Abstract: A pattern inspection apparatus includes: an optical image acquiring unit configured to acquire optical image data of a target object on which each of a plurality of identical patterns is respectively formed at a respective corresponding position of a plurality of forming positions with distortion; a cut-out unit configured to cut out a plurality of partial optical image data from the optical image data; a correction unit configured to correct positions of the plurality of partial optical image data by using distortion information from which each amount of distortion of the plurality of identical patterns respectively formed at the respective corresponding position of the plurality of forming positions on the target object can be acquired; and a comparison unit configured to compare a plurality of corrected partial optical image data against each other on a pixel to pixel basis.

Abstract: The entire surface of a photomask 101 is inspected after data and parameters of the lithography simulator are set in the operation setting screen of a control computer 110 and after the inspection system 100 is calibrated. The coordinates of a portion or portions determined in the inspection to be a defect are written into an XML file. When the inspection system 100 is in the die-to-database inspection mode, the control computer 110 reads pattern data from the database, which data is used by the inspection system 100 to generate reference data, and then converts the read pattern data into OASIS format, which is highly versatile. The optical image captured by the inspection system 100 is converted into a bitmap. These data are sent to the lithography simulator, together with simulation operating conditions and the image data that was used to calibrate the inspection system 100.

Abstract: A pattern inspection apparatus includes a first unit configured to acquire an optical image of pattern, a second unit configured to generate a reference image to be compared, a third unit configured to calculate elements of a normal matrix for a least-squares method for calculating a displacement amount displaced from a preliminary alignment position, a forth unit configured to estimate a type of the reference image pattern, by using some of the elements of the normal matrix, a fifth unit configured to calculate the displacement amount based on the least-squares method, by using a normal matrix obtained by deleting predetermined elements depending upon the type of the pattern, a sixth unit configured to correct an alignment position between the optical image and the reference image to a position displaced by the displacement amount, and a seventh unit configured to compare the optical image and the reference image.

Abstract: In an automatic focus adjusting mechanism, a test sample having a patterned surface is mounted on a mount table, and an light beam passing through a slit formed in a field stop is applied to the patterned surface of the test sample. The light beam reflected from the test sample is split into two segment light beams. Focus adjusting aperture stops having respective apertures formed rhomboid are provided across the optical paths of the segment light beams. The amounts of the segment light beams passing through the rhomboid apertures are detected by light receiving units. Based on the difference between the detected light amounts, the position of the mount table is controlled by the focus adjusting unit.

Abstract: A technique for correcting an image by using frequency division images and decomposition images corresponding in number to reference points is disclosed. An image correction apparatus includes an image divider which divides an inspection reference image into frequency regions to form frequency division images, a decomposition image generator for defining reference points at several locations within at least one frequency division image and for applying weighting with each reference point as a reference to thereby generate decomposition images corresponding in number to the reference points, a model parameter identifier for identifying a model parameter by using 2D linear prediction models of an image being tested, the decomposition images and a frequency division image which is out of the generation of decomposition images, and a model image generator for using the model parameter to generate a model image.

Abstract: An image correction device for use in a pattern inspection apparatus is disclosed, which has automatic adaptability to variations in density of a pattern image of a workpiece being tested. The device is operable to identify a two-dimensional (2D) linear predictive model parameters from the pattern image of interest and determine the value of a total sum of these identified parameters. This value is then used to switch between a corrected pattern image due to the 2D linear prediction modeling and a corrected image that is interpolated by bicubic interpolation techniques. A pattern inspection method using the image correction technique is also disclosed.

Abstract: An illumination beam irradiation apparatus for use in pattern inspection systems is disclosed, which is less in deterioration of optical components and in attenuation of illumination light. The illumination apparatus includes a light source which yields a fundamental wave, a beam-shaper unit which performs beam-shaping of the fundamental wave so that this wave has a prespecified shape, and a pattern generator unit which operates, upon receipt of the beam-shaped fundamental wave, to convert this incoming wave into illumination light with a shorter wavelength to thereby generate illumination light of a prespecified shape. The illuminator also includes an image relay unit for guiding the illumination light that was generated by the pattern generator to fall onto a workpiece under inspection, such as a photomask or else.

