CN109636772A - The defect inspection method on the irregular shape intermetallic composite coating surface based on deep learning - Google Patents

The defect inspection method on the irregular shape intermetallic composite coating surface based on deep learning Download PDF

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CN109636772A
CN109636772A CN201811252083.8A CN201811252083A CN109636772A CN 109636772 A CN109636772 A CN 109636772A CN 201811252083 A CN201811252083 A CN 201811252083A CN 109636772 A CN109636772 A CN 109636772A
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deep learning
image
composite coating
coating surface
intermetallic composite
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陈启军
颜熠
王德明
周光亮
李树
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Tongji University
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    • GPHYSICS
    • G06COMPUTING OR CALCULATING; COUNTING
    • G06TIMAGE DATA PROCESSING OR GENERATION, IN GENERAL
    • G06T7/00Image analysis
    • G06T7/0002Inspection of images, e.g. flaw detection
    • G06T7/0004Industrial image inspection
    • GPHYSICS
    • G06COMPUTING OR CALCULATING; COUNTING
    • G06TIMAGE DATA PROCESSING OR GENERATION, IN GENERAL
    • G06T3/00Geometric image transformations in the plane of the image
    • G06T3/02Affine transformations
    • GPHYSICS
    • G06COMPUTING OR CALCULATING; COUNTING
    • G06TIMAGE DATA PROCESSING OR GENERATION, IN GENERAL
    • G06T7/00Image analysis
    • G06T7/10Segmentation; Edge detection
    • G06T7/13Edge detection
    • GPHYSICS
    • G06COMPUTING OR CALCULATING; COUNTING
    • G06TIMAGE DATA PROCESSING OR GENERATION, IN GENERAL
    • G06T7/00Image analysis
    • G06T7/10Segmentation; Edge detection
    • G06T7/187Segmentation; Edge detection involving region growing; involving region merging; involving connected component labelling
    • GPHYSICS
    • G06COMPUTING OR CALCULATING; COUNTING
    • G06TIMAGE DATA PROCESSING OR GENERATION, IN GENERAL
    • G06T2207/00Indexing scheme for image analysis or image enhancement
    • G06T2207/20Special algorithmic details
    • G06T2207/20021Dividing image into blocks, subimages or windows
    • GPHYSICS
    • G06COMPUTING OR CALCULATING; COUNTING
    • G06TIMAGE DATA PROCESSING OR GENERATION, IN GENERAL
    • G06T2207/00Indexing scheme for image analysis or image enhancement
    • G06T2207/20Special algorithmic details
    • G06T2207/20024Filtering details
    • GPHYSICS
    • G06COMPUTING OR CALCULATING; COUNTING
    • G06TIMAGE DATA PROCESSING OR GENERATION, IN GENERAL
    • G06T2207/00Indexing scheme for image analysis or image enhancement
    • G06T2207/20Special algorithmic details
    • G06T2207/20081Training; Learning
    • GPHYSICS
    • G06COMPUTING OR CALCULATING; COUNTING
    • G06TIMAGE DATA PROCESSING OR GENERATION, IN GENERAL
    • G06T2207/00Indexing scheme for image analysis or image enhancement
    • G06T2207/20Special algorithmic details
    • G06T2207/20084Artificial neural networks [ANN]
    • GPHYSICS
    • G06COMPUTING OR CALCULATING; COUNTING
    • G06TIMAGE DATA PROCESSING OR GENERATION, IN GENERAL
    • G06T2207/00Indexing scheme for image analysis or image enhancement
    • G06T2207/30Subject of image; Context of image processing
    • G06T2207/30108Industrial image inspection
    • G06T2207/30136Metal

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  • General Physics & Mathematics (AREA)
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  • Computer Vision & Pattern Recognition (AREA)
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Abstract

The defect inspection method on the present invention relates to a kind of irregular shape intermetallic composite coating surface based on deep learning, this method by being pre-processed to the intermetallic composite coating surface image of acquisition, image enhancement, the network architecture based on YOLOv3, the deep learning network suitable for defects detection is built, by carrying out handmarking to sample, the training of deep learning network is carried out using the sample of tape label, to obtain defects detection model, defects detection finally is carried out to collected intermetallic composite coating surface image using defects detection model, obtains the result of defects detection.Compared with prior art, the network architecture in the present invention has good adaptability for the detection of wisp Small object, within four basic steps unifications to the same depth network frame of candidate region generation, feature extraction, classification, position refine of target detection, the speed of service is improved, keeps detection more accurate.

