JP3904796B2 - Foreign object or defect inspection apparatus, and foreign object or defect inspection method - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a foreign matter or defect inspection apparatus and a foreign matter or defect inspection method, and relates to a foreign matter existing in a thin film substrate, a semiconductor substrate, a photomask, or the like in manufacturing a semiconductor chip or a liquid crystal product, or a pattern defect generated in the pattern. The present invention relates to a foreign matter or defect inspection apparatus and a foreign matter or defect inspection method capable of quickly displaying the cause of the failure by displaying the inspection result in a format that can be easily analyzed by the user.
[0002]
[Prior art]
2. Description of the Related Art Conventionally, a technique for detecting defects on a semiconductor substrate or the like with an optical measuring means is widely known. For example, the “semiconductor wafer inspection apparatus” disclosed in Japanese Patent Application Laid-Open No. Sho 62-89336 detects scattered light from foreign matter generated when foreign matter adheres to a semiconductor substrate by irradiating a laser on the semiconductor substrate. A technique that enables inspection of foreign matter or defects by comparing with the inspection result of the same type semiconductor substrate inspected immediately before is disclosed.
[0003]
Further, as described in “Method and apparatus for measuring particle or defect size information” in Japanese Patent Application Laid-Open No. 5-273110, a laser beam is irradiated on a test object, and the particle or crystal of the test object is irradiated. A method for measuring the size of a particle or crystal defect by receiving scattered light from the defect and performing image processing is disclosed.
[0004]
[Problems to be solved by the invention]
2. Description of the Related Art Conventionally, in a production line for semiconductor substrates, thin film substrates, and the like, a management method for monitoring foreign matters and defects on a substrate has been used as one of methods for managing product manufacturing processes. As one of such monitoring methods, a method of inspecting a foreign substance or a defect inspection apparatus for inspecting a foreign substance or a pattern defect on a substrate and monitoring a transition of the number of detections from the foreign substance or the defect inspection apparatus Is used, and a defect analysis is performed on a foreign object / defect on a substrate having a large number of detected objects.
[0005]
However, with this conventional technique, the time required for defect analysis is “detection number × defect analysis time for one foreign object / defect”, especially when the number of detected objects in the foreign object defect inspection apparatus is large. There is a problem that the analysis takes an enormous amount of time and the production of the substrate is delayed.
[0006]
The present invention has been made in order to solve the above-described prior art, and its purpose is to perform the inspection and defect analysis of the manufacturing process of a semiconductor wafer or a thin film substrate, the size of foreign matter, the size of pattern defects, It is an object of the present invention to provide a foreign matter or defect inspection apparatus and a foreign matter or defect inspection method capable of quickly taking countermeasures against defects by performing inspections according to the characteristics of the region of the inspection object.
[0007]
[Means for Solving the Problems]
In order to achieve the above object, the first configuration of the foreign matter or defect inspection apparatus according to the present invention is a foreign matter or defect inspection apparatus that measures an object to be inspected by an optical technique and detects the foreign matter or defect. An illuminating means for irradiating light on the object to be inspected, a light detecting means for detecting reflected light or scattered light from the object to be inspected, and a signal detected by the light detecting means. Detection means for detecting a defect and a signal detected by the light detection means The signal detected by the light detection means when the X and Y axes are defined as coordinate axes for determining the position in the image obtained by For the part where the peak level of the waveform is saturated, Said X, Y axis Dimension measurement that measures the size of a foreign substance or a defect using information on each peak level of the detected signal waveform by calculating a peak level from signal information of a portion that is not saturated based on information on a sectional shape in a direction Means for processing the result of the inspection, and means for displaying the information on the result of the inspection. The cause of failure is pointed out from the processing, and the result information of the inspection is displayed on the display means.
[0008]
In order to achieve the above object, the second configuration of the foreign matter or defect inspection apparatus according to the present invention is a foreign matter or defect inspection apparatus that measures an object to be inspected by an optical technique and detects foreign matter or defects. An illuminating means for irradiating light on the object to be inspected, a light detecting means for detecting reflected light or scattered light from the object to be inspected, and a signal detected by the light detecting means. Detection means for detecting a defect and a signal detected by the light detection means The signal detected by the light detection means when the X and Y axes are defined as coordinate axes for determining the position in the image obtained by For the part where the peak level of the waveform is saturated, Said X, Y axis Dimension measurement that measures the size of a foreign substance or a defect using information on each peak level of the detected signal waveform by calculating a peak level from signal information of a portion that is not saturated based on information on a sectional shape in a direction Means for processing the inspection result, and means for displaying the inspection result information. The means for displaying the inspection result information has a size of the foreign matter or defect obtained by the dimension measuring means. Frequency distribution display is performed.
[0009]
In order to achieve the above object, a third configuration of the foreign matter or defect inspection apparatus according to the present invention is a foreign matter or defect inspection apparatus that measures an object to be inspected by an optical method and detects the foreign matter or defect. An illuminating means for irradiating light on the object to be inspected, a light detecting means for detecting reflected light or scattered light from the object to be inspected, and a signal detected by the light detecting means. Detection means for detecting a defect and a signal detected by the light detection means The signal detected by the light detection means when the X and Y axes are defined as coordinate axes for determining the position in the image obtained by For the part where the peak level of the waveform is saturated, Said X, Y axis Dimension measurement that measures the size of a foreign substance or a defect using information on each peak level of the detected signal waveform by calculating a peak level from signal information of a portion that is not saturated based on information on a sectional shape in a direction Means, a data processing means for processing the inspection result, and a means for displaying the inspection result information. It is displayed by discriminating from defects.
[0010]
In order to achieve the above object, the fourth configuration of the foreign matter or defect inspection apparatus according to the present invention is a foreign matter or defect inspection apparatus for measuring an object to be inspected by an optical technique and detecting foreign matter or a defect. An illuminating means for irradiating light on the object to be inspected, a light detecting means for detecting reflected light or scattered light from the object to be inspected, and a signal detected by the light detecting means. Detection means for detecting a defect and a signal detected by the light detection means The signal detected by the light detection means when the X and Y axes are defined as coordinate axes for determining the position in the image obtained by For the part where the peak level of the waveform is saturated, Said X, Y axis Dimension measurement that measures the size of a foreign substance or a defect using information on each peak level of the detected signal waveform by calculating a peak level from signal information of a portion that is not saturated based on information on a sectional shape in a direction Means, data processing means for processing the inspection result, and means for displaying the inspection result information, providing management information for each area of the object to be inspected, the management information and the foreign matter detected from the area Alternatively, the defect size is compared, and the quality analysis for each area of the inspection target object is evaluated to perform defect analysis for each area.
[0011]
More specifically, in the foreign matter or defect inspection apparatus, a foreign matter or defect having a specific size for each region is displayed as distinguished from other foreign matter or defect based on the result of the evaluation.
