A method including obtaining a first image of an object, generating a second image by convolving the first image with a filter kernel, wherein each pixel value of the second image is a weighted combination of a plurality of accumulation values associated with surrounding pixels of the first image, and determining, based on the second image, whether the object includes a defect.

A system and method for optimizing an illumination source to print a desired pattern of features dividing a light source into pixels and determining an optimum intensity for each pixel such that when the pixels are simultaneously illuminated, the error in a printed pattern of features is minimized. In one embodiment, pixel solutions are constrained from solutions that are bright, continuous, and smooth. In another embodiment, the light source optimization and resolution enhancement technique(s) are iteratively performed to minimize errors in a printed pattern of features.

A method for obtaining a compensation pattern for a workpiece patterning device comprises printing (S11) a calibration pattern with a plurality of simultaneously operating exposure beams being sweepable in a second direction according to calibration pattern print data having a multitude of edges. Positions of the edges are measured (S12). Deviations of the measured positions relative calibration pattern are calculated (S13). Each deviation is associated (S14) with a used exposure beam, with a sweep position and a grid fraction position. Edge compensating data is computed (S15) for adapting edge representations of pattern print data prior to printing to compensate for the calculated deviations. The edge compensating data is dependent on the used exposure beam, the sweep position, and the grid fraction position.

A method includes detecting data associated with a patterning device and/or a lithographic apparatus, performing an action from a plurality of actions when a determination not to proceed is made, and performing the action on the patterning device and/or a lithographic apparatus.

A method of aligning a pair of complementary diffraction patterns having a first complementary diffraction pattern and a second complementary diffraction pattern, the pair of complementary diffraction patterns obtained from performance of a metrology process on a structure formed by a lithographic process. The method includes performing at least a fine alignment stage to align the pair of complementary diffraction patterns. The alignment stage includes: interpolating measured values of the first complementary diffraction pattern over at least a portion of a detector area; and minimizing a residual between measured values in the second complementary diffraction pattern and corresponding interpolated values from the interpolation of the first complementary diffraction pattern, by one or both of translation and rotation of the second complementary diffraction pattern.

A method for transferring a fractured pattern decomposed into elementary shapes, onto a substrate by direct writing by a particle or photon beam, comprises a step of identifying at least one elementary shape of the fractured pattern, called removable elementary shape, whose removal induces modifications of the transferred pattern within a preset tolerance envelope; a step of removing the removable shape or shapes from the fractured pattern to obtain a modified fractured pattern; and an exposure step, comprising exposing the substrate to a plurality of shots of a shaped particle or photon beam, each shot corresponding to an elementary shape of the modified fractured pattern. A computer program product for carrying out such a method is provided.

An imaging device has a photoconductive drum with a surface that is charged and selectively discharged to create a latent electrostatic image of an image to-be-printed for attracting toner for transfer to a media. A memory of the imaging device stores energy density values for use by the laser beam that can be accessed by a controller according to a predetermined number of media imaged by the photoconductive drum. During imaging, the controller controls the laser beam based on the stored energy density values. The energy density of the laser beam is increased or decreased when the laser beam is scanned along the photoconductive drum.

Disclosed are a substrate treating apparatus and a substrate treating method. The substrate treating apparatus includes a first process chamber configured to supply a development liquid to a substrate that is carried into the first process chamber after an exposure process is performed on the substrate, a second process chamber configured to treat the substrate through a supercritical fluid, a feeding robot configured to transfer the substrate from the first process chamber to the second process chamber, and a controller configured to control the feeding robot such that the substrate is transferred to the second process chamber in a state in which the development liquid supplied by the first process chamber resides in the substrate.

A lithography system is provided capable of deterring contaminants, such as tin debris from entering into the scanner. The lithography system in accordance with various embodiments of the present disclosure includes a processor, an extreme ultraviolet light source, a scanner, and a hollow connection member. The light source includes a droplet generator for generating a droplet, a collector for reflecting extreme ultraviolet light into an intermediate focus point, and a light generator for generating pre-pulse light and main pulse light. The droplet generates the extreme ultraviolet light in response to the droplet being illuminated with the pre-pulse light and the main pulse light. The scanner includes a wafer stage. The hollow connection member includes an inlet that is in fluid communication with an exhaust pump. The hollow connection member provides a hollow space in which the intermediate focus point is disposed. The hollow connection member is disposed between the extreme ultraviolet light source and the scanner.

A method for improving a lithographic process for imaging a portion of a design layout onto a substrate using a lithographic apparatus, the method including: obtaining a first source of the lithographic apparatus; classifying the first source into a class among a plurality of possible classes, based on one or more numerical characteristics of the first source, using a machine learning model, by a computer; determining whether the class is among one or more predetermined classes; only when the class is among the one or more predetermined classes, adjusting one or more source design variables to obtain a second source.