Abstract: During a calculation technique, a modification to a reflective photo-mask is calculated. In particular, using information specifying a defect associated with a location on a top surface of the reflective photo-mask, the modification to the reflective photo-mask is calculated. For example, the calculation may involve an inverse optical calculation in which a difference between a pattern associated with the reflective photo-mask at an image plane in a photo-lithographic process and a reference pattern at the image plane in the photo-lithographic process is used to calculate the modification at an object plane in the photo-lithographic process. Note that the modification includes a material added to the top surface of the reflective photo-mask using an additive fabrication process. Moreover, the modification is proximate to the location.

Abstract: A technique for reconstructing an electron-beam (EB) image, which can be a scanning-electron-microscope (SEM) image or an EB-inspection image, is described. This reconstruction technique may involve an inverse electro-optical calculation that corrects for the influence of an electro-optical transfer function associated with an EB system on the EB image. In particular, in the inverse calculation a multi-valued representation of an initial EB image is at an image plane in the model of the electro-optical transfer function and a resulting EB image is at an object plane in the model of the electro-optical transfer function. Furthermore, the model of the electro-optical transfer function may have an analytical derivative and/or may be represented by a closed-form expression.

Abstract: A system receives a mask pattern and a first image of at least a portion of a photo-mask corresponding to the mask pattern. The system determines a second image of at least the portion of the photo-mask based on the first image and the mask pattern. This second image is characterized by additional spatial frequencies than the first image.

Abstract: During a calculation technique, a modification to a reflective photo-mask is calculated. In particular, using information associated with different types of analysis techniques a group of one or more potential defects in the reflective photo-mask is determined. Then, the modification to the reflective photo-mask is calculated based on at least a subset of the group of potential defects using an inverse optical calculation. In particular, during the inverse optical calculation, a cost function at an image plane in a model of the photolithographic process is used to determine the modification to the reflective photo-mask at an object plane in the model of the photolithographic process.

Abstract: During a calculation technique, contributions to reflected light from multiple discrete cells in a model of a multilayer stack in a reflective photo-mask may be determined based on angles of incidence of light in a light pattern to the multilayer stack, a polarization of the light in the light pattern, and a varying intensity of the light in the light pattern through the multilayer stack. Then, phase values of the contributions to the reflected light from the multiple discrete cells are adjusted, thereby specifying optical path differences between the multiple discrete cells in the multilayer stack that are associated with the defect. Moreover, the contributions to the reflected light from multiple discrete cells are combined to determine the reflected light from the multilayer stack. Next, k-space representations of the contributions to the reflected light from the multiple discrete cells are selectively shifted based on the angles of incidence.

Abstract: A technique for providing information about defects in a mask pattern is described. In this technique, defects in the mask pattern may be determined based on differences between a calculated pattern produced at an image plane in the photolithographic process, when the mask pattern, illuminated by an associated source pattern, is at an object plane in the photolithographic process, and a target pattern that excludes the defects. Then the defect information may be provided to the user, such as a spatial map of the determined defects, where the spatial map is associated with at least the portion of the mask pattern.

Abstract: A technique for determining photo-mask defect disposition is described. In this technique, a target mask pattern is used to expand an initial region in a photo-mask that is included in an initial mask-inspection image. In particular, a revised mask-inspection image that includes the initial region and a region surrounding the initial region is generated based on the initial mask-inspection image and the target mask pattern. Then a corresponding simulated mask pattern is calculated in an inverse optical calculation using the revised mask-inspection image and an optical model of the mask-inspection system. This simulated mask pattern is used to simulate a wafer pattern in a photo-lithographic process, and disposition of a possible defect in the initial region is subsequently determined based on the simulated wafer pattern and a target wafer pattern.

Abstract: A technique for calculating a second aerial image associated with a photo-mask that can be used to determine whether or not the photo-mask (which may include defects) is acceptable for use in a photolithographic process is described. In particular, using a first aerial image produced by the photo-mask when illuminated using a source pattern and an inspection image of the photo-mask, a mask pattern corresponding to the photo-mask is determined. For example, the first aerial image may be obtained using an aerial image measurement system, and the inspection image may be a critical-dimension scanning-electron-microscope image of the photo-mask. This image, which has a higher resolution than the first aerial image, may indicate spatial-variations of a magnitude of the transmittance of the photo-mask. Then, the second aerial image may be calculated based on the determined mask pattern using a different source pattern than the source pattern.

Abstract: During a calculation technique, at least a portion of a target pattern associated with an integrated-circuit design is modified so that polygons in the target pattern, which represent features in the design, result in acceptable accuracy during a photolithographic process that fabricates the target pattern on a semiconductor die. In particular, a set of polygon parameters associated with the polygons are modified, as needed, so that a cost function that corresponds to a difference between a modified target pattern and an estimated target pattern produced during the photolithographic process meets a termination criterion. A mask pattern that can fabricate the modified target pattern on the semiconductor die is calculated using an inverse optical calculation in which the modified target pattern is at an image plane of an optical path associated with the photolithographic process and the mask pattern is at an object plane of the optical path.