[0012]
In order to achieve the above object, a fifth configuration of the foreign matter or defect inspection apparatus according to the present invention is a foreign matter or defect inspection apparatus for measuring an object to be inspected by an optical technique and detecting foreign matter or a defect. An illuminating means for irradiating light on the object to be inspected, a light detecting means for detecting reflected light or scattered light from the object to be inspected, and a signal detected by the light detecting means. Detection means for detecting a defect and a signal detected by the light detection means The signal detected by the light detection means when the X and Y axes are defined as coordinate axes for determining the position in the image obtained by For the part where the peak level of the waveform is saturated, Said X, Y axis Dimension measurement that measures the size of a foreign substance or a defect using information on each peak level of the detected signal waveform by calculating a peak level from signal information of a portion that is not saturated based on information on a sectional shape in a direction Means for processing the result of the inspection, and means for displaying the result information of the inspection, the object to be inspected being managed for each region, and means for displaying the result information of the inspection The frequency distribution display of the size of the foreign matter or defect obtained by the dimension measuring means is performed for each region.
[0013]
More specifically, in the foreign matter or defect inspection apparatus, in the illumination means, the light source for detecting the foreign matter or the defect and the light source for measuring the size of the foreign matter or the defect are the same light source. Is.
[0015]
Next, in order to achieve the above object, the first configuration of the invention relating to the foreign matter or defect inspection method of the present invention is to measure a subject to be inspected by an optical method and detect the foreign matter or defect. In the inspection method, a procedure for irradiating the inspection object with light, a procedure for detecting reflected light or scattered light from the inspection object, and a procedure for detecting a foreign object or a defect based on the detected signal And the detected signal The signal detected when the X and Y axes are defined as coordinate axes for determining the position in the image obtained by For the part where the peak level of the waveform is saturated, Said X, Y axis A procedure for measuring the size of a foreign substance or a defect using information on each peak level of the detected signal waveform by calculating a peak level from signal information of a portion that is not saturated based on information on a sectional shape in a direction; The data processing procedure for processing the inspection result and the procedure for displaying the inspection result information are performed in this order, and the size of the foreign matter or the defect and the cause of the defect are related. The cause of the defect is pointed out from the statistical processing, and the result information of the inspection is displayed.
[0016]
In order to achieve the above object, the second configuration of the foreign matter or defect inspection method of the present invention is a foreign matter or defect inspection method for measuring a subject to be inspected by an optical technique and detecting the foreign matter or defect. , A procedure for irradiating the object to be inspected with light, a procedure for detecting reflected or scattered light from the object to be inspected, a procedure for detecting foreign matter or a defect based on the detected signal, and detection Signal The signal detected when the X and Y axes are defined as coordinate axes for determining the position in the image obtained by For the part where the peak level of the waveform is saturated, Said X, Y axis A procedure for measuring the size of a foreign substance or a defect using information on each peak level of the detected signal waveform by calculating a peak level from signal information of a portion that is not saturated based on information on a sectional shape in a direction; The data processing procedure for processing the inspection result and the procedure for displaying the inspection result information are performed in this order, and when the inspection result information is displayed, the foreign matter obtained by the procedure for measuring the dimensions or The frequency distribution display of the size of the defect is performed.
[0017]
In order to achieve the above object, a third configuration of the foreign matter or defect inspection method of the present invention is a foreign matter or defect inspection method for measuring a subject to be inspected by an optical technique and detecting the foreign matter or defect. , A procedure for irradiating the object to be inspected with light, a procedure for detecting reflected or scattered light from the object to be inspected, a procedure for detecting foreign matter or a defect based on the detected signal, and detection Signal The signal detected when the X and Y axes are defined as coordinate axes for determining the position in the image obtained by For the part where the peak level of the waveform is saturated, Said X, Y axis A procedure for measuring the size of a foreign substance or a defect using information on each peak level of the detected signal waveform by calculating a peak level from signal information of a portion that is not saturated based on information on a sectional shape in a direction; The data processing procedure for processing the inspection result and the procedure for displaying the inspection result information are performed in this order, and when the inspection result information is displayed, the foreign matter or defect of a specific size is replaced with another foreign matter. Or it is made to distinguish and display from a defect.
[0018]
In order to achieve the above object, a fourth configuration of the foreign matter or defect inspection method of the present invention is a foreign matter or defect inspection method for measuring a subject to be inspected by an optical technique and detecting the foreign matter or defect. , A procedure for irradiating the object to be inspected with light, a procedure for detecting reflected or scattered light from the object to be inspected, a procedure for detecting foreign matter or a defect based on the detected signal, and detection Signal The signal detected when the X and Y axes are defined as coordinate axes for determining the position in the image obtained by For the part where the peak level of the waveform is saturated, Said X, Y axis A procedure for measuring the size of a foreign substance or a defect using information on each peak level of the detected signal waveform by calculating a peak level from signal information of a portion that is not saturated based on information on a sectional shape in a direction; The data processing procedure for processing the inspection result and the procedure for displaying the inspection result information are performed in this order, and management information is provided for each region of the object to be inspected. By comparing the size of the foreign matter or the defect and evaluating the quality of each area of the object to be inspected, a defect analysis can be performed for each area.
[0019]
More specifically, in the foreign matter or defect inspection method, based on the result of the evaluation, a foreign matter or defect having a specific size for each region is displayed separately from other foreign matters or defects.
[0020]
In order to achieve the above object, a fifth configuration of the foreign matter or defect inspection method of the present invention is a foreign matter or defect inspection method for measuring a subject to be inspected by an optical technique and detecting the foreign matter or defect. , A procedure for irradiating the object to be inspected with light, a procedure for detecting reflected or scattered light from the object to be inspected, a procedure for detecting foreign matter or a defect based on the detected signal, and detection Signal The signal detected when the X and Y axes are defined as coordinate axes for determining the position in the image obtained by For the part where the peak level of the waveform is saturated, Said X, Y axis A procedure for measuring the size of a foreign substance or a defect using information on each peak level of the detected signal waveform by calculating a peak level from signal information of a portion that is not saturated based on information on a sectional shape in a direction; When the data processing procedure for processing the inspection result and the procedure for displaying the inspection result information are performed in this order, and the inspection object is managed for each area, and the inspection result information is displayed. In addition, the frequency distribution display of the size of the foreign matter or defect obtained by the procedure of measuring the dimensions for each region is performed for each region.
[0021]
More specifically, in the foreign matter or defect inspection method, the light source for detecting the foreign matter or the defect and the light source for measuring the size of the foreign matter or the defect are the same light source in the illuminating procedure. It is a thing.
[0023]
DETAILED DESCRIPTION OF THE INVENTION
Embodiments according to the present invention will be described below with reference to FIGS.