Description

The defect inspection method on the irregular shape intermetallic composite coating surface based on deep learning
Technical field
The present invention relates to a kind of intermetallic composite coating detection method of surface flaw, more particularly, to it is a kind of based on deep learning not The defect inspection method on regular shape intermetallic composite coating surface.
Background technique
It is an essential process in metal works production and manufacture field, defects detection;Due to producing work at present The complexity of part structure carries out defects detection to a certain extent or by human resources.Mainstream is artificial in the prior art Visual detection mode not only inefficiency, and examination criteria subjective factor is big, affects the entire production line to a certain extent Automated process.In addition, the management to company human resource is also a kind of test with the continuous improvement of human cost.In recent years Coming, the automation defect inspection method based on machine vision is of interest by numerous researchers, also increasingly by the favor of manufacturer, But current methods detection accuracy is low and time-consuming, is not able to satisfy real-time detection demand, becomes and restricts machine substitution mankind's progress The principal element of defects detection.
Method used in the prior art and the test object being directed to all are not quite similar, and image source acquisition aspect includes using Laser sensor, ultrasonic sensor, electromagnetic sensor etc.;The object of detection generally compares the surface for being confined to certain objects, Such as metal decking, metal tube surface etc..For image, there are the diversity of shape edges on intermetallic composite coating surface, merely It is unsatisfactory that detection effect is carried out using traditional image processing method.And template is used for the finished surface of regular shape The robustness that matched method carries out defects detection is not strong, and to the more demanding of imaging circumstances, application scenarios are relatively fixed, For test object it is more single, there is limitation, and cannot classify well to the defect detected.In addition, right For intermetallic composite coating workpiece, the station of detection is more, and surface is also more complicated, and the prior art does not reach requirement and has higher The processing time, unsuitable real-time detecting system builds.Therefore to realize the promotion of productivity in addition to the precision in detection It is upper it is more demanding other than, also there is very high requirement to the time of detection processing.
Summary of the invention
It is an object of the present invention to overcome the above-mentioned drawbacks of the prior art and provide one kind to be based on deep learning Irregular shape intermetallic composite coating surface defect inspection method.
The purpose of the present invention can be achieved through the following technical solutions:
The defect inspection method on the irregular shape intermetallic composite coating surface based on deep learning, this method include following step It is rapid:
S1: the original image on acquisition irregular shape intermetallic composite coating surface.
S2: pre-processing collected original image, obtains ROI (region of interest, region of interest Domain).The step specifically includes:
201) piecemeal is numbered after being cut original image;
202) image after cutting is filtered and edge detection process;
203) Morphological scale-space is carried out to image, obtains multiple connected regions, connected region is marked and is classified, it is right Sorted connected region carries out the calculating of average pixel value;
204) average pixel value of calculating is judged, the highest connected region of selection average brightness, which is used as, to be needed to extract Feature detection zone;
205) the connected region degree of comparing of selection is enhanced, obtains ROI.
Preferably, the image after cutting is filtered using Gaussian filter.
Preferably, edge detection process is carried out to the image after cutting using Canny operator extraction method.
S3: using pretreated ROI as initial data set, the artificial mark of priori knowledge is carried out to initial data set, Each frames images is taken out into defect using rectangle frame, and marks actual defect classification, obtains the sample infused with defective collimation mark This.Then sample is expanded by data enhancing, using the sample after expansion as the data set of training network.
Data enhancing includes the one or more of following operation:
A. image is overturn, including flip horizontal and spun upside down;
B. Illumination adjusting is carried out to image, so that image becomes brighter or darker;
C. noise addition is carried out to image;
D. affine transformation, including translation, rotation, change of scale are carried out to image.
S4: deep learning detection network is built based on YOLOv3.Specific steps are as follows:
401) deep learning detection network is built using 53 layers of convolutional network, feature extraction is carried out to ROI;
402) feature of extraction is sent into classifier and returns device, obtain the size and location of defect;
402) each image is compared with the obtained result of device is returned with true value by classifier, according to comparing As a result the parameter of percentage regulation study detection network.
