TW202328665A - Method for analyzing defect - Google Patents

Abstract

A method for analyzing defect is provided, which is suitable for using an electronic apparatus to perform the following steps. A detected layout is divided into a plurality of straight blocks in equal parts along a horizontal direction, and the number of first defect points in each straight block is calculated. In addition, the detected layout is divided into a plurality of horizontal blocks in equal parts along a vertical direction, and the number of second defect points in each horizontal block is calculated. When at least one of the following predetermined conditions is satisfied, it is determined that the detected layout has a defect cluster. The predetermined conditions include: the number of first defect points in at least one straight block is greater than a first preset value; and the number of second defect points in at least one horizontal block is greater than a second preset value.

Description

Methods for Analyzing Defects

The present invention relates to a panel inspection method, and in particular to a defect analysis method.

Most thin film transistor liquid crystal display (TFT-LCD) manufacturers will use layer-by-layer defect inspection (Defect Inspection) to find defective panels in real time. Most of the detection methods are to use automatic scanning and photographing for comparison through the inspection machine, so as to find out the problematic panels. Therefore, these defect detection processes will generate a large amount of defect information and defect image files.

After the defects are detected by the machine, it is necessary for the yield technician to manually judge whether there are defect clusters in the defect information and defect image files. Since yield technicians have to check the test results of more than 150 production batches every day, and need to inspect and judge defect clusters for each production batch and each panel, when determining abnormalities with defect clusters, they will be notified manually. Manual judgment will result in different judgment results due to inconsistencies in standards, and may cause missed inspections due to factors such as fatigue, which will affect factory production capacity, yield, and cost.

The invention provides a method for analyzing defects, which can improve the problems of poor efficiency in the past.

The defect analysis method of the present invention is suitable for using an electronic device to perform the following steps, including: dividing the detection layout (Layout) into multiple straight blocks along the horizontal direction, and calculating the The number of first defect points; along the vertical direction, divide the detection layout into multiple horizontal blocks, and calculate the second defect points of each horizontal block; and when at least one of the following conditions is met In the case where it is determined that the detection layout has a defect cluster, the specified conditions include: the first defect point number of at least one vertical block is greater than the first preset value; and the second defect point number of at least one horizontal block is greater than Second default value.

In an embodiment of the present invention, the above-mentioned method for analyzing defects further includes: calculating the first defect ratio of each bar block in the inspection layout based on the first number of defect points and the total number of defect points in the inspection layout; and The second defect ratio of each bar block in the detection layout (Layout) is calculated by using the second defect points and the total defect points of the detection layout. The prescribed conditions further include: the first defect ratio of at least one vertical block is greater than the first monolithic ratio; and the second defect ratio of at least one horizontal block is greater than the second monolithic ratio.

In an embodiment of the present invention, the above-mentioned inspection layout is obtained after one of the plurality of test items received from the defect inspection machine undergoes defect inspection, and the test items belong to the same production batch.

In an embodiment of the present invention, the above method for analyzing defects further includes: calculating the batch defect sum of all defect points obtained after the defect detection of the production batch; , calculate the vertical area ratio of each vertical block in the production batch; and calculate the horizontal area ratio of each horizontal block based on the second defect points and the total number of batch defects. The prescribed conditions further include: the proportion of the vertical area of at least one straight block is greater than the proportion of the first batch; and the proportion of the horizontal area of at least one horizontal block is greater than the proportion of the second batch.

In an embodiment of the present invention, after calculating the batch defect sum of all defect points obtained after the defect detection of the production batch, it further includes: when the batch defect sum is greater than the first reference quantity , calculate the proportion of single-chip defects in the inspection layout based on the total number of batch defects and the total number of defect points in the inspection layout. The prescribed conditions further include: the total number of defect points is greater than or equal to a first set value, and the proportion of single-chip defects is greater than or equal to a second set value.

In an embodiment of the present invention, the above-mentioned method for analyzing defects further includes: when the total number of batch defects is greater than a second reference quantity, the specified condition further includes: the vertical area of at least one straight block occupies The ratio is greater than the proportion of the first batch, wherein the number of straight blocks is 3; when the total number of batch defects is greater than the third benchmark number, the specified conditions further include: at least one horizontal block The proportion of the horizontal area is greater than the proportion of the second batch, wherein the number of horizontal stripe blocks is 3.

In an embodiment of the present invention, after determining that the detection layout has a defective cluster, it further includes: recording a corresponding cluster label for the specified condition met.

