Abstract: A system for controlling a tool-to-tool disparity between a plurality of scanning electron microscopes includes a measuring unit for measuring a tool-to-tool disparity between plural scanning electron microscopes based on information extracted from secondary electron images which are captured by imaging a reference pattern formed on a wafer, a tool state monitoring unit for monitoring tool states of each of the plural scanning electron microscopes, and an output unit for displaying on a screen a relationship between the tool-to-tool disparity between the plural scanning electron microscopes and tool states of each of the plural scanning electron microscopes monitored by the tool state monitoring unit. The tool state monitoring unit monitors the tool states of each of the plural scanning electron microscopes while imaging the reference pattern formed on the wafer by using each of the plural scanning electron microscopes.

Abstract: A method of inspecting patterns to detect a defect of the patterns by using information of a scattered diagram of brightness of said first and second images.

Abstract: A method and apparatus for efficiently executing two types of measurements with an optical measuring device and a scanning electron microscope are provided. For example, the method and apparatus may execute the following steps: calculating an average of the dimensional values of a plurality of scanned feature objects; and calculating an offset of a dimensional value on the basis of a difference between the calculated average value and the dimensional value of the feature object obtained when the light is irradiated. The offset between measurement values between the optical measuring device and the scanning electron microscope can be determined precisely.

Abstract: A system for controlling a tool-to-tool matching between a plurality of scanning electron microscopes for pattern dimension measurement includes a measuring unit for, at regular intervals, measuring a tool-to-tool disparity between canning electron microscopes based on secondary electron image data, and measuring indicators indicating states of the microscopes, a tool-to-tool-disparity causing factor analyzing unit for analyzing a relationship between the tool-to-tool disparity and the values of the indicators measured by the measuring unit to estimate a factor that has caused said tool-to-tool disparity, and an output unit for displaying and outputting the tool-to-tool disparity causing factor estimated by the tool-to-tool-disparity causing factor analyzing unit.

Abstract: A method of measuring pattern dimensions includes evaluating a relationship between cross-sectional shapes of a pattern and measurement errors of a pattern in a specified image processing technique, and conducting an actual measurement in which dimension measurement of an evaluation objective pattern from image signals of a microscope is carried out, and revising errors of the dimension measurement of the evaluation objective pattern based on the relationship between the cross-sectional shapes of a pattern and the measurement errors of a pattern previously evaluated.

Abstract: Disclosed is a scanning electron microscope (SEM) for realizing high-precision dimension measurement of a sample, such as an ArF exposure photoresist, that requires the measurement of a dimension by a low S/N signal waveform. To this end, partial waveforms (or partial images) of sample signal waveforms (or an images) acquired from a dimension measurement target sample and a sample material of the same kind are registered in advance, a measurement target signal waveform (or an image) obtained from the dimension measurement target sample and the sample registration waveform are combined, and a dimension of the dimension measurement target pattern is calculated based on the combination result.

Abstract: A pattern inspection apparatus including: an image detecting part for detecting a digital image of an object substrate; a display having a screen on which the digital image of the object substrate and/or a distribution of defect candidates in a map form are displayable; an input device for inputting information of a non-inspection region to be masked on the object substrate by defining a region on the screen on which said distribution of defect candidates is displayed in a map form; a memory part for storing coordinate data, pattern data or feature quantity data of the non-inspection region to be masked on the object substrate inputted on the screen by the input device; and a defect judging part in which the digital image detected by the image detecting part is examined in a state that a region matching with a condition stored in the memory part is masked and a defect is detected in a region other than said masked region.

Abstract: A pattern inspection method and apparatus in which a charged particle beam is irradiated onto a surface of a specimen on which a pattern is formed, plural sensors simultaneously detect secondary particles emanated from the surface of the specimen by the irradiation, signals outputted from each sensor of the plural sensors which simultaneously detect the secondary particles are added, an image of the surface of the specimen on which the pattern is obtained from the added signals, and the image is processed to detect a defect of the pattern.

Abstract: There is provided a device which may easily and visually judge which chip in an FEM wafer has a normal exposure condition, or which chip has an abnormal exposure condition. A feature quantity for a sectional shape of a resist pattern of an FEM wafer is calculated for each chip region on an FEM wafer using an image of a resist pattern for an FEM wafer. The feature quantity of a sectional shape is displayed for each chip in a chip table of a map representing a position of a chip region on the FEM wafer. Deviations in feature quantities of sectional shapes of resist patterns of a FEM wafer to an appropriate value are displayed in color in the chip table.

Abstract: It is difficult for a material having low resistance to electron beam irradiation to obtain an electron microscopic image having a high S/N ratio. A conventional image smoothing process can improve stability of measurement, but this process has a problem of measurement errors for absolute values, reduction of sensitivity, deterioration of quality of cubic shape information and the like. In the present invention, by performing an image averaging process without deteriorating cubic shape information of a signal waveform in consideration of dimension deviation of a measurement target pattern, measurement stability is compatible with improvement of precision and sensitivity. Accordingly, it is possible to realize measurement of pattern dimensions and shapes with high precision and control of a highly sensitive semiconductor manufacturing process using the measurement.