Preferably, residual error network knot is interspersed among the convolutional layer and pond layer of 53 layers of the convolutional network Structure.
S5: network is detected using the sample training deep learning of the defective collimation mark note of the enhanced band of data, obtains defect Detection model.
S6: the defects detection model that the acquisition image input training for being used to detect is obtained obtains defeated with rectangle box form Defective locations and confidence level out work back to the defective locations of output in original image according to the number of image, obtain original The defects of image position.
The data format of each rectangle frame includes the coordinate and rectangle frame of the coordinate of upper left corner angle point, lower right corner angle point Length and width.
Compared with prior art, the invention has the following advantages that
1, the present invention has carried out pretreatment, image enhancement to the image on the irregular shape intermetallic composite coating surface of acquisition, and Deep learning detection network is built based on YOLOv3 and carries out failure prediction, the candidate region of target detection is generated, feature mentions It takes, classify, within four basic steps unifications to the same depth network frame of position refine, all calculating do not repeat, greatly The speed of service is improved greatly;
2, the pretreatment that the present invention has carried out including subregion cutting, filtering processing, edge detection original image comes Prominent features detection zone is obtained, subregion cutting is exaggerated original image, increases the ratio of defect on the image, makes subsequent lack Sunken processing is more accurate;In addition, interference region is filtered by filtering processing, edge detection, reduce the processing of down-stream Amount, improves recall rate, reduces error rate;
3, the present invention enhances technology pair using the data for including the operations such as overturning, illumination variation, addition noise, affine transformation Training sample carries out data enhancing, has expanded the scale of data set, has solved the problems, such as the sample scarcity of actual production, and enhance The robustness and generalization ability of model;
4, the present invention uses deep learning frame, has broken traditional based on the manual extractions feature such as edge, profile, gray scale Detection method parameter setting puzzlement;In addition, each picture by classifier and is returned the obtained result of device and true Value is relatively adjusted the parameter of network, and the traditional method for manually adjusting parameter for the model ratio for obtaining training has more Strong robustness;
5, the present invention is realized using image variants to the defects detection on irregular shape intermetallic composite coating surface, is compared In the defects detection for manually carrying out workpiece, human cost is saved, production efficiency is improved;
6, the present invention builds deep learning detection network using YOLOv3 and carries out failure prediction, can be with by adjusting threshold value Detect different degrees of defect, suitable for multiplicity examination criteria, for different standards can by retraining to model into Row perfect, strong applicability and using flexible;
7, the present invention is based on the detection frameworks of YOLOv3, have built a set of deep learning net suitable for metal surface detection Network improves the rate of detection under the premise of guaranteeing defect detection accuracy, realizes real-time defects detection, further improve The efficiency of detection;
8, the present invention has very high real-time on the basis of realizing high-precision detection defect, can satisfy actual production Requirement of the middle defects detection production line to time and efficiency, is conducive to building for later period entire detection system.
Detailed description of the invention
Fig. 1 is the flow diagram of the method for the present invention;
Fig. 2 is the extraction flow chart of the characteristic area in the method for the present invention;
Fig. 3 is the schematic diagram of the bounding box prediction in YOLOv3.
Specific embodiment
The present invention is described in detail with specific embodiment below in conjunction with the accompanying drawings.
Embodiment
The defect inspection method on the present invention relates to a kind of irregular shape intermetallic composite coating surface based on deep learning is such as schemed Shown in 1, this method includes the following steps:
Step 1: the original image on acquisition irregular shape intermetallic composite coating surface.
Step 2: carrying out pretreatment to collected original image obtains ROI, and ROI is cut into the identical side of size Shape subgraph, to adapt to the input requirements of deep learning network.
Acquired image is the reflected image under same angle light source, but due to the profile and shape of metal surface to be measured Shape is not quite similar, so also will include the information on some non-surfaces to be measured sometimes.Therefore it needs to carry out centainly original image Pretreatment, prominent features detection zone and filters out interference region, and will treated that image carries out dimension normalization, it is unified deep Spend the input picture of network.On the one hand the treating capacity of down-stream can be reduced, detection speed is improved, on the other hand to extracting Region has carried out partial enlargement, and it is more prominent to make that there may be the positions of defect, i.e., defect characteristic is more prominent, for subsequent spy Sign extraction step is ready, and the final recall rate that improves reduces error rate.When carrying out the training of model using deep learning in this way The consistency that can guarantee background type and graphical rule, enables model preferably to restrain, and improves the accuracy of defects detection.