Abstract: A pattern image inspection apparatus with enhanced image correctability due to consolidation of alignment and image correction by using an image as divided by frequency regions while reducing image degradation and setup parameters is disclosed. The apparatus includes an image divider for creating for the test image and the reference image a plurality of frequency division images divided into frequency regions, a model parameter identifier for using 2D linear prediction models of the test image and the reference image to identify model parameters for each frequency division image, a model image generator for creating a model image based on the model parameters, and a comparison processor for performing inspection by comparing the model image to either the test image or the reference image with respect to each frequency division image. An image inspection method is also disclosed.

Abstract: A mask/reticle pattern inspection apparatus capable of readily detecting local critical dimension (CD) errors of a circuit pattern of a testing workpiece is disclosed. This apparatus includes a search unit for finding a plurality of resembling or “look-alike” adjacent patterns around a specific pattern on the workpiece, which have similarity to the specific pattern. The inspection apparatus also includes a calculation unit for obtaining dissimilarity between the specific pattern and look-alike adjacent pattern, a variation evaluation unit which excludes an allowable error from the dissimilarity to thereby obtain a local CD error criterion value, and a CD error decision unit for determining the presence of a local CD error when the criterion value exceeds a threshold value in case the distance between the specific and look-alike patterns increases. A pattern inspection method is also disclosed.

Abstract: A wavelength conversion light source apparatus includes a fundamental wave light source configured to emit a fundamental wave, a nonlinear crystal configured to convert a wavelength of the fundamental wave by being irradiated with the fundamental wave and making the fundamental wave pass therethrough, and a movement unit configured to place the nonlinear crystal thereon and continuously move the nonlinear crystal within a plane, where a phase matching condition is not violated, so that a passage path of the fundamental wave passing through the nonlinear crystal is changed.

Abstract: In a reticle inspecting apparatus or the like, there is provided an image correcting method which is effective when a rank of a matrix lacks due to continuous equal grayscale values when an image is handled as a matrix. In the image correcting method, a random noise image having fine grayscale is superposed on a pattern image to make a matrix full-rank.

Abstract: An XY stage apparatus capable of reducing a measurement error due to air fluctuations is provided. The XY stage apparatus includes a stage that moves in the XY directions, a laser interferometer to measure a position of the stage, and a measuring optical path barrel mechanism having a fixed barrel that covers at least a portion of a measuring optical path between the stage and the laser interferometer, is provided on a side of the laser interferometer of the measuring optical path, and is fixed to the laser interferometer and a movable barrel that covers at least a potion of the measuring optical path, is provided on the side of the stage of the measuring optical path, and moves together with movement of the stage, wherein an end of one of the fixed barrel and the movable barrel is inserted into that of the other.

Abstract: A photomask inspection method that identifies a foreign particle such as dirt on a photomask with high sensitivity by suppressing erroneous identification due to an influence of noise is provided. The photomask inspection method includes acquiring image data of a photomask having regions with different layer structures on a surface thereof, creating inverted image data by subtracting the image data from pixel value data of the regions, creating offset inverted image data by raising pixel values of the inverted image data by a fixed amount, creating normalized correlation image data by computing a normalized correlation of the offset inverted image data and an offset Gaussian distribution-type kernel, and identifying foreign particles by comparing the normalized correlation image data and a predetermined threshold.