Abstract: As measurement accuracy required for the scanning electron microscope (SEM) for measuring a pattern width becomes stringent, a technique of reducing the difference in a measured dimension between the SEM's is desired. However, the conventional technique of evaluating the difference in a measured dimension between the SEM's cannot separate the difference in a measured dimension between the SEM's themselves and a dimensional change resulting from deformation of the pattern itself. Moreover, the technique of reducing the difference in a measured dimension between the SEM's needs an operator for reducing the difference in a measured dimension between the SEM's for each measurement pattern shape.

Abstract: A method for measuring a dimension of a pattern formed on a sample using a secondary electron image obtained by picking up an image of the sample using a scanning electron microscope includes: obtaining a secondary electron image of a sample by picking up an image of the sample using a scanning electron microscope; creating, using the secondary electron image, an image profile of a pattern whose dimension is to be measured, within the obtained secondary electron image; retrieving a model profile that matches best with the created image profile from a plurality of model profiles prestored that are obtained from respective secondary electron images of a plurality of patterns, the cross sections of the plurality of patterns being of known shapes and dimensions and being different in shape; and obtaining a dimension of the pattern using information of the retrieved model profile.

Abstract: The present invention relates to an electron microscope which reduces a difference in measured values that occur due to a difference in resolution that cannot be fully adjusted which exists among electron microscopes, or occurs as time elapses, and a method for measuring dimensions. An operator adapted to compensate for changes of an electron image to be generated due to a difference in probe diameter is obtained in advance from electron images of one reference sample created by electron microscopes having different resolution (probe diameter). Then a compensation-measurement electron image which is equivalent to an electron image created under the same probe diameter by applying the operator for compensation, and the compensation-measurement electron image is used for measuring the dimensions.

Abstract: A method of inspecting patterns to detect a defect of the patterns by using information of a scattered diagram of brightness of said first and second images.

Abstract: In the case of monitoring a resolution of a scanning electron microscope, it is required to prepare a sample and to use a measuring algorithm so as to reduce the pattern dependency of an index value of resolution to be measured in order to measure a variation in the size of an electron beam with a high degree of accuracy. According to the present invention, there is used a sample having a sectional shape which is appropriate for monitoring the resolution, that is, the sample has a pattern with such a sectional shape that a side wall of the pattern is inclined so as to prevent an electron beam irradiated on the sample from impinging upon the side wall of the pattern. With this configuration, it is possible carry out such resolution monitor that does not depend upon a sectional shape of a pattern.

Abstract: An apparatus for processing a defect candidate image, including: an imager for taking an enlarged image of a specimen; an image processor for processing the image taken by the imager to detect defect candidates existing on the specimen and classify the detected defect candidates into one of plural defect classes; a memory for storing information of the defect candidates including the images of the defect candidates and the classified defect class data outputted from the image processor; and a display unit having a display screen for displaying information stored in the memory, wherein the display unit displays an image of the defect candidates together with the defect class data stored in the memory and the displayed defect class data is changeable on the display screen, and the memory changes the stored defect class data of the displayed defect candidate to the changed defect class data.

Abstract: An apparatus for processing a defect candidate image, including: a scanning electron microscope for taking an enlarged image of a specimen by irradiating and scanning a converged electron beam onto the specimen and detecting charged particles emanated from the specimen by the irradiation; an image processor for processing the image taken by the scanning electron microscope to detect defect candidates on the specimen and classify the detected defect candidates into one of plural classes; a memory for storing output from the image processor including images of the detected defect candidates; and a display unit which displays information stored in the memory and an indicator, wherein the display unit displays a distribution of the detected and classified defect candidates in a map format by distinguishing by the classified class, and the display unit also displays an image of a defect candidate stored in the memory together with the map which is indicated on the map by the indicator.

Abstract: With complexity of a process, the setting of conditions for pattern measurement by an SEM image falls into difficulties. However, the present invention aims to realize the setting of easy and reliable measuring conditions even with respect to a pattern complex in structure. Points characterized in terms of an SEM image signal are calculated as candidates for measurement values. The calculated candidates for measurement values are displayed with being superimposed on the SEM image. An operator selects the optimum one from the displayed candidates and thereby determines the optimum image processing condition for measurement. The relationship between the result of measurement under a predetermined image processing condition and pattern portions has been made clear using model data of a sectional shape and an electron beam simulation image.

Abstract: In a pattern inspecting apparatus, images of places which can be expected to be the same pattern are compared with one another. However, a comparison of images obtained by different stage scans and the occurrence of a place capable of being inspected only once lead to a deterioration in the performance of detecting various error defects and an area incapable of being inspected, respectively. For solving this problem, defects detected in a high sensitivity condition are regarded as defect candidates and a critical threshold value, used as a boundary to detect a smaller value as a defect, of a defect candidate portion is obtained by an image processing circuit or an image of the defect candidate portion is obtained by processing with software. Further, the critical threshold value thus obtained is compared with plural threshold values, thereby permitting plural inspection results to be obtained in a single inspection.

Abstract: Disclosed is a scanning electron microscope (SEM) for realizing high-precision dimension measurement of a sample, such as an ArF exposure photoresist, that requires the measurement of a dimension by a low S/N signal waveform. To this end, partial waveforms (or partial images) of sample signal waveforms (or an images) acquired from a dimension measurement target sample and a sample material of the same kind are registered in advance, a measurement target signal waveform (or an image) obtained from the dimension measurement target sample and the sample registration waveform are combined, and a dimension of the dimension measurement target pattern is calculated based on the combination result.