pattern more accurately and therefore help manufacture an integrated circuit (IC), for example, that more accurately matches its intended layout.

Abstract: A method and apparatus for inspecting a photolithography mask for defects is provided. The inspection method comprises providing a defect area image to an image simulator wherein the defect area image is an image of a portion of a photolithography mask, and providing a set of lithography parameters as a second input to the image simulator. The defect area image may be provided by an inspection tool which scans the photolithography mask for defects using a high resolution microscope and captures images of areas of the mask around identified potential defects. The image simulator generates a first simulated image in response to the defect area image and the set of lithography parameters. The first simulated image is a simulation of an image which would be printed on a wafer if the wafer were to be exposed to an illumination source directed through the portion of the mask.

Abstract: A lithography mask layout is designed and verified incrementally to help reduce the amount of time to produce the mask layout. For one embodiment, a layout defining a target pattern may be processed to produce a mask layout, and the mask layout may be verified to identify errors. Rather than processing and verifying the entire mask layout for error correction over one or more subsequent iterations, sub-layouts having errors may be removed or copied from the mask layout for separate processing and verification. Because the amount of data defining a sub-layout is relatively small, the time to design and verify the mask layout is reduced. The resulting mask layout having one or more processed and verified sub-layout(s) may then be used to manufacture a mask set to help print the target pattern in manufacturing integrated circuits (ICs), for example.

Abstract: One embodiment of the invention provides a system that communicates feedback from a compactor to a router to facilitate layout of an integrated circuit. The system operates by first receiving a routing for a cell in an integrated circuit layout at the compactor. The system then attempts to compact the routing. If compaction of the routing fails, the system identifies an infeasibility path in the routing and rips up traces on the infeasibility path while leaving other traces undisturbed. The system then adjusts parameters associated with the routing process and reroutes the cell using the adjusted parameters. The system then attempts to compact this rerouting.

Abstract: One embodiment of the invention provides a system that facilitates minimum spacing and/or width control during an optical proximity correction operation for a layout of a mask used in manufacturing an integrated circuit. During operation, the system considers a target edge of a first feature on the mask and then identifies a set of interacting edges in proximity to the target edge. Next, the system performs the optical proximity correction operation, wherein performing the optical proximity correction operation involves applying a first edge bias to the target edge to compensate for optical effects in a resulting image of the target edge. While applying the first edge bias to the target edge, the system allocates an available bias between the first edge bias for the target edge and a second edge bias for at least one edge in the set of interacting edges.

Abstract: Features of a mask, when close enough to one another, can cause unwanted phantom images to print on an integrated circuit. Advantageously, potential locations of phantom images can be automatically identified from a mask layout. This technique can include creating perimeters or rings around features in the mask layout (in one case, after proximity correction). An overlap of perimeters/rings can be assigned a particular weight such that areas of greater overlap have a higher weight and areas of less overlap have a lower weight. If the weight of an overlap area exceeds a trigger weight, then an evaluation point can be added to the mask layout, thereby identifying that layout location as a potential location of a phantom image. After simulation of the mask layout, that layout location can be analyzed to determine if a phantom image would print.

Abstract: Defect printability analysis in a mask or wafer requires the accurate identification of defect images and reference (i.e. defect-free) images, in particular for a die-to-die inspection mode. A method of automatically distinguishing a reference image from a defect image is provided. In this method, multiple images can be accessed and aligned. Then, a common area of the multiple images can be defined. At this point, a complexity of each of the images, as defined by the common area, can be computed. Advantageously, by comparing the complexity of the multiple images, the reference and defect images can be quickly and accurately designated. Specifically, the most complex image is designated the defect image because the defect image must describe the defect. Complexity can be computed using various techniques.