In an embodiment of the present invention, after determining that the detection layout has defect clusters, it further includes: generating an abnormal notification for the production batches with defect clusters.

Based on the above, this disclosure groups the defect coordinates in the horizontal direction and vertical direction, and calculates the number and proportion of each group, and the corresponding threshold value, so as to perform linear detection in the horizontal direction and linear detection in the vertical direction. Accordingly, the judgment of defect clusters is automated to improve past inefficiencies.

FIG. 1 is a block diagram of an electronic device for analyzing defects according to an embodiment of the invention. Referring to FIG. 1 , the electronic device 100 receives station inspection data D to analyze defects. The electronic device 100 includes a processor 110 and a storage unit 120 . The processor 110 is coupled to the storage unit 120 . The machine inspection data D is generated by the defect inspection machine, and includes defect information and defect coordinate data obtained after defect inspection of multiple DUTs belonging to the same production batch.

The processor 110 is, for example, a central processing unit (Central Processing Unit, CPU), a physical processing unit (Physics Processing Unit, PPU), a programmable microprocessor (Microprocessor), an embedded control chip, a digital signal processor (Digital Signal Processor) Processor, DSP), Application Specific Integrated Circuits (Application Specific Integrated Circuits, ASIC) or other similar devices.

The storage unit 120 is, for example, any type of fixed or removable random access memory (Random Access Memory, RAM), read-only memory (Read-Only Memory, ROM), flash memory (Flash memory), hard Disc or other similar device or combination of these devices. The storage unit 120 includes one or more code fragments. After the above code fragments are installed, the processor 110 will execute the following defect analysis method.

FIG. 2 is a flowchart of a method for analyzing defects according to an embodiment of the present invention. Please refer to FIG. 1 and FIG. 2 , after the electronic device 100 receives the machine inspection data D, the processor 110 can analyze the machine inspection data D to determine whether there is a cluster of defects on each panel. The machine inspection data D includes defect information and defect coordinate data corresponding to each batch and each panel. The processor 110 can take out the detection layout (Layout) corresponding to each panel one by one for multiple defect coordinate data of the same production batch.

In step S205, along the horizontal direction, the detection layout is equally divided into a plurality of straight blocks, and the number of first defect points of each straight block is calculated. Moreover, in step S210, along the vertical direction, the detection layout is equally divided into a plurality of horizontal stripe blocks, and the second number of defect points of each horizontal stripe block is calculated. Here, the execution sequence of step S205 and step S210 is not limited, for example, step S205 may be executed first, or step S210 may be executed first, and step S205 and step S210 may also be executed simultaneously.

In one embodiment, the detection layout can be divided into a plurality of vertical strip areas and a plurality of horizontal strip blocks at intervals of a specified length in the horizontal direction and the vertical direction, respectively, as shown in FIG. 3A and FIG. 3B . 3A and 3B are schematic diagrams of equal division according to an embodiment of the present invention. In another embodiment, the detection layout is also divided into three vertical regions and three horizontal regions every other in the horizontal direction and the vertical direction, respectively, as shown in FIGS. 4A and 4B . 4A and 4B are schematic diagrams of equal division according to another embodiment of the present invention.

After the division, the number of first defect points and the number of second defect points are respectively calculated for the divided vertical and horizontal regions. Afterwards, in step S215, when a predetermined condition is satisfied, it is determined that the detection layout has a defect cluster. The prescribed conditions include at least one of the following conditions: the first defect point count of at least one vertical block is greater than a first preset value; the second defect point count of at least one horizontal block is greater than a second preset value.

Taking Fig. 3A and Fig. 3B as an example, it is assumed that the detection layout is divided into n straight blocks and n horizontal blocks along the horizontal direction and vertical direction at intervals of length (for example, 1 mm), and each The first number of defect points x _i (i=1~n) included in a vertical block and the second number of defect points y _i (i=1~n) included in each horizontal block. Next, compare the first defect point number _xi with the first preset value T1, and compare the second defect point number y _i with the second preset value T2. Furthermore, the following conditions are further set: x _i >T1 (condition 1); y _i >T2 (condition 2). In one embodiment, the first preset value and the second preset value can be set to 25 pieces.

In addition, the first defect ratio _{ratio_xi} (= _xi /total number of defect points) of each bar block in the detection layout can be further calculated based on the first defect points x _i and the total defect points of the detection layout ; Calculate the second defect ratio ratio_y _i (=y _i /total defect points) of each bar block in the detection layout based on the second defect points and the total defect points of the detection layout. Moreover, the specified conditions further include: the first defect ratio _{ratio_xi} of at least one vertical block is greater than the first monolithic ratio T _r1 ; and the second defect ratio ratio_y _i of at least one horizontal block is greater than the first The ratio of the second monolithic chip is T _r2 . That is, _{ratio_xi} >T _r1 (condition 3); ratio_y _i >T _r2 (condition 4).