[Configuration and operation of foreign matter or defect inspection apparatus according to the present invention]
First, the configuration and operation of the foreign matter or defect inspection apparatus according to the present invention will be described with reference to FIGS.
FIG. 1 is a diagram showing a configuration of a foreign matter or defect inspection apparatus according to the present invention.
FIG. 2 is a block diagram when the foreign matter or defect inspection apparatus according to the present invention is operated as a system.
[0024]
Hereinafter, in the embodiment, a case where a foreign substance on a semiconductor wafer is inspected will be described as an example. However, the present invention can also be applied to an apparatus for inspecting a pattern defect other than a foreign substance. Further, the present invention is not limited to semiconductor wafers, and can be applied to thin film substrates, photomasks, TFTs, PDPs, and the like.
[0025]
A foreign matter or defect inspection apparatus according to the present invention includes an illumination optical system 101, a detection optical system 103, a light detection unit 104, a signal processing circuit 105, a data display unit 106, a stage unit 107, an autofocus illumination unit 108, and an autofocus light receiving unit. 109.
[0026]
When inspecting, the inspection object 102 is placed on the stage unit 107, the inspection object 102 is irradiated by the illumination optical system 101, and the scattered light from the inspection object 102 is collected by the detection optical system 103. Then, the light detection unit 104 detects scattered light from the inspection object 102. Scattered light detected by the light detection unit 104 is subjected to photoelectric conversion and the like, and signal processing is performed by the signal processing circuit 105, whereby a foreign object is detected and its size is measured.
[0027]
Further, the object to be inspected 102 is moved in the horizontal direction by the stage unit 107, and further the vertical direction so that the object to be inspected 102 comes to the focal position of the detection optical system 103 by the autofocus illumination unit 108 and the autofocus light receiving unit 109. By moving to the position, it is possible to detect the foreign matter in the entire region of the inspection object 102 and measure the size thereof. The detection result is displayed on the data display unit 106.
[0028]
Here, the illumination optical system 101 is configured such that, for example, a laser light source such as an Ar laser or a semiconductor laser is used to irradiate the inspection object 102 with light using a beam expander, a collimator lens, a cylindrical lens, or the like. It is adjusted so that light is irradiated to the focal position of the detection optical system 103. In addition, the detection optical system 103 is configured with an optical lens so that the light detected from the inspection object 102 out of the light irradiated by the illumination optical system 101 is condensed on the light detection unit 104. The detection optical system 103 can also perform optical processing on the scattered light, for example, change / adjustment of optical characteristics using a polarizing plate or a spatial filter.
[0029]
The light detection unit 104 receives scattered light collected by the detection optical system 103 and performs photoelectric conversion. For example, the light detection unit 104 is a TV camera, a CCD linear sensor, a TDI sensor, an anti-blooming TDI sensor, a photomultiplier, or the like. It is. Further, the signal processing circuit 105 includes a part for detecting foreign matter and a part for measuring the size of the foreign matter. When the signal processing circuit 105 detects a foreign object, for example, the input signal is binarized, and a signal equal to or higher than the binarization threshold is determined as a foreign object and output. The signal processing circuit 105 also measures the size of the foreign matter, and the processing will be described in detail later. Furthermore, the stage unit 107 includes, for example, a mechanism for moving the inspection object 102 in the horizontal and vertical directions and rotating the inspection object 102. In addition, the autofocus illumination unit 108 condenses light emitted from a white light source such as an Hg lamp or a laser light source such as He—Ne on the inspection object 102. The auto-focus light receiving unit 109 is a part that receives light reflected from the inspection object 102 out of the light emitted from the auto-focus illumination unit 108, and can detect the position of light such as a position sensor, for example. Is used. Furthermore, information obtained by the autofocus light receiving unit 109 is sent to the stage unit 107 and used for stage control. In the example shown in this figure, the illumination optical system 101 shows an example in which the object 102 is illuminated from one direction. However, the illumination optical system 101 may be configured to illuminate from two or more directions. Furthermore, in the example of this figure, each of the detection optical system 103 and the detection unit 104 is one and is detected in one direction with respect to the inspection object 102, but has two or more of these and has two or more directions. It is also possible to use a configuration that detects with.
[0030]
Next, when the system is configured using the foreign matter or defect inspection apparatus according to the present invention, it is as shown in FIG. In other words, this system includes a foreign substance inspection apparatus 1301, a data server 1302, a review apparatus 1303, an electrical test apparatus 1304, an analysis apparatus 1305, and a network 1306 connecting the apparatuses. Here, the review device 1303 is, for example, a length measurement SEM, the electrical test device 1304 is a tester, and the analysis device 1305 is a device that analyzes a foreign component such as EDX. The data server 1302 is a computer that can collect and store inspection data of the foreign substance inspection apparatus 1301, review results of the review apparatus 1303, test results of the electrical test apparatus 1304, and analysis results of the analysis apparatus 1305. Is, for example, an Ethernet communication network.
[0031]
Next, the operation of the system using the foreign matter or defect inspection apparatus will be described. After the inspection by the foreign object inspection apparatus 1301, a foreign object requiring countermeasures is selected by the method described above. Information on the selected foreign matter is added to the inspection result of the foreign matter inspection device 1301, for example, the serial number at the time of detection of the detected foreign matter, the position information of the foreign matter and the size information of the foreign matter, and the data server 1302 via the network 1306 Send. Here, as a method of adding information on the selected foreign matter, for example, a flag indicating whether countermeasures are necessary may be added to the inspection result. Then, the object to be inspected is moved to the review device 1303 in order to examine the foreign matter detected by the foreign matter inspection device 1301 in more detail. This movement may be manual conveyance or mechanical conveyance. After the inspection object is moved to the review device 1303, the review device 1303 accesses the data server 1302 and receives the inspection result from the data server 1302 via the network 1306. And a review is started using this test result. At this time, by using the information added by the foreign substance inspection apparatus 1301 to preferentially review foreign substances that need countermeasures, it becomes possible to quickly analyze foreign substances that cause defects. Similarly, the analysis apparatus 1305 can preferentially analyze a foreign substance that needs countermeasures based on information added by the foreign substance inspection apparatus 1301, and can promptly analyze the cause of the defect.
[0032]
These review data and analysis results are accumulated in the data server 1302 and can be checked with the test results in the electrical test apparatus 1304 to confirm whether or not they finally become defective. If it does not eventually become defective, the data server 1302 transmits data for changing the standard for selecting a foreign substance requiring countermeasures to the foreign substance inspection apparatus 1301, and the standard for determining whether the foreign substance inspection apparatus 1301 needs countermeasures. By changing, it becomes possible to select a foreign substance that needs countermeasures with higher accuracy, and it is possible to take countermeasures against defects in semiconductor manufacturing more quickly.