Abstract: One embodiment of the invention provides a system that simulates effects of a manufacturing process on an integrated circuit to enhance process latitude and/or reduce layout size. During operation, the system receives a representation of a target layout for the integrated circuit, wherein the representation defines a plurality of shapes that comprise the target layout. Next, the system simulates effects of the manufacturing process on the target layout to produce a simulated printed image for the target layout. The system then identifies problem areas in the simulated printed image that do not meet a specification. Next, the system moves corresponding shapes in the target layout to produce a new target layout for the integrated circuit, so that a simulated printed image of the new target layout meets the specification.

Abstract: One embodiment of the invention provides a system that uses simulation results to select evaluation points for a model-based optical proximity correction (OPC) operation. Upon receiving a layout, the system first selects critical segments in the layout, and then performs a dense simulation on the critical segments. This dense simulation identifies deviations (or low contrast) between a desired layout and a simulated layout at multiple evaluation points on each of the critical segments. Next, for each critical segment, the system selects an evaluation point from the multiple evaluation points on the critical segment based on results of the dense simulation. The system then performs a model-based OPC operation using the selected evaluation point for each critical segment.

Abstract: An automated metrology recipe set up process is described for a manufacturing process, in which patterns to be formed on a device are defined using a design database. The design database is processed to produce a simulated image of a feature for use in a metrology tool for a measurement of the feature. The simulated image is supplied to the metrology tool, where it is used as a basis for alignment of the tool for the measurement. Other recipe data is combined with the simulated image to provide a fully automated metrology set up process.

Abstract: One embodiment of the invention provides a system for analyzing a layout related to a circuit on a semiconductor chip. The system operates by receiving a design hierarchy specifying the layout of the circuit. This design hierarchy includes a set of hierarchically organized nodes, wherein a given node in the design hierarchy specifies a geometrical feature that is comprised of lower-level geometrical features that are represented by lower-level nodes located under the given node in the design hierarchy. The system modifies the design hierarchy by, examining a set of sibling nodes that are located under a parent node in the design hierarchy in order to identify a set of interacting geometrical features between the set of sibling nodes. The system then moves the set of interacting geometrical features from the sibling nodes to the parent node, so that the interaction is visible at the parent node.

Abstract: Techniques are provided for extending the use of phase shift techniques to implementation of masks used for complex layouts in the layers of integrated circuits, beyond selected critical dimension features. The method includes identifying features for which phase shifting can be applied, automatically mapping the phase shifting regions for implementation of such features, resolving phase conflicts which might occur according to a given design rule, and application of assist features and proximity correction features. The method includes applying an adjustment to a phase shift mask pattern including a first and a second phase shift window, and a control chrome with a control width, and/or to a trim mask pattern having a trim shape with a trim width based upon one or both of a rule based correction and a model based correction to improve a match between a resulting exposure pattern and a target feature.

Abstract: One embodiment of the invention provides a system for analyzing a layout related to a circuit on a semiconductor chip. The system operates by receiving a design hierarchy specifying the layout of the circuit. This layout includes a set of hierarchically organized nodes, wherein a given node specifies a geometrical feature that is comprised of lower-level geometrical features that are represented by lower-level nodes located under the given node in the design hierarchy. The system operates by modifying the design hierarchy by examining a set of sibling nodes that are located under a parent node in the design hierarchy in order to identify a set of interacting geometrical features between the set of sibling nodes. Next, the system then moves the set of interacting geometrical features to a new child node under the parent node, and then performs an analysis on the modified design hierarchy.

Abstract: Techniques for forming a mask fabrication layout for a physical integrated circuit design layout include correcting the fabrication layout for proximity effects using a proximity effects model. A proximity effects model is executed to produce an initial output. The initial output is based on a first position for a segment in a fabrication layout. The first position is displaced from a corresponding original edge in the original fabrication layout by a distance equal to an initial bias. The model is also executed to produce a second output based on a second position for the segment. The second position is displaced from the corresponding original edge by a distance equal to a second bias. An optimal bias for the segment is determined based on the initial output and the second output. The segment is displaced in the fabrication layout from the corresponding edge based on the optimal bias.