That is, in the defect analysis of the present disclosure, it can be further judged whether the ratio of the first defect points of the straight block to the total defect points of the single sheet (the first defect ratio) is greater than the first proportion of defects. Or, it is further judged whether the ratio of the second defect points of the horizontal stripe block to the total defect points of the single chip (the second defect ratio) is greater than the second defect ratio.

In one embodiment, the first preset value and the second preset value can be set to 30 pieces, and the first defect ratio and the second defect ratio can be set to 30%. It is possible to further find the straight blocks with _xi greater than 30 and _{ratio_xi} greater than 30%; or further find the horizontal blocks with y _i greater than 30 and _{ratio_y} greater than 30%. Or, in other embodiments, it may be further set as: when the total number of defect points is greater than 42, find out horizontal stripe blocks with y _i ≥ 20 and ratio_y _i ≥ 30%.

The conditions 1 to 4 are used to find out the defect clusters of a single panel, and the defect clusters can be further found for the same production batch. In order to find out the defect clusters of production batches, the image can be divided into three vertical blocks of left, middle and right in the horizontal direction, and divided into three horizontal blocks of upper, middle and lower in the vertical direction for analysis , can refer to FIG. 4A and FIG. 4B.

First, the batch defect sum of all defect points obtained after defect detection of all panels of the same production batch is calculated. When the total number of batch defects is greater than the first benchmark quantity, calculate the proportion of single-chip defects in the inspection layout based on the total number of batch defects and the total number of defect points in the inspection layout (total number of defect points/total number of batch defects ). The prescribed conditions further include: the total number of defect points is greater than or equal to a first set value, and the proportion of single-chip defects is greater than or equal to a second set value (condition 5).

For example, the first base quantity is 36 pieces, the first set value is 27 pieces, and the second set value is 23%. When the total number of batch defects is greater than 36, find out the images corresponding to panels with a total defect number greater than 27 and a single-chip defect ratio greater than or equal to 23%.

In addition, based on the number of first defect points x _i (i=1~3) and the total number of batch defects, calculate the vertical area ratio S _{ratio _xi} (= _xi / batch Secondary defect total); and calculate the horizontal area ratio S _ratio _y _i (=y _{i /} total batch defects). The prescribed conditions further include: the vertical area ratio of at least one straight block is larger than the first batch ratio Tlot _r1 ; and the horizontal area ratio of at least one horizontal block is larger than the second batch ratio Tlot _r2 . That is, S _{ratio _xi} > Tlot _r1 (condition 6); S _ratio _y _i > Tlot _r2 (condition 7). In addition, it can be further set as follows: when the total number of batch defects is greater than the second reference quantity, judge condition 6; when the total batch defects are greater than the third reference quantity, judge condition 7.

For example, in condition 6, the second benchmark quantity is set to 22 pieces, and the first batch accounts for Tlot _r1 as 65%. When the total number of defects in the batch is greater than 22, find the straight block whose vertical area accounts for more than 65%. In condition 7, set the third benchmark quantity as 21 pieces, and the second batch accounts for Tlot _r2 as 80%. When the total number of defects in the batch is greater than 21, find out the horizontal stripe block whose horizontal area accounts for more than 80%.

In addition, in another embodiment, it can also be set as follows: first use condition 1 and condition 2 to judge the defect cluster of a single panel, and then analyze the defect cluster area of the production batch after it is determined to be a defect cluster .

After it is determined that the detection layout has a defect cluster, the corresponding cluster label is further recorded for the satisfied specified condition. For example, a record tag is set, which includes 5 record bits, ie (B1, B2, B3, B4, B5). The recording bits B1-B4 are respectively used to record whether the conditions 1-4 are satisfied, "0" means not satisfied, and "1" means satisfied. In addition, the record bit B5 is used to record whether the conditions 5-7 are met, "0" means that none of the conditions 5-7 are met, "1" means that one of the conditions 5-7 is met, and "2" means that the conditions 5-7 are met Two of them, "3" means that all conditions 5 to 7 are met.

And, for production batches with defective clusters, exception notifications are generated. For example, when one of the recording bits B1-B5 is not 0, an exception notification is generated.