[0033]
Although the above explanation has been given taking the case where data is transmitted / received via a network as an example, it is not necessarily performed via a network, and data is transferred via a removable storage medium or printed paper. May be.
[0034]
[Measurement of foreign material size]
Next, a process for measuring the size of a foreign substance using the foreign substance or defect inspection apparatus of the present invention will be described with reference to FIGS.
FIG. 3 is a diagram illustrating image data when there is a foreign object, and a diagram illustrating a signal intensity distribution when the foreign object data is measured.
FIG. 4 is a diagram comparing two types of signal intensity distributions and an explanatory diagram for obtaining the maximum value of the signal intensity.
[0035]
FIG. 3A shows an example of an image processed by the signal processing circuit 105 when there is a foreign object, and foreign object data 201 exists at the center of the image. The foreign matter data 201 is output from the light detection unit 104 and is captured by the signal processing circuit 105 as data having a gray value. FIG. 3B is a three-dimensional representation of FIG. 3A. The x and y axes are coordinate axes for determining the position in the image, and the z axis is a plot of the signal intensity at that position. And connected with lines. In FIG. 3B, the waveform 202 indicates the waveform data of the foreign matter data 201. This waveform 202 is a waveform that can be approximated to a Gaussian distribution due to the properties of the illumination optical system 101 and the detection optical system 103, and the width and height of the Gaussian distribution change depending on the size of the foreign matter on the inspection object 102. Furthermore, the width and height of the distribution change depending on the illuminance of the laser illumination used in the illumination optical system 101. Therefore, if the shape and feature of the distribution are measured in advance with respect to various standard particles with the apparatus configuration of the present invention, and the measurement result is compared with the detected waveform 202, the size information of the detected foreign matter is obtained. Obtainable.
[0036]
Here, as a method of comparing the waveform of the standard particle and the waveform 202 of the foreign substance, the total sum (integrated value) of the signal intensity of the foreign substance data 201 part, that is, the volume data of the waveform 202 is measured, The volume data and the volume data of the foreign matter data 201 may be compared. However, if there is a difference in illuminance of the illumination optical system 101 during measurement of these data, normalization is performed by dividing each volume data by the illuminance of the illumination optical system 101 using the respective volume data, or the illuminance ratio is determined as a foreign object. The volume data is corrected by multiplying the data 201 or the volume data of the standard particles.
[0037]
As another method for comparing waveforms, the maximum value of the signal intensity of the waveform 202 or the width of the waveform 202 may be compared.
[0038]
In the following, a method for obtaining the maximum value of the signal strength will be described with reference to FIG. FIG. 4 shows an example of the waveform data of the foreign matter data, similarly to the waveform 202. FIG. 4A shows a mountain-shaped waveform in which the signal waveform of the foreign matter data obtained by the light detection unit 104 has a peak. This indicates that the signal does not reach the saturation region of the light detection unit 104. FIG. 4B is an example in which the signal waveform of the foreign substance data has a plateau-like waveform at the top, which is that the signal has reached the saturation region of the light detection unit 104 and is higher than the saturation region. Indicates that no data exists.
[0039]
When the signal waveform as shown in FIG. 4A is drawn, the maximum value of the signal strength is obtained by comparing the signal strength of each pixel of the waveform, that is, the peak signal strength 301 is the signal strength. Maximum value. When drawing a signal waveform as shown in FIG. 4B, the following calculation is performed to obtain the maximum value of the signal intensity.
[0040]
First, in the saturation region 302, the maximum length of the saturated region is obtained in the x and y directions. Shown in FIG. 4C is a cross section of FIG. In FIG. 4C, the horizontal axis is a coordinate axis indicating the pixel position of the maximum length portion, and the vertical axis is a coordinate axis indicating the signal intensity. The signal intensity 303 indicates the saturation level of the light detection unit 104. Three or more unsaturated signals 304 are selected for this cross section. Here, the description will be made assuming that three points are selected. As points to be selected, three signals that are not saturated in the cross section are selected from those having a high signal intensity. If the coordinates of the selected three points are x1, x2, and x3, and the signal strengths are z1, z2, and z3, the unknowns k, σ, and u are used.
[0041]
[Expression 1]
z1 = k / σ × exp (− (x1−u) ² / (2 × σ ² ))
z2 = k / σ × exp (− (x2−u) ² / (2 × σ ² ))
z3 = k / σ × exp (− (x3−u) ² / (2 × σ ² ))
An expression for the Gaussian distribution is obtained. The unknowns k, σ, and u can be obtained by combining the above three equations. Then, using the obtained values of k and σ, the maximum value of the signal intensity in FIG.
k / σ
Can be calculated as
[0042]
By comparing the maximum value of the signal intensity obtained by the above calculation with the value of the standard particle and the value of the detected foreign matter, the size of the foreign matter can be measured.
[0043]
In this embodiment, in the description of the above configuration, the illumination optical system 101 uses an example of using laser light, but measurement using white light may also be used. Further, for the foreign matter on the circuit pattern having repeatability, the above-described size measurement process may be performed after taking a difference between an image in which no foreign matter is present on the repeated pattern and an image in which the foreign matter is present. Regardless of the presence or absence of repeatability, if scattered light data is obtained in advance from a circuit pattern or film on a circuit pattern or film, such as an oxide film or metal film, the data can be used to May be corrected. Furthermore, in order to measure the size of the foreign material, the comparison is made here with the size of the standard particle, but this may be compared with a foreign material of known size.
[0044]
In the above description, foreign matter inspection has been performed using scattered light. As an advantage of this method, it is possible to efficiently detect foreign substances. In addition, if the size of the foreign matter is determined by the method described above, a special light source for measuring the size is not required, and the foreign matter can be found and its size can be measured. There is an advantage that it can be performed with a light source using the same scattered light.
[0045]
[Defect cause analysis and result display]
Next, a procedure for analyzing the cause of failure and a procedure for displaying the result to the user when the size of the foreign matter is measured by the foreign matter or defect inspection apparatus of the present invention will be described with reference to FIGS.
FIG. 5 is a diagram showing that the relationship between the size of foreign matter and the number of occurrences varies depending on the cause of the defect.
FIG. 6 is a line graph showing the number of detected foreign objects and the size of the foreign objects.
FIG. 7 is a diagram showing the number of detected foreign objects and the size of the foreign objects in a histogram.
FIG. 8 is a schematic diagram explicitly showing a foreign substance having a specific size on the wafer.
FIG. 9 is a graph showing the transition of the number of detections for each size of a specific foreign object in time series.
FIG. 10 is a diagram of a screen that displays the cause of a defect in which a foreign object has occurred to the user.
[0046]
One important idea of the present invention is to use foreign matter size information for analysis of the cause of failure. In the following, the effectiveness of using foreign matter size information for failure cause analysis will be described.
