# Detecting scratch on image with much noise

I am having problem to detect scratch on these images. Actually, it is very easy to see by human eyes. However, when applying some algorithms, there are a lot of noise and I couldn't extract the scratch only.

Here are these images:

At present, I tried some kinds of filter (smoothing, average, median, Gaussian filter or Sobel edge detector) to erase noise and detect scratch but they don't help much. Could you suggest some idea? Some tools or algorithms that I should consider?

• I just looked at your image, and I can't tell what's a scratch and what's a normal feature. Are the three large parallel slashes the scratches, or is it the small horizontal line on the left slash? Oct 20, 2015 at 3:03
• Hi,scratches are three large parallel slashes. Oct 20, 2015 at 3:30
• Use the ideas in the duplicate post. The duplicate post goes further and removes the scratches in the image. Just use the first half of the highest voted answer. Oct 20, 2015 at 8:05
• This is definitely not a duplicate of the question listed. This question is about detecting scratches automatically, the other question is about removing scratches (when you know where it is). I suggest to reopen. Oct 20, 2015 at 9:05
• @DanivanderMeer My bad. You're right. I should have read the post better. Reopening. Oct 20, 2015 at 16:44

This is my implementation for the defect detection, its a very simple yet effective approach, i have implemented this code in MATLAB, but there is not any difficulty to port it on any language because its use basic image processing operations.

`clc`

`clear all`

`close all`

1. Read Both the Images and downsample them(for fast calculation) by factor of 2.

`im1 = imresize(imread('scratch.jpg'),0.5);`

1. Convert them into gray scale.

`gray = rgb2gray(im);`

1. Apply a Gaussian filter of size 15 X 15.

`gSize = 15;`

`gray = imfilter(gray,fspecial('gaussian',[gSize,gSize],gSize/2),'replicate');`

`[~,~,mg,~] = ImageFeatures.Gradients(gray);`

1. Threshold Gradient magnitude with a threshold of 30 percentile of max value.

`mgBw = mg > 0.3*max(mg(:));

1. Apply morpholgical operation Closing of binary image by a disk mask of 3 X 3.

`mgBw = imclose(mgBw,strel('disk',1));`

1. Apply Particle Analyze(CCL).

`mgBw = bwareaopen(mgBw,500);`

1. Again Close Image for joining Lines together.

`mgBw = imclose(mgBw,strel('disk',2));`

1. Fill Holes in the image.

`mgBw = imfill(mgBw,'holes');`

1. Final Annotations:

Try Above procedure on your images hope it will work

Thank You

Values For Gaussian Mask are Given below i have just copied as it is, you can only use values 4 places after decimal and one more thing before convolution scale your image values between 0 and 1:

``````         0.00253790859361804,0.00284879446220838,0.00314141610419987,0.00340305543986557,0.00362152753952273,0.00378611472031542,0.00388843599983945,0.00392315394879368,0.00388843599983945,0.00378611472031542,0.00362152753952273,0.00340305543986557,0.00314141610419987,0.00284879446220838,0.00253790859361804;
0.00284879446220838,0.00319776287779517,0.00352622975612324,0.00381991909245893,0.00406515334132644,0.00424990193722614,0.00436475725361032,0.00440372804277458,0.00436475725361032,0.00424990193722614,0.00406515334132644,0.00381991909245893,0.00352622975612324,0.00319776287779517,0.00284879446220838;
0.00314141610419987,0.00352622975612324,0.00388843599983945,0.00421229243210782,0.00448271658130972,0.00468644212981339,0.00481309512122034,0.00485606890058492,0.00481309512122034,0.00468644212981339,0.00448271658130972,0.00421229243210782,0.00388843599983945,0.00352622975612324,0.00314141610419987;
0.00340305543986557,0.00381991909245893,0.00421229243210782,0.00456312191696750,0.00485606890058492,0.00507676215263394,0.00521396370030743,0.00526051663974220,0.00521396370030743,0.00507676215263394,0.00485606890058492,0.00456312191696750,0.00421229243210782,0.00381991909245893,0.00340305543986557;
0.00362152753952273,0.00406515334132644,0.00448271658130972,0.00485606890058492,0.00516782273108746,0.00540268422664802,0.00554869395001131,0.00559823553262373,0.00554869395001131,0.00540268422664802,0.00516782273108746,0.00485606890058492,0.00448271658130972,0.00406515334132644,0.00362152753952273;
0.00378611472031542,0.00424990193722614,0.00468644212981339,0.00507676215263394,0.00540268422664802,0.00564821944786971,0.00580086485975791,0.00585265795345929,0.00580086485975791,0.00564821944786971,0.00540268422664802,0.00507676215263394,0.00468644212981339,0.00424990193722614,0.00378611472031542;
0.00388843599983945,0.00436475725361032,0.00481309512122034,0.00521396370030743,0.00554869395001131,0.00580086485975791,0.00595763557555571,0.00601082839853353,0.00595763557555571,0.00580086485975791,0.00554869395001131,0.00521396370030743,0.00481309512122034,0.00436475725361032,0.00388843599983945;
0.00392315394879368,0.00440372804277458,0.00485606890058492,0.00526051663974220,0.00559823553262373,0.00585265795345929,0.00601082839853353,0.00606449615428972,0.00601082839853353,0.00585265795345929,0.00559823553262373,0.00526051663974220,0.00485606890058492,0.00440372804277458,0.00392315394879368;
0.00388843599983945,0.00436475725361032,0.00481309512122034,0.00521396370030743,0.00554869395001131,0.00580086485975791,0.00595763557555571,0.00601082839853353,0.00595763557555571,0.00580086485975791,0.00554869395001131,0.00521396370030743,0.00481309512122034,0.00436475725361032,0.00388843599983945;
0.00378611472031542,0.00424990193722614,0.00468644212981339,0.00507676215263394,0.00540268422664802,0.00564821944786971,0.00580086485975791,0.00585265795345929,0.00580086485975791,0.00564821944786971,0.00540268422664802,0.00507676215263394,0.00468644212981339,0.00424990193722614,0.00378611472031542;
0.00362152753952273,0.00406515334132644,0.00448271658130972,0.00485606890058492,0.00516782273108746,0.00540268422664802,0.00554869395001131,0.00559823553262373,0.00554869395001131,0.00540268422664802,0.00516782273108746,0.00485606890058492,0.00448271658130972,0.00406515334132644,0.00362152753952273;
0.00340305543986557,0.00381991909245893,0.00421229243210782,0.00456312191696750,0.00485606890058492,0.00507676215263394,0.00521396370030743,0.00526051663974220,0.00521396370030743,0.00507676215263394,0.00485606890058492,0.00456312191696750,0.00421229243210782,0.00381991909245893,0.00340305543986557;
0.00314141610419987,0.00352622975612324,0.00388843599983945,0.00421229243210782,0.00448271658130972,0.00468644212981339,0.00481309512122034,0.00485606890058492,0.00481309512122034,0.00468644212981339,0.00448271658130972,0.00421229243210782,0.00388843599983945,0.00352622975612324,0.00314141610419987;
0.00284879446220838,0.00319776287779517,0.00352622975612324,0.00381991909245893,0.00406515334132644,0.00424990193722614,0.00436475725361032,0.00440372804277458,0.00436475725361032,0.00424990193722614,0.00406515334132644,0.00381991909245893,0.00352622975612324,0.00319776287779517,0.00284879446220838;
0.00253790859361804,0.00284879446220838,0.00314141610419987,0.00340305543986557,0.00362152753952273,0.00378611472031542,0.00388843599983945,0.00392315394879368,0.00388843599983945,0.00378611472031542,0.00362152753952273,0.00340305543986557,0.00314141610419987,0.00284879446220838,0.00253790859361804;
``````

`````` 1, 2, 1;
0, 0, 0;
-1,-2, 1;
``````