In an application example, the machine detection data D is used for cluster detection and image recognition detection by using the programming language Python. The cluster detection includes the methods mentioned in the above embodiments, and can be further combined with a DBSCAN (Density-based spatial clustering of applications with noise) algorithm. The image recognition detection uses the OpenCV (Open Source Computer Vision Library) suite. Afterwards, the detected results are stored in the data access server, and after obtaining the weighted calculated risk value, they are output to the interface through wired or wireless transmission for the user to implement decision-making basis.

To sum up, the present disclosure can perform horizontal linear detection and vertical linear detection on a single chip, and can further perform regional cluster ratio detection on the same production batch. Accordingly, the judgment of defect clusters is automated to improve past inefficiencies. In addition, abnormalities can be reported proactively, thereby improving the batch processing efficiency of precise focusing abnormalities and shortening time-consuming multi-platform operations.

100: Electronic device 110: Processor 120: storage unit D: Machine testing data S205～S215: Steps of analyzing defect method

FIG. 1 is a block diagram of an electronic device for analyzing defects according to an embodiment of the invention. FIG. 2 is a flowchart of a method for analyzing defects according to an embodiment of the present invention. 3A and 3B are schematic diagrams of equal division according to an embodiment of the present invention. 4A and 4B are schematic diagrams of equal division according to another embodiment of the present invention.

S205~S215: Steps of analyzing defect method

Claims (8)

A method for analyzing defects, adapted to use an electronic device to perform the following steps, comprising: Along a horizontal direction, a detection layout is equally divided into a plurality of vertical blocks, and a first defect point number of each of the vertical blocks is calculated; Along a vertical direction, the inspection layout is equally divided into a plurality of horizontal stripe blocks, and a second defect number of each of the horizontal stripe blocks is calculated; and In the case that at least one of the following specified conditions is met, it is determined that the detection layout has a defect cluster, and the specified conditions include: The first defect number of at least one of the straight blocks is greater than a first preset value; and The second defect point number of at least one of the horizontal stripe blocks is greater than a second preset value. The method for analyzing defects as described in Claim 1 further includes: calculating a first defect ratio of each of the straight blocks in the test layout by using the first defect count and a total defect count of the test layout; and calculating a second defect ratio of each of the horizontal stripe blocks in the detection layout by using the second defect count and the total defect count of the detection layout, Among them, the stated conditions further include: The first defect ratio of at least one of the straight blocks is greater than a first monolithic ratio; and The second defect ratio of at least one of the horizontal stripe blocks is greater than a second monolithic ratio. The method for analyzing defects as described in Claim 1, wherein the detection layout is obtained after one of a plurality of test items received from a defect detection machine undergoes defect detection, and these test items belong to the same production batch . The method for analyzing defects as described in Claim 3 further includes: Calculate the batch defect sum of all defect points obtained after the defect detection of the production batch; calculating a vertical area ratio of each of the straight blocks in the production batch by using the first defect points and the batch defect total; and Calculate a horizontal area ratio of each of the horizontal bars by using the second defect points and the total defect number of the batch, Among them, the stated conditions further include: The vertical area ratio of at least one of the straight blocks is greater than a first batch ratio; and The horizontal area ratio of at least one of the horizontal stripe blocks is greater than a second batch ratio. The method for analyzing defects as described in claim item 4, after calculating the batch defect sum of all defect points obtained after the defect detection of the production batch, it further includes: In the case that the total number of defects in the batch is greater than a first reference quantity, calculate a single-chip defect ratio of the inspection layout based on the total number of defects in the batch and a total number of defect points in the inspection layout; Wherein, the specified condition further includes: the total defect points are greater than or equal to a first set value, and the single-chip defect ratio is greater than or equal to a second set value. The method for analyzing defects as claimed in item 4, wherein, In the case that the total number of defects in the batch is greater than a second reference quantity, the specified condition further includes: the vertical area ratio of at least one of the straight blocks is greater than the first batch ratio, wherein the The number of straight blocks is 3; and In the case that the total number of defects in the batch is greater than a third reference quantity, the specified condition further includes: the proportion of the horizontal area of at least one of the horizontal stripe blocks is greater than the proportion of the second batch, wherein the The number of these horizontal bar blocks is 3. The method for analyzing defects as described in claim item 1, after determining that the detection layout has defect clusters, further includes: For the specified condition met, record the corresponding cluster label. The method for analyzing defects as described in claim item 1, after determining that the detection layout has defect clusters, further includes: For production batches with defective clusters, an exception notification is generated.

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