[0047]
Here, it is assumed that a foreign substance is detected from a wafer applied to a semiconductor manufacturing apparatus, for example, an etching apparatus, and the relationship between the size of the foreign substance and the number of generated foreign substances is as shown in FIG. A region 401 in FIG. 5A shows a distribution of foreign matters that are constantly generated during the process of the etching apparatus. In this case, the size of the foreign matter is concentrated in the portions a to b, and one gentle mountain is formed according to the size of the foreign matter.
[0048]
On the other hand, FIG. 5B shows an example of the foreign substance generation distribution when the apparatus is abnormal. In this case, in addition to the foreign substance in the steady state shown in the area 401, it is shown in the area 402. Such large foreign matters (portions having a size of c or more) frequently occur. This may be because deposits deposited on the inner wall surface of the etching apparatus were peeled off from the wall surface during the etching process. FIG. 5C also shows an example of the generated foreign material distribution at the time of abnormality. In this case, in addition to the foreign matter in the steady state, the size of the foreign matter is concentrated on the portions d to e. This may be because the specific pattern is peeled off during the etching process.
[0049]
As described above, in a manufacturing apparatus such as a semiconductor, there is a relation between the size of a generated foreign matter and the cause of the generation of the foreign matter. You can know quickly. That is, the cause of the failure can be determined by examining the relationship between the size of the foreign matter and the number of occurrences.
[0050]
As a matter of course, the values a to e and the like are values that vary depending on the manufacturing apparatus, the manufacturing process, and the like, and foreign substances generated due to other causes may exhibit different sizes of distribution. Therefore, it is better to use data according to the size distribution of the foreign matter for each cause. In this example, the cause of the occurrence of foreign matter is specified in two ranges, but it may be divided into two or more regions.
[0051]
Next, the function for analyzing the cause of failure will be described in detail.
[0052]
First, the display of the size and the number of detected foreign objects on the data display unit 106 will be described. The data display unit 106 displays a graph of the size distribution of foreign matter as described above, that is, a graph that shows the relationship between the size of foreign matter and the number of detected foreign matters. Figure 6 Is a graph in which the horizontal axis represents the size of a foreign object and the vertical axis represents the number of detected foreign objects. A point 501 indicates the number of detections by size, and in the example of this graph, data in units of 0.1 μm is indicated. The graph 502 is a line connecting the points 501 with straight lines. By displaying the graph as in this example, it is possible to quickly see how the distribution of the foreign matter detected from the inspection object 102 is. Here, the minimum value on the horizontal axis may be, for example, the minimum detection size of the foreign substance inspection apparatus or the size of the foreign substance desired to be managed in the semiconductor manufacturing line. The scale may be displayed logarithmically as in this graph, may be linear, or the scale unit may be variable. Furthermore, the display range of each axis may be fixed or variable, and for example, only a specific foreign matter cause may be displayed by displaying only a specific size. Further, the contents arranged on the vertical axis and the horizontal axis may be interchanged, and may be expressed by the density of foreign matter instead of the number of detected foreign matter. Furthermore, although the graph is displayed in this example, an average value of the graph, a standard deviation value or a variance value of the graph may be displayed in addition to the graph.
[0053]
The graph may be displayed using a histogram as shown in FIG. The graph of FIG. 7 is a graph in which the horizontal axis indicates the size of a foreign object and the vertical axis indicates the number of detected foreign objects, as in FIG. In this graph, the horizontal axis is displayed by dividing the size of the foreign matter into certain sections, and indicates the case where the data section is in units of 0.2 μm. Further, when a bar graph is selected, a function for displaying the position information of the detected foreign matter in the selected portion may be added.
[0054]
A function for displaying the detected position information of the foreign matter will be described. FIG. 8A displays position information of all detected foreign matters detected by the foreign matter inspection. In this figure, for example, the detected foreign matter 702 is present on the outer shape 701 of an 8-inch semiconductor wafer. At this time, when the bar graph 601 in FIG. 7 is clicked or double-clicked, a function of changing the section of the bar graph 601, that is, the display of the foreign matter 703 of 2.8 μm to 3.0 μm as shown in FIG. Thereby, it becomes possible to quickly grasp the position of the foreign object having a specific size on the inspection object 102.
[0055]
Next, a management method when the size of a specific foreign object is statistically taken in time series will be described with reference to FIG.
[0056]
Here, FIG. 9A shows a time-series transition of the total sum of all foreign matters regardless of the size detected by the foreign matter detection device for wafers of the same process processed by the same manufacturing apparatus, FIG. 9C shows a time-series transition of the sum total of foreign matters having a size of 2.8 to 3.0 [μm] of the size of foreign matters shown in the example of FIG. FIG. 9 (b) is a graph showing changes in time series of the total sum of foreign matters having other sizes.
[0057]
Further, threshold values 1001, 1002, and 1003 indicate management reference values for the number of foreign particles, respectively. If more foreign particles are detected than the threshold values, the wafer is diagnosed as abnormal. Is shown. That is, in FIG. 9A, it is determined that the peak value 1004 around the inspection time point A indicates abnormality.
[0058]
However, although it is presumed that some abnormality has occurred only with the statistics in FIG. 9A, it is difficult to investigate the cause.
[0059]
On the other hand, when the size of the foreign matter is managed according to the size by the inspection method of the present invention, a remarkable peak 1005 is seen at time A in FIG. 9C, and 2.8-3. It can be seen that foreign matters having a size of 0 [μm] are particularly concentrated. Therefore, figure 9 In (b), there is no part that exceeds the threshold, 9 In (c), the peak value 1005 has been detected, and for the reason shown in FIG. 5, the user is responsible for the extraneous matter that the pattern of this size on the wafer is peeled off during the etching process. Therefore, it is possible to quickly take effective countermeasures such as checking the etching apparatus.
[0060]
Next, figure 10 An example in which the cause of failure is displayed to the user will be described.
[0061]
The foreign matter or defect inspection apparatus according to the present invention has a function of analyzing the size of foreign matter and the number of detected foreign matters and displaying the cause of failure to the user.
[0062]
For example, it is assumed that the failure cause listed in FIG. 5C is taken as a model, and the result of the inspection shown in the graph of FIG. 7 is obtained. Further, it is assumed that the section from d to e in FIG. 5 corresponds to 2.8 μm to 3.0 μm in FIG. Therefore, when the test results shown in FIG. 10 The screen shown in is displayed and the analysis result of the cause of failure is clearly indicated to the user.
[0063]
[Inspection of foreign matter by area and analysis of cause of failure]
Next, an example in which foreign matter data is managed for each region on a wafer and countermeasures against defects are performed with the foreign matter or defect inspection apparatus of the present invention will be described with reference to FIGS.
FIG. 11 is a diagram schematically showing a region of a semiconductor wafer.
FIG. 12 is a schematic diagram explicitly showing a foreign substance having a specific size on the wafer when the foreign substance data is managed for each region.