Abstract: A technique for reconstructing a mask pattern corresponding to a photo-mask using a target mask pattern (which excludes defects) and an image of at least a portion of the photo-mask is described. This image may be an optical inspection image of the photo-mask that is determined using inspection optics which includes an optical path, and the reconstructed mask pattern may include additional spatial frequencies than the image. Furthermore, the reconstructed mask pattern may be reconstructed based on a characteristic of the optical path (such as an optical bandwidth of the optical path) using a constrained inverse optical calculation in which there are a finite number of discrete feature widths allowed in the reconstructed mask pattern, and where a given feature has a constant feature width. Consequently, the features in the reconstructed mask pattern may each have the constant feature width, such as an average critical dimension of the reconstructed mask pattern.

Abstract: A system receives a mask pattern and a first image of at least a portion of a photo-mask corresponding to the mask pattern. The system determines a second image of at least the portion of the photo-mask based on the first image and the mask pattern. This second image is characterized by additional spatial frequencies than the first image.

Abstract: A system receives a mask pattern and a first image of at least a portion of a photo-mask corresponding to the mask pattern. The system determines a second image of at least the portion of the photo-mask based on the first image and the mask pattern. This second image is characterized by additional spatial frequencies than the first image.

Abstract: A system receives a mask pattern and a first image of at least a portion of a photo-mask corresponding to the mask pattern. The system determines a second image of at least the portion of the photo-mask based on the first image and the mask pattern. This second image is characterized by additional spatial frequencies than the first image.

Abstract: During a method for generating a mask pattern for a photo-mask, a target pattern is partitioned into subsets of the target pattern. The subsets of the target pattern may be selected so that at least some of the subsets are approximately identical, thereby dividing the subsets into a degenerate group and a non-degenerate group. A group of the subsets may include multiple shapes, and a given target pattern may be significantly larger than a pre-determined length scale and a given shape in the multiple shapes is smaller than the pre-determined length scale. The non-degenerate group of subsets of the target pattern may be distributed to multiple processors. These processors may be used to determine subsets of the mask pattern based on the non-degenerate group of subsets of the target pattern. The subsets of the mask pattern may be combined to generate the mask pattern.

Abstract: A system receives a mask pattern and a first image of at least a portion of a photo-mask corresponding to the mask pattern. The system determines a second image of at least the portion of the photo-mask based on the first image and the mask pattern. This second image is characterized by additional spatial frequencies than the first image.

Abstract: A system receives a mask pattern and a first image of at least a portion of a photo-mask corresponding to the mask pattern. The system determines a second image of at least the portion of the photo-mask based on the first image and the mask pattern. This second image is characterized by additional spatial frequencies than the first image.

Abstract: A system receives a mask pattern and a first image of at least a portion of a photo-mask corresponding to the mask pattern. The system determines a second image of at least the portion of the photo-mask based on the first image and the mask pattern. This second image is characterized by additional spatial frequencies than the first image.

Abstract: A method for generating a write pattern to be used in a maskless-lithography process is described. During the method, a computer system determines a one-to-one correspondence between pixels in the write pattern and at least a subset of elements in a spatial-light modulator used in the maskless-lithography process. Furthermore, the computer system generates the write pattern. Note that the write pattern includes features corresponding to at least the subset of elements in the spatial-light modulator, and the generating is in accordance with a characteristic dimension of an element in the spatial-light modulator and a target pattern that is to be printed on a semiconductor wafer during the maskless-lithography process.

Abstract: Embodiments of a method for determining a mask pattern to be used on a photo-mask in a lithography process are described. This method may be performed by a computer system. During operation, this computer system receives at least a portion of a first mask pattern including first regions that violate pre-determined rules associated with the photo-mask. Next, the computer system determines a second mask pattern based on at least the portion of the first mask pattern, where the second mask pattern includes second regions that are estimated to comply with the pre-determined rules. Note that the second regions correspond to the first regions, and the second mask pattern is determined using a different technique than that used to determine the first mask pattern.

Abstract: A method for determining mask patterns to be used on photo-masks in a multiple-exposure photolithographic process is described. During the method, an initial mask pattern, which is intended for use in a single-exposure photolithographic process, and a target pattern that is to be printed are used to determine a first mask pattern and a second mask pattern, which are intended for use in the multiple-exposure photolithographic process. In particular, the first mask pattern includes a first feature and the second mask pattern includes a second feature, and the first feature and the second feature overlap an intersection between features in the initial mask pattern. Moreover, the first mask pattern and the second mask pattern have at least one decreased spatial frequency relative to the initial mask pattern along at least one direction in the initial mask pattern.