Acquired image region may include large-scale workpiece surface region and perimeter, and due to workpiece The profile on surface is different, and large-scale characteristic area extracts the accuracy that will affect extraction.Based on this, as shown in Fig. 2, of the invention Piecemeal is numbered after original image is cut first.By designing good imaging scheme, can make collected original Image has the differentiation of apparent background and prospect, wherein highlighted region is the intermetallic composite coating surface detected, The relatively clear protrusion of its profile.
It is then filtered, so that image is more smooth, while the distracter of dash area being desalinated.Filtering Method has many kinds, the preferred Gaussian filter of the present embodiment;Then edge detection is carried out to image, the edge inspection often occurred Measuring and calculating attached bag includes the first order differential operator including Robert operator, Sobel operator and the second order including Laplace operator is micro- Divide operator.The above operator mentions image edge detailss by the method completion of gray level image and a certain size mask convolution It takes, it is easy to accomplish, there is good real-time, but be easily disturbed by noise, it is easily lost edge details.The present invention uses Canny operator extraction edge.Canny edge detection algorithm be it is a kind of will optimize thought be applied to image procossing algorithm, with Conventional differential operator is compared, and not only possesses higher noise output ratio, also has quite reliable precision.
Edge is obtained later by carrying out the connected region that morphologic operation obtains multiple sealings to image, then to even Logical region is marked and classifies, and asks calculation to sorted connected region progress average pixel value, judges average brightness most The feature detection zone that high connected region as needs to extract.It can will be to be detected by choosing the connected region Workpiece surface region is split from original image, other connected domains directly fill black replacement, can greatly reduce background pair The interference of defect recognition.
Final step is connected region degree of the comparing enhancing to extraction.Between different piecemeals, due to the light of imaging Source problem may have different Luminance Distributions.Therefore the enhancing to degree of comparing in connected region is also needed, is lacked with prominent Sunken feature obtains ROI (region of interest, area-of-interest).The present invention selects histogram equalization, this method The enhancing to realize contrast is adjusted to gray value by using aggregation function." the middle thought of histogram equalization processing Think " it is that the grey level histogram of original image is become in whole tonal ranges uniform from some gray scale interval for comparing concentration Distribution.The defect details in the insufficient region of illumination can also be protruded in this way, while also can be thin by the defect for exposing excessive region Section highlights.
Step 3: carrying out handmarking to sample, the sample of tape label is obtained.
Using pretreated ROI as initial data set, need to carry out the mark of priori knowledge.For each input Its major defect progress frame is taken by rectangle frame, and marks actual defect classification by image.The data format of one template For the coordinate in the upper left corner and lower right corner angle point, respectively (x1, y1), (x2, y2), the length and width of rectangle frame.For each knowledge Other frame can all have corresponding label, the classification of the tag representation defect.
Step 4: carrying out data extending to initial data set using data enhancing technology, trained sample more abundant is obtained This.
To guarantee that model has very strong generalization ability, it is contemplated that the actually detected environment of metal processing piece in the factory, From scale, rotation, translation, illumination plus makes an uproar etc. data enhancing is carried out to image training sample.Particular content includes:
1, image is overturn, including flip horizontal and spun upside down.
2, Illumination adjusting is carried out to image, so that image becomes brighter or darker.
3, noise addition is carried out to image, the noise of the present embodiment addition is Gaussian noise.
4, affine transformation, including translation, rotation, change of scale are carried out to image.
It should be noted that above-mentioned data enhancement operations can be used in combination with each other, type available in this way is more, lacks Richer image data is fallen into, the training of model is conducive to.The identification frame wherein marked can keep opposite position with various transformation It sets constant, is equivalent to have obtained a greater variety of defect sample from the point of view of sample.
Step 5: building deep learning detection network based on YOLOv3.
One 53 layers of convolutional network (Darknet-53) has been used in deep learning frame of the invention, the network number of plies Increase, may make the performance enhancement of network, prediction effect is more preferable.During deep neural network is built, in convolutional layer and Residual error network structure is interted among the layer of pond, network number of plies increase can have been solved, the accuracy rate of training set is caused to be saturated even decline The problem of.