FIG. 13 and FIG. 14 are graphs showing the number of detected foreign substances by area and by area.
[0064]
In general, when a chip pattern is formed on a semiconductor wafer, the pattern is not necessarily formed uniformly, and the pattern formation density may be high or low. For example, if the chip shown in FIG. 11 is a microprocessor, the area 1101 can be divided into a memory cell circuit portion, the area 1102 can be divided into a data input / output circuit portion, and the area 1103 can be divided into a portion without a circuit pattern. ing. Usually, these areas 1101, 1102, and 1103 have different circuit pattern integration degrees. Therefore, as a result, the size of the foreign matter that causes the defect also differs in each region. That is, the size of the foreign matter to be managed and analyzed differs depending on the area in the chip. More specifically, for example, in the area 1101, a foreign object having a size α or more is defective, in the region 1102, a foreign object having a size β or more, and in the area 1103, a foreign object having a size γ or more is defective. In this case, the area information and the size information of the defective foreign matter are given in advance to the inspection apparatus as management data. The method for inputting the region information and the size information of the defective foreign matter may be directly input by providing a screen for inputting the coordinate value or the size of the foreign matter in the inspection apparatus, or the optical image of the wafer may be input by a TV camera or the like. An area may be selected from the input image. Further, data may be downloaded from the host system, or data may be read into the inspection device from a removable storage medium, for example, a floppy disk.
[0065]
As described above, the inspection apparatus is inspected by providing the inspection apparatus with information on the size of the foreign substance to be determined as a region and a defect. Then, the region is determined based on the position information of the detected foreign matter in the inspection apparatus, and the size information of the detected foreign matter is compared with the size information of the foreign matter that is defective to determine whether or not the cause is defective.
[0066]
As a result, by changing the output display form of the foreign matter that has been determined to be the cause of failure and the foreign matter that has been determined not to be the cause of failure, the foreign matter that is causing the failure is clearly indicated to the user, so that the user can immediately determine the foreign matter that causes the failure. Can be seen.
[0067]
This technique is specifically shown as follows using FIG.
[0068]
The position of the detected foreign matter 1202 is shown and output on the wafer 1201 shown in FIG. Conventionally, since the detection result is as shown in FIG. 12A, in order to analyze the cause of the defect, a foreign object is appropriately selected and the foreign object is analyzed. Therefore, the probability of selecting a foreign substance to be truly analyzed is low, and it takes time to analyze the cause of the defect. However, as shown in FIG. 12B using the previous determination, the foreign matter determined to cause the defect, that is, the foreign matter to be analyzed from the detected foreign matters by changing the display of the foreign matter 1203 to be analyzed. It becomes easy to select 1203, the probability that a foreign object to be analyzed can be selected increases, and the cause of the defect can be quickly analyzed. In FIG. 11, as a method of changing the display, the display pattern is changed, but the color and size of the display pattern may be changed. Further, only the foreign matter that causes the failure may be displayed. Further, in this embodiment, the area is divided in the chip as the area division, but this is divided into areas in the wafer surface, for example, the area is divided and managed according to the distance from the wafer center to the wafer edge. The size of the foreign material may be changed. Further, the layout of the semiconductor chip may be displayed on the wafer shape 1201.
[0069]
Next, a method of grasping the number of detected foreign matters for each region and taking countermeasures against defects will be described with reference to FIGS.
[0070]
In this example, one wafer is classified into three regions. Assume that the areas are areas A, B, and C, and the number of foreign objects is detected for each area. Then, the result is displayed to the user as a graph for each region.
[0071]
For example, as shown in FIG. 13, the horizontal axis indicates the size of a foreign object, the vertical axis indicates the number of detected foreign objects, and the areas A, B, and C are color-coded to determine the size of the foreign object. Display them in a graph so that they are arranged horizontally for each category.
[0072]
Further, as shown in FIG. 14, the graphs may be displayed so as to be arranged vertically for each category of the size of the foreign matter.
[0073]
Specifically, for example, in the case of a semiconductor wafer, the three regions are three regions including a memory cell circuit portion, a circuit portion other than the memory cell circuit, and a portion without a circuit pattern. By displaying as shown in FIG. 13 and FIG. 14, it becomes easy to manage foreign substances by region. Here, the region information can be input directly by providing a screen for inputting the coordinate value and the size of the foreign substance in the inspection apparatus, or the region image can be input from an image input by a TV camera or the like. You may make it select. Data may be downloaded from the host system, or data may be read into the inspection device from a removable storage medium such as a floppy disk.
[0074]
Now, a method for finding a defective product by counting the number of detected foreign particles for each area will be described.
[0075]
As described above, the size of a foreign object that is determined to be defective is different for each region. In some areas, it is not a very fine circuit, so even if there is a relatively large foreign object, it will not be regarded as defective. In some areas, it is a fine circuit, and even a relatively small foreign object may cause trouble. . Thus, the threshold value for issuing a warning for each area is set to α, β, γ for each of the areas A, B, and C.
For example, in the example shown in FIGS.
[0076]
[Expression 2]
α = 1.0 [μm]
β = 1.6 [μm]
γ = 2.0 [μm]
Suppose that
[0077]
According to this, the sum of the number of detected foreign objects having a size exceeding the threshold value for each region is as follows.
[0078]
Area A ... 24
Area B ... 3
Area C ... 1 piece
Therefore, apparently, the foreign matter detected in the region C is very large, but they do not affect the quality of the product so much. However, the probability of affecting the quality of the product is high, so it can be said that there is a high probability of being judged as a defective product due to the foreign matter adhering to the region A. In this way, a threshold value that is regarded as a foreign object defect is provided for each region, the total number of detected foreign objects exceeding the threshold value is determined, the quality of the object to be inspected is determined as good and defective, and this is displayed to the user. This makes it possible to perform a reasonable inspection according to the characteristics of the region.
[0079]
[Optical system of foreign matter or defect inspection equipment]
As described above, in the description of the present invention, the optical system of the foreign matter or defect inspection apparatus has been described for detecting foreign matter using scattered light and measuring the size thereof. The present invention is applicable even if the system is a reflected light that detects a foreign substance and measures its size. In general, those using scattered light have good inspection efficiency, but measurement accuracy is difficult, and those using reflected light are vice versa, while inspection efficiency is poor, but measurement accuracy is excellent. The technique of the present invention is applicable to both.
[0080]
【The invention's effect】
According to the present invention, inspection and defect analysis of a semiconductor wafer or thin film substrate in the manufacturing process and defect analysis can be quickly performed by performing inspection and defect analysis in accordance with the characteristics of foreign matter and patterns and the characteristics of the region of the inspection object. It is possible to provide a foreign matter or defect inspection apparatus and a foreign matter or defect inspection method capable of taking various countermeasures against defects.