Abstract: A pattern inspection apparatus includes an optical image acquiring unit that acquires optical image data of a target plate formed as a pattern. The pattern inspection apparatus also includes a design image data generating unit that generates first design image data based on a first design pattern serving as a base of pattern formation of the target plate. The pattern inspection apparatus additionally includes a comparing unit that compares the optical image data and the first design image data with each other. Further, information of a second design pattern is input in parallel with information of the first design pattern to the pattern inspection apparatus. In the comparing unit, second design image data generated based on the second design pattern is further input, and the optical image data is compared with the second design image data in place of the first design image data.

Abstract: A target workpiece inspection apparatus comprises an optical image acquiring unit to acquire an optical image of a target workpiece, a reference image generating unit to generate a reference image to be compared, a difference judging unit to judge whether an absolute value of difference between pixel values of the images in each pixel at a preliminary alignment position between the images is smaller than a threshold value, a least-squares method displacement calculating unit to calculate a displacement amount displaced from the preliminary alignment position, by using a regular matrix for a least-squares method obtained from a result judged, a position correcting unit to correct an alignment position between the optical image and the reference image to a position displaced from the preliminary alignment position by the displacement amount, and a comparing unit to compare the optical image and the reference image whose alignment position has been corrected.

Abstract: A pattern inspection apparatus is disclosed, which includes a first laser light source for emission of first laser light having a first wavelength, a second laser light source for emission of second laser light having a second wavelength, and a deep ultraviolet (DUV) light source for emission of DUV light with a wavelength of less than or equal to 266 nm based on the first laser light and the second laser light. A first optical fiber is provided for connecting between the first laser light source and the DUV light source. A second optical fiber is for connection between the second laser light source and the DUV light source. The apparatus also includes a pattern inspection unit with the DUV light source being built therein, for inspecting a workpiece pattern being tested by using the DUV light as illumination light therefore.

Abstract: A workpiece inspection apparatus includes a search unit for finding from an input reference image a first pixel group which contains a certain pixel and a second pixel group having grayscale values within a threshold, and a probability acquisition unit responsive to receipt of an optical image of a workpiece being tested and the reference image, for obtaining a probability value based on a grayscale value of the certain pixel, a grayscale value of its corresponding pixel in the second pixel group, a grayscale value of an optical image pixel corresponding to the certain pixel, and a grayscale value of an optical image pixel corresponding to a pixel in the second pixel group corresponding to the certain pixel. The probability value is used to determine whether a defect exists at the optical image pixel corresponding to the certain pixel.

Abstract: A pattern inspection apparatus, including an optical image acquiring unit that acquires optical image data of a target plate to be inspected, the target plate being formed as a pattern. The pattern inspection apparatus also includes a design image data generating unit that generates design image data based on a design pattern serving as a base of pattern formation of the target plate. The pattern inspection apparatus further includes a comparing unit that inputs region image data generated based on information of a region pattern which is input to the pattern inspection apparatus. The information of the region pattern represents a predetermined region and is formed in the same format as that of information of the design pattern. The comparing unit compares the optical image data with the design image data based on the region image data.

Abstract: A technique for discriminating a specific pattern, such as an assist pattern, from an integrate circuit pattern of a workpiece by using transmission and reflection images of the workpiece pattern is disclosed. A pattern discrimination device includes an optical image acquisition unit for acquiring a transmissive image of a workpiece having a pattern and a reflective image of the workpiece pattern simultaneously, and a specific pattern detection unit which detects for extraction a specific pattern from among pattern shapes of the transmissive and reflective images in conformity with a distinguishing condition of the specific pattern. A workpiece pattern inspection apparatus using the device is also disclosed.

Abstract: A pattern inspection apparatus which compares a plurality of partial optical image data of a same target plate to be inspected, the target plate being formed as a pattern, includes an optical image data acquiring unit which acquires optical image data of the target plate to be inspected, and a comparing circuit which compares the plurality of partial optical image data. In the comparing circuit, region image data generated based on information of region pattern representing a predetermined region is input, and a decision criterion is changed with reference to the input region image data when the plurality of partial optical image data are compared with each other to decide the presence/absence of a defect on the target plate.