It is pre- that bounding box prediction uses dimension cluster (dimension clusters) to come as anchor point (anchor boxes) Bounding box is surveyed, the output of network is that each bounding box predicts 4 coordinates, and the meaning of 4 coordinates is respectively the central point predicted Horizontal, ordinate bx、byAnd the width b of bounding boxw, height bh, calculate as shown in Figure 3.cx、cyRespectively refer to the grid divided The distance in the ranks direction in the range image upper left corner unit (grid cell), pw、phRespectively refer to the width and height of priori bounding box Degree, σ () function refer to sigmoid function, high by the position of grid cell and the width of priori bounding box, calculate prediction side The center of boundary's frame and width, height.
YOLOv3 predicts the score of each bounding box using logistic regression.If the degree of overlapping of priori bounding box and true frame Will be good than any other bounding box before, then the value should be 1.If priori bounding box is not best, but really with The overlapping of real object is more than some threshold value (the present embodiment chooses 0.5), then ignores current prediction.YOLOv3 is only each true Object distributes a bounding box, if priori bounding box is misfitted with real object, will not generate coordinate or class prediction damage It loses, can only generate object prediction loss.
The YOLOv3 network architecture carries out prediction task from the characteristic spectrum of three kinds of different scales.It is obtained in Darknet-53 Characteristic pattern on the basis of, obtain first characteristic spectrum by 7 convolution, done on this characteristic spectrum for the first time predict. Then the output for obtaining 3rd convolutional layer reciprocal from back to front carries out x2 up-sampling of a convolution, will up-sampling feature with 43rd convolution feature connection, obtains second characteristic spectrum by 7 convolution, and second is done on this characteristic spectrum in advance It surveys.Then the output for obtaining the 3rd convolutional layer reciprocal from back to front carries out x2 up-sampling of a convolution, and up-sampling is special Sign is connect with the 26th convolution feature, obtains third characteristic spectrum by 7 convolution, and third time is done on this characteristic spectrum Prediction.The feature sizes that each prediction task obtains are N × N × [3* (4+1+80)], and N is grid size, and 3 be each grid Obtained bounding box quantity, 4 be bounding box coordinates quantity, and 1 is target prediction value, and 80 be categorical measure.
After carrying out feature extraction to ROI using 53 layers of convolutional networks, the feature extracted is sent into classifier and recurrence Device, wherein classifier effect is that judgement has whether the picture of a certain feature belongs to defect, and the effect for returning device is to judge certain The size of defect included by kind feature and position.Each picture by classifier and is returned into the obtained result of device and true Real value is compared, the parameter of adjustable network, to achieve the purpose that e-learning and evolution, finally make network output with it is true Value as close as.
The entire data set obtained after data enhancing is divided into training data and test data: will be in labeled data collection 80% be used as training dataset, 20% be used as validation data set.Trained parameter is adjusted simultaneously, in total the number of iterations It is set as 50000 times to be trained, GPU (Graphics Processing Unit, graphics processor) can be used to improve operation Rate.The data set of the tape label of building carries out the training of deep learning network as network inputs, obtains defects detection model, For carrying out defects detection to every tension position picture.
Step 6: carrying out defect inspection to collected intermetallic composite coating surface image using the defects detection model that training obtains It surveys, obtains the result of defects detection.
The defects detection model that the acquisition image input training for being used to detect is obtained.The position of defect is with rectangle frame (coordinate of rectangle upper left angle point and the length and width of rectangle frame) that form provides, then according to the number of image, by output Defective locations work back in original image, to guarantee the defective locations of final system output as the position in original image.It is practical Application requirement in, can defect the length and width of rectangle frame less than 0.1 centimetre ignore.When statistical shortcomings, if rectangle The length and width of frame is respectively less than 0.1 centimetre, then will not output it.In addition, the result that model judges is saved in text, save The defective state of content (YES indicate retain defect, NG expression ignore the defect), defective locations and confidence level.
The above description is merely a specific embodiment, but scope of protection of the present invention is not limited thereto, any The staff for being familiar with the art in the technical scope disclosed by the present invention, can readily occur in various equivalent modifications or replace It changes, these modifications or substitutions should be covered by the protection scope of the present invention.Therefore, protection scope of the present invention should be with right It is required that protection scope subject to.