[Brief description of the drawings]
FIG. 1 is a diagram showing a configuration of a foreign matter or defect inspection apparatus according to the present invention.
FIG. 2 is a block diagram when the foreign matter or defect inspection apparatus according to the present invention is operated as a system.
FIG. 3 is a diagram showing image data when there is a foreign substance, and a diagram showing a signal intensity distribution when the foreign substance data is measured.
FIG. 4 is a diagram comparing two types of signal intensity distributions and an explanatory diagram for obtaining a maximum value of the signal intensity.
FIG. 5 is a diagram showing that the relationship between the size of foreign matter and the number of occurrences varies depending on the cause of failure.
FIG. 6 is a line graph showing the number of detected foreign objects and the size of the foreign objects.
FIG. 7 is a diagram showing the number of detected foreign objects and the size of foreign objects in a histogram.
FIG. 8 is a schematic diagram explicitly showing a foreign substance having a specific size on a wafer.
FIG. 9 is a graph showing the transition of the number of detections for each size of a specific foreign object in time series.
FIG. 10 is a diagram of a screen for displaying a cause of a defect in which a foreign object has occurred to a user.
FIG. 11 is a diagram schematically showing a region of a semiconductor wafer.
FIG. 12 is a schematic diagram explicitly showing a foreign substance having a specific size on a wafer when foreign substance data is managed for each region.
FIG. 13 is a diagram showing a graph displaying the number of detected foreign substances according to area size (part 1);
FIG. 14 is a diagram showing a graph displaying the number of detected foreign matters according to region size (Part 2).
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 101 ... Illumination optical system, 102 ... Test object, 103 ... Detection optical system, 104 ... Light detection part, 105 ... Signal processing circuit, 106 ... Data display part, 107 ... Stage part, 108 ... Auto-focus illumination part, 109 ... Autofocus light receiver.
201 ... Foreign matter data, 202 ... Waveform of foreign matter data 201.
301: Maximum value of signal strength of foreign matter data 302: Saturated region of signal strength of foreign matter data 303: Saturation level of signal strength 304: Unsaturated data of signal strength of foreign matter data
401, 402, 403 ... Foreign matter distribution area.
501: Number of detected foreign matters by size, 502: Graph connecting the detected numbers 501.
601: A graph showing the number of detected foreign matters.
701: External shape of a semiconductor wafer, 702: Detected foreign matter, 703: Foreign matter of a specific size.
1001, 1002, 1003, management threshold, 1004, 1005, abnormality exceeding the management threshold.
1101, 1102, 1103... Area in the chip.
1201 ... Semiconductor wafer, 1202 ... Detected foreign matter, 1201 ... Foreign matter to be analyzed on the detection result.
1301 ... Foreign matter inspection device, 1302 ... Data server, 1303 ... Review device, 1304 ... Electrical test device, 1305 ... Analytical device, 1306 ... Network connecting each device.

Claims (14)

In a foreign object or defect inspection device that measures an object to be inspected by an optical method and detects a foreign object or a defect,
Illuminating means for irradiating the object to be inspected with light;
A light detecting means for detecting reflected light or scattered light from the inspection object;
Detection means for detecting a foreign object or a defect based on the signal detected by the light detection means;
The peak level of the waveform of the signal detected by the light detection means is saturated when the X and Y axes are defined as coordinate axes for determining the position in the image obtained from the signal detected by the light detection means . the portion with the X, information of each peak level of the detected signal waveforms by calculating the peak level from the signal information of the portion not saturated on the basis of the information in the Y-axis direction of the cross-sectional shape of the saturation region Dimensional measuring means for measuring the size of foreign matter or defects;
Data processing means for processing the results of the inspection;
Means for displaying the result information of the examination,
The foreign matter characterized in that the size of the foreign matter or the defect is associated with the cause of the failure, the data processing means indicates the cause of the failure from the statistical processing of the inspection result, and is displayed on the means for displaying the inspection result information. Or defect inspection equipment. In a foreign object or defect inspection device that measures an object to be inspected by an optical method and detects a foreign object or a defect,
Illuminating means for irradiating the object to be inspected with light;
A light detecting means for detecting reflected light or scattered light from the inspection object;
Detection means for detecting a foreign object or a defect based on the signal detected by the light detection means;
The peak level of the waveform of the signal detected by the light detection means is saturated when the X and Y axes are defined as coordinate axes for determining the position in the image obtained from the signal detected by the light detection means . the portion with the X, information of each peak level of the detected signal waveforms by calculating the peak level from the signal information of the portion not saturated on the basis of the information in the Y-axis direction of the cross-sectional shape of the saturation region Dimensional measuring means for measuring the size of foreign matter or defects;
Data processing means for processing the results of the inspection;
Means for displaying the result information of the examination,
A foreign matter or defect inspection apparatus, wherein the frequency distribution display of the size of the foreign matter or defect obtained by the dimension measuring means is displayed on the means for displaying the inspection result information. In a foreign object or defect inspection device that measures an object to be inspected by an optical method and detects a foreign object or a defect,
Illuminating means for irradiating the object to be inspected with light;
A light detecting means for detecting reflected light or scattered light from the inspection object;
Detection means for detecting a foreign object or a defect based on the signal detected by the light detection means;
The peak level of the waveform of the signal detected by the light detection means is saturated when the X and Y axes are defined as coordinate axes for determining the position in the image obtained from the signal detected by the light detection means . the portion with the X, information of each peak level of the detected signal waveforms by calculating the peak level from the signal information of the portion not saturated on the basis of the information in the Y-axis direction of the cross-sectional shape of the saturation region Dimensional measuring means for measuring the size of foreign matter or defects;
Data processing means for processing the results of the inspection;
Means for displaying the result information of the examination,
A foreign matter or defect inspection apparatus characterized in that, on the means for displaying the inspection result information, a foreign matter or defect having a specific size is displayed separately from other foreign matter or defect. In a foreign object or defect inspection device that measures an object to be inspected by an optical method and detects a foreign object or a defect,
Illuminating means for irradiating the object to be inspected with light;
A light detecting means for detecting reflected light or scattered light from the inspection object;
Detection means for detecting a foreign object or a defect based on the signal detected by the light detection means;
The peak level of the waveform of the signal detected by the light detection means is saturated when the X and Y axes are defined as coordinate axes for determining the position in the image obtained from the signal detected by the light detection means . the portion with the X, information of each peak level of the detected signal waveforms by calculating the peak level from the signal information of the portion not saturated on the basis of the information in the Y-axis direction of the cross-sectional shape of the saturation region Dimensional measuring means for measuring the size of foreign matter or defects;
Data processing means for processing the results of the inspection;
Means for displaying the result information of the examination,
Management information is provided for each area of the inspection object, and the quality of each area of the inspection object is evaluated by comparing the management information with the size of the foreign matter or defect detected from the area. Thus, a foreign matter or defect inspection apparatus capable of performing defect analysis for each region.   5. The foreign matter or defect inspection apparatus according to claim 4, wherein a foreign matter or defect having a specific size is displayed for each region by distinguishing it from other foreign matter or defect based on the result of the evaluation. In a foreign object or defect inspection device that measures an object to be inspected by an optical method and detects a foreign object or a defect,
