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Gray Scale Image with Holes

can any one please help me in filling these black holes by values taken from neighboring non-zero pixels. thanks

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Duplicate on DSP: dsp.stackexchange.com/q/2803/590 –  Chris Jul 5 '12 at 8:26
    
Solving that: cs.stackexchange.com/questions/23794/… would do it... –  Drazick Apr 15 at 18:46
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3 Answers

up vote 4 down vote accepted

There is a file on Matlab file exchange, - inpaint_nans that does exactly what you want. The author explains why and in which cases it is better than Delaunay triangulation.

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thanks man this gives satisfactory result –  crack_addict Jul 6 '12 at 4:27
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One nice way to do this is to is to solve the linear heat equation. What you do is fix the "temperature" (intensity) of the pixels in the good area and let the heat flow into the bad pixels. A passable, but somewhat slow, was to do this is repeatedly average the image then set the good pixels back to their original value with newImage(~badPixels) = myData(~badPixels);.

I do the following steps:

  1. Find the bad pixels where the image is zero, then dilate to be sure we get everything
  2. Apply a big blur to get us started faster
  3. Average the image, then set the good pixels back to their original
  4. Repeat step 3
  5. Display

You could repeat averaging until the image stops changing, and you could use a smaller averaging kernel for higher precision---but this gives good results:

enter image description here

The code is as follows:

numIterations = 30;
avgPrecisionSize = 16; % smaller is better, but takes longer

% Read in the image grayscale:
originalImage = double(rgb2gray(imread('c:\temp\testimage.jpg')));

% get the bad pixels where  = 0 and dilate to make sure they get everything:
badPixels = (originalImage == 0);
badPixels = imdilate(badPixels, ones(12));

%# Create a big gaussian and an averaging kernel to use:
G = fspecial('gaussian',[1 1]*100,50);
H = fspecial('average', [1,1]*avgPrecisionSize);

%# User a big filter to get started:
newImage = imfilter(originalImage,G,'same');
newImage(~badPixels) = originalImage(~badPixels);

% Now average to
for count = 1:numIterations
   newImage = imfilter(newImage, H, 'same');
   newImage(~badPixels) = originalImage(~badPixels);
end

%% Plot the results
figure(123);
clf;

% Display the mask:
subplot(1,2,1);
imagesc(badPixels);
axis image
title('Region Of the Bad Pixels');

% Display the result:
subplot(1,2,2);
imagesc(newImage);
axis image
set(gca,'clim', [0 255])
title('Infilled Image');

colormap gray

But you can get a similar solution using roifill from the image processing toolbox like so:

newImage2 = roifill(originalImage, badPixels);

figure(44);
clf;
imagesc(newImage2);
colormap gray

notice I'm using the same badPixels defined from before.

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To fill one black area, do the following:

1) Identify a sub-region containing the black area, the smaller the better. The best case is just the boundary points of the black hole.

2) Create a Delaunay triangulation of the non-black points in inside the sub-region by:

 tri = DelaunayTri(x,y); %# x, y (column vectors) are coordinates of the non-black points.

3) Determine the black points in which Delaunay triangle by:

[t, bc] = pointLocation(tri, [x_b, y_b]); %# x_b, y_b (column vectors) are coordinates of the black points
tri = tri(t,:);

4) Interpolate:

v_b = sum(v(tri).*bc,2); %# v contains the pixel values at the non-black points, and v_b are the interpolated values at the black points.
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Seems it will work let me try. thanks for your effort –  crack_addict Jul 5 '12 at 6:19
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