Claims (10)

1. the defect inspection method on the irregular shape intermetallic composite coating surface based on deep learning, which is characterized in that this method packet Include following steps:
1) original image on irregular shape intermetallic composite coating surface is acquired;
2) collected original image is pre-processed, obtains ROI;
3) ROI is manually marked, obtains the sample infused with defective collimation mark, sample is expanded by data enhancing, Using the sample after expansion as the data set of training network;
4) deep learning detection network is built based on YOLOv3;
5) network is detected using the sample training deep learning of the defective collimation mark note of the enhanced band of data, obtains defects detection mould Type;
6) defects detection is carried out to collected intermetallic composite coating surface image using the defects detection model that training obtains, obtains and lacks Fall into testing result.
2. the defect inspection method on the irregular shape intermetallic composite coating surface according to claim 1 based on deep learning, It is characterized in that, the specific steps for obtaining ROI include:
201) piecemeal is numbered after being cut original image;
202) image after cutting is filtered and edge detection process;
203) Morphological scale-space is carried out to image, obtains multiple connected regions, connected region is marked and is classified, to classification Connected region afterwards carries out the calculating of average pixel value;
204) average pixel value of calculating is judged, chooses the spy that the highest connected region of average brightness is extracted as needs Levy detection zone;
205) the connected region degree of comparing of selection is enhanced, obtains ROI.
3. the defect inspection method on the irregular shape intermetallic composite coating surface according to claim 1 based on deep learning, It is characterized in that, the data enhancing includes one of Image Reversal, image irradiation adjusting, noise addition, affine transformation Or a variety of operations.
4. the defect inspection method on the irregular shape intermetallic composite coating surface according to claim 2 based on deep learning, It is characterized in that, using pretreated ROI as initial data set, carrying out priori knowledge mark to initial data set in step 3) Each frames images is taken out defect using rectangle frame, and marks actual defect classification by note.
5. the defect inspection method on the irregular shape intermetallic composite coating surface according to claim 4 based on deep learning, It is characterized in that, step 4) specifically includes the following steps:
401) deep learning detection network is built using 53 layers of convolutional network, feature extraction is carried out to ROI;
402) feature of extraction is sent into classifier and returns device, obtain the size and location of defect;
402) each image is compared with the result that device obtains is returned with true value by classifier, according to comparison result The parameter of percentage regulation study detection network.
6. the defect inspection method on the irregular shape intermetallic composite coating surface according to claim 5 based on deep learning, It is characterized in that, the particular content of step 6) are as follows:
The defects detection model that the acquisition image input training for being used to detect is obtained, obtains the defect exported with rectangle box form Position and confidence level work back to the defective locations of output in original image according to the number of image, obtain in original image Defective locations.
7. the defect inspection method on the irregular shape intermetallic composite coating surface according to claim 6 based on deep learning, It is characterized in that, the data format of each rectangle frame includes the coordinate and square of the coordinate of upper left corner angle point, lower right corner angle point The length and width of shape frame.
8. the defect inspection method on the irregular shape intermetallic composite coating surface according to claim 2 based on deep learning, It is characterized in that, being filtered using Gaussian filter to the image after cutting.
9. the defect inspection method on the irregular shape intermetallic composite coating surface according to claim 2 based on deep learning, It is characterized in that, carrying out edge detection process to the image after cutting using Canny operator extraction method.
10. the defect inspection method on the irregular shape intermetallic composite coating surface according to claim 5 based on deep learning, It is characterized in that, being interspersed with residual error network structure among the convolutional layer and pond layer of 53 layers of the convolutional network.
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CN117830184A (en) * 2024-03-06 2024-04-05 陕西长空齿轮有限责任公司 Metallographic image enhancement method and system
CN117830184B (en) * 2024-03-06 2024-05-31 陕西长空齿轮有限责任公司 Metallographic image enhancement method and system
CN119863440A (en) * 2024-12-26 2025-04-22 中南大学 Automatic identification and cutting method for surface defects of metal strip based on edge detection
CN119863440B (en) * 2024-12-26 2025-09-23 中南大学 Automatic identification and cutting method for surface defects of metal strip based on edge detection
CN120013927A (en) * 2025-04-15 2025-05-16 北京妙想科技有限公司 Industrial product surface defect detection method based on AI big model

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Application publication date: 20190416