Illuminating means for irradiating the object to be inspected with light;
A light detecting means for detecting reflected light or scattered light from the inspection object;
Detection means for detecting a foreign object or a defect based on the signal detected by the light detection means;
The peak level of the waveform of the signal detected by the light detection means is saturated when the X and Y axes are defined as coordinate axes for determining the position in the image obtained from the signal detected by the light detection means . the portion with the X, information of each peak level of the detected signal waveforms by calculating the peak level from the signal information of the portion not saturated on the basis of the information in the Y-axis direction of the cross-sectional shape of the saturation region Dimensional measuring means for measuring the size of foreign matter or defects;
Data processing means for processing the results of the inspection;
Means for displaying the result information of the examination,
The object to be inspected is managed for each area, and as a means for displaying the result information of the inspection, the frequency distribution display of the size of the foreign matter or defect obtained by the dimension measuring means is performed for each area. Foreign matter or defect inspection device characterized by   The light source for detecting a foreign matter or a defect and the light source for measuring the size of the foreign matter or the defect in the illumination means are the same light source. Foreign matter or defect inspection equipment. In a foreign matter or defect inspection method for measuring an object to be inspected by an optical method and detecting foreign matter or a defect,
Irradiating the object to be inspected with light; and
A procedure for detecting reflected or scattered light from the object to be inspected;
A procedure for detecting a foreign object or defect based on the detected signal;
Wherein X of said the portions in which the peak level of the waveform of the detected signal is saturated saturation region when you defined X, the Y-axis as coordinate axes for defining the position in the images obtained by the detected signal, By calculating the peak level from the signal information of the portion not saturated based on the cross-sectional shape information in the Y- axis direction, the size of the foreign matter or defect is measured using the information on each peak level of the detected signal waveform. Procedure and
A data processing procedure for processing the results of the inspection;
Follow the procedure to display the inspection result information in this order,
A foreign matter or defect inspection method characterized by correlating the size of a foreign matter or defect with a cause of failure, pointing out the cause of failure from statistical processing of the result of inspection in the data processing procedure, and displaying the result information of the inspection . In a foreign matter or defect inspection method for measuring an object to be inspected by an optical method and detecting foreign matter or a defect,
Irradiating the object to be inspected with light; and
A procedure for detecting reflected or scattered light from the object to be inspected;
A procedure for detecting a foreign object or defect based on the detected signal;
Wherein X of said the portions in which the peak level of the waveform of the detected signal is saturated saturation region when you defined X, the Y-axis as coordinate axes for defining the position in the images obtained by the detected signal, By calculating the peak level from the signal information of the portion not saturated based on the cross-sectional shape information in the Y- axis direction, the size of the foreign matter or defect is measured using the information on each peak level of the detected signal waveform. Procedure and
A data processing procedure for processing the results of the inspection;
Follow the procedure to display the inspection result information in this order,
A foreign matter or defect inspection method characterized by displaying a frequency distribution of the size of a foreign matter or defect obtained by the procedure for measuring the dimensions when displaying the inspection result information. In a foreign matter or defect inspection method for measuring an object to be inspected by an optical method and detecting foreign matter or a defect,
Irradiating the object to be inspected with light; and
A procedure for detecting reflected or scattered light from the object to be inspected;
A procedure for detecting a foreign object or defect based on the detected signal;
For the portion where the peak level of the waveform of the detected signal is saturated, the waveform of the detected signal is defined when the X and Y axes are defined as coordinate axes for determining the position in the image obtained by the detected signal . wherein X, of the detected signal waveforms by calculating the peak level from the signal information of the portion not saturated on the basis of the information in the Y-axis direction of the cross-sectional shape of the saturation region for the portion where the peak level is saturated in A procedure to measure the size of a foreign object or defect using information at each peak level;
A data processing procedure for processing the results of the inspection;
Follow the procedure to display the inspection result information in this order,
A foreign matter or defect inspection method, wherein when displaying the inspection result information, a foreign matter or defect having a specific size is displayed by being distinguished from another foreign matter or defect. In a foreign matter or defect inspection method for measuring an object to be inspected by an optical method and detecting foreign matter or a defect,
Irradiating the object to be inspected with light; and
A procedure for detecting reflected or scattered light from the object to be inspected;
A procedure for detecting a foreign object or defect based on the detected signal;
Wherein X of said the portions in which the peak level of the waveform of the detected signal is saturated saturation region when you defined X, the Y-axis as coordinate axes for defining the position in the images obtained by the detected signal, By calculating the peak level from the signal information of the portion not saturated based on the cross-sectional shape information in the Y- axis direction, the size of the foreign matter or defect is measured using the information on each peak level of the detected signal waveform. Procedure and
A data processing procedure for processing the results of the inspection;
Follow the procedure to display the inspection result information in this order,
Management information is provided for each area of the inspection object, and the quality of each area of the inspection object is evaluated by comparing the management information with the size of the foreign matter or defect detected from the area. A foreign matter or defect inspection method characterized in that a failure analysis can be performed for each region. 12. The foreign matter or defect inspection method according to claim 11 , wherein a foreign matter or defect having a specific size is displayed for each region by distinguishing it from other foreign matter or defect based on the result of the evaluation. In a foreign matter or defect inspection method for measuring an object to be inspected by an optical method and detecting foreign matter or a defect,
Irradiating the object to be inspected with light; and
A procedure for detecting reflected or scattered light from the object to be inspected;
A procedure for detecting a foreign object or defect based on the detected signal;
Wherein X of said the portions in which the peak level of the waveform of the detected signal is saturated saturation region when you defined X, the Y-axis as coordinate axes for defining the position in the images obtained by the detected signal, By calculating the peak level from the signal information of the portion not saturated based on the cross-sectional shape information in the Y- axis direction, the size of the foreign matter or defect is measured using the information on each peak level of the detected signal waveform. Procedure and
A data processing procedure for processing the results of the inspection;
Follow the procedure to display the inspection result information in this order,
The inspection object is managed for each area, and when displaying the inspection result information, the frequency distribution display of the size of the foreign matter or defect obtained by the procedure of measuring the dimensions for each area is displayed. A foreign matter or defect inspection method, which is performed for each region. In the procedure of the lighting, for detecting foreign objects or defective light source, the foreign substance or a defect and the light source in order to measure the magnitude of the claims 8 to 13, wherein the identical light source Any foreign or defect inspection method.

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