and

`````` 1, 0,-1;
2, 0,-2;
1, 0,-1;
``````

``````function [gx,gy,mag,phi] = Gradients(gray)
gray = double(gray);

phi = (atan2((gy),(gx)));

mag = mat2gray(sqrt(gx.^2+gy.^2));
end
``````
• Well, very impressive! I will try this procedure in C++ and post the result when I finish. Oct 22, 2015 at 13:10
• too Many parameters.. I am positive that it won't work with slightly diffrent condetions Oct 23, 2015 at 11:03
• Try it dude... in sample there were only two images...algorithms always designed on the basis of data availability. Oct 23, 2015 at 12:09
• what is the source of this technique? I mean, how/where did you find it? Any article/book/citation/anything? Aug 22, 2017 at 17:38
• experience was the source of the technique :) Mar 21, 2018 at 10:59

I tried the following procedure for detection. The output looks moderate, but still I thought of sharing.

• downsample the color image.
• apply median blur with different window sizes, then take the absolute difference: I'm doing this to enhance the scratch marks and at the same time achieve illumination flattening. Shown below are the difference images obtained this way.

• use Gaussian Mixture based background/foreground segmentation to segment the scratch marks in the difference image. Idea here is, we can extract m x n windows from this image and train. As the scratch marks don't occupy a large area in the difference image, we can think the learned background should approximate the region outside scratch marks. This method worked better for both difference images than applying a threshold to the difference image. This method did not work well when I fed the downsampled image directly. I think this is due to the nonuniform nature of the pixel color values in regions. So I used the illumination flattened difference image. Below are the segmented images. This procedure is slow as it checks every possible m x n window in the image.

• use probabilistic Hough transform to detect lines in the segmented image. Using the line density in regions or using morphological filtering for lines, I think it's possible to arrive at a reasonable guess as to where the scratch marks are.

Here's the code

background segmentation code:

``````Mat threshold_mog(Mat& im, Size window)
{
BackgroundSubtractorMOG2 bgModel;
Mat output = Mat::ones(im.rows, im.cols, CV_8U);

for (int r = 0; r < im.rows - window.height; r++)
{
for (int c = 0; c < im.cols - window.width; c++)
{
}
}

for (int r = 0; r < im.rows - window.height; r++)
{
for (int c = 0; c < im.cols - window.width; c++)
{
Mat region = im(Rect(c, r, window.width, window.height));
}
}

return output;
}
``````

main:

``````Mat rgb = imread("scratch_2.png.jpg");

pyrDown(rgb, rgb);

Mat med, med2, dif, bw;

medianBlur(rgb, med, 3);
medianBlur(rgb, med2, 21);

absdiff(med2, med, dif);

bw = threshold_mog(dif, Size(15, 15));

Mat dst = bw.clone();
vector<Vec4i> lines;
HoughLinesP(dst, lines, 1, CV_PI/180, 8, 10, 20);
for( size_t i = 0; i < lines.size(); i++ )
{
Vec4i l = lines[i];
line(rgb, Point(l[0], l[1]), Point(l[2], l[3]), Scalar(0,0,255), 1, CV_AA);
}
``````
• Thank you, everyone. It seems good enough. I am writing Hough transform right now. Oct 22, 2015 at 12:48
• @anhnha Did you able to complete it using C++ ? Can you post source code for reference ? Dec 2, 2019 at 6:54
• @user1220497 it has been a long time and now I'm working in a different field Dec 2, 2019 at 15:57