# Binarization methods, middle-treshold binarisation

I'm trying to binarise a picture, firstly of course having it prepared(grayscaling) My method is to find the maximum and minimum values of grayscale, then find the middle value(which is my treshold) and then, iterating over all the pixels I compare the current one with a treshold and if the grayscale is larger than the treshold, I put 0 in a matrix, or for the others I put 1. But now I'm facing the problem. In common I'm binarising images with white background, so my algorithm is further based on this feature. But when I meet an image with black background everything collapses, but I still can see the number clearly(now 0's and 1's switch places) How can i solve this problem, make my program more common? Maybe I'd better look for another ways of binarization/

P.S. I looked for an understandable explanation of Otsu treshold method, but it seems either I'm not prepared for this way of difficulty or I find very complicated explanations every time, but I can't write it in C. If anyone could hrlp here, it'd be wonderful.

Sorry for not answering the questions, just didn't see them Firstly - the code

``````for (int y=1;y<Source->Picture->Height;y++)
for (int x=1;x<Source->Picture->Width;x++)
{
unsigned green = GetGValue(Source->Canvas->Pixels[x][y]);
unsigned red = GetRValue(Source->Canvas->Pixels[x][y]);
unsigned blue = GetBValue(Source->Canvas->Pixels[x][y]);
treshold = (0.2125*red+0.7154*green+0.0721*blue);
if (min>treshold)
min=treshold;
if (max<treshold)
max = treshold;
}
middle = (max+min)/2;
``````

Then iterating through the image

``````        if (treshold<middle)
{
picture[x][y]=1;
fprintf( fo,"1");
} else {
picture[x][y]=0;
fprintf( fo,"0");
}
}
fprintf( fo,"\n");
}
fclose(fo);
``````

So I get a file, something like this

000000000
000001000
000001000
000011000
000101000
000001000
000001000
000001000
000000000

Here you can see an example of one.

Then I can interpolate it, or do something else (recognize), depending on zero's and one's. But if I switch the colors, the numbers won't be the same. So the recognition will not work. I wonder if there's an algoritm that can help me out.

-
Post some code please –  KCH Jan 13 '12 at 17:14
Why does it "collapse"? Sounds like it should work fine for black backgrounds. –  Mooing Duck Jan 13 '12 at 17:37
Can you point us to a couple of sample pictures, one white background and one black background? –  Mark Ransom Jan 13 '12 at 17:45
I've read the problem a few times, I really cannot figure out what you're asking of us. Can you re-word the question to clarify? –  Mooing Duck Jan 20 '12 at 21:49
@Mooing Duck That's okay, everything's clearly done. You've helped a lot with the explamation of Otsu's treshold, thanks. –  user1131662 Jan 21 '12 at 17:58

I've never heard of Otsu's method, but I understand some of the wikipedia page so I'll try to simplify that.

``````1 Count how many pixels are at each level of darkness.
2 "Guess" a threshold.
3 Calculate the variance of the counts of darkness less than the threshold
4 Calculate the variance of the counts of darkness greater than the threshold
5 If the variance of the darker side is greater, guess a darker threshold,
else guess a higher threshold.
Do this like a binary search so that it ends.
6 Turn all pixels darker than threshold black, the rest white.
``````

Otsu's method is actually "maximizing inter-class variance", but I don't understand that part of the math.

The concept of variance, is "how far apart are the values from each other." A low variance means everything is similar. A high variance means the values are far apart. The variance of a rainbow is very high, lots of colors. The variance of the background of stackoverflow is 0, since it's all perfectly white, with no other colors. Variance is calculated more or less like this

``````double variance(unsigned int* counts, int size, int threshold, bool above) {
//this is a quick trick to turn the "upper" into lower, save myself code
if (above) return variance(counts, size-threshold, size-threshold, false);
//first we calculate the average value
unsigned long long atotal=0;
unsigned long long acount=0;
for(int i=0; i<threshold; ++i) {
atotal += counts[i]*i //number of px times value
acount += counts[i];
}
//finish calculating average
double average = double(atotal)/count;
//next we calculate the variance
double vtotal=0;
for(int i=0; i<threshold; ++i) {
//to do so we get each values's difference from the average
double t = std::abs(i-average);
//and square it (I hate mathmaticians)
vtotal += counts[i]*t*t;
}
//and return the average of those squared values.
return vtotal/count;
}
``````
-
Let's see, what I understood. At first, I'm just doing a histogram. It may be a matrix with one index showing the greyscale values and the other - numbers of them. Then I'm just picking some value. Then I'm counting how many values of darker/higher pixels. Then I'm deciding whether to lower or higher the first treshold value. The next thing I do not understand, so when should I end my treshold choice? The last thing is clear to me as well –  user1131662 Jan 13 '12 at 17:49
@user1131662: I updated the answer with a variance function. If the guess is too dark, then the variance of the lighter pixels will be high, if the guess is too light, the variance of the darker pixels will be high. You have to do a binary search for the threshold where the two variances are as close as possible. –  Mooing Duck Jan 13 '12 at 17:55
Oh, thanks, I'll try to understand it. –  user1131662 Jan 13 '12 at 18:06
@user1131662: I commented the variance function –  Mooing Duck Jan 13 '12 at 18:13
I'm very grateful for your efforts, but it seems, that I'm even more stupid. I have a problem understanding small pieces of code. But again, thank you, now that I have an algoritm, it's easier to understand (rather than just math functions) –  user1131662 Jan 13 '12 at 18:20

I would tackle this problem with another approach:

• Compute the cumulative histogram of greyscaled values of the image.
• Use as threshold the pixel value in which this cumulative reaches half of the total pixels of the image.

The algorithm would go as follows:

``````  int bin [256];
foreach pixel in image
bin[pixelvalue]++;
endfor  // this computes the histogram of the image

int thresholdCount = ImageWidth * ImageSize / 2;
int count = 0;
for int i = 0 to 255
count = count + bin[i];
if( count > thresholdCount)
threshold = i;
break; // we are done
endif
endfor
``````

This algorithm does not compute the cumulative histogram itself but rather uses the image histogram to do what I said earlier.

-
Well, let's see, if I understood it clearly enough. –  user1131662 Jan 13 '12 at 17:18
Firstly I iterate through all the pixels and summarize their greyscaled values. S = g1+g2+g3 Secondly I divide this s value by half the number of all pixels in an image. Is it right? –  user1131662 Jan 13 '12 at 17:21
No, that will give you double the average value, which might not even be a valid value. Though I do not understand this answer either. –  Mooing Duck Jan 13 '12 at 17:27
@user1131662, what you're describing is (almost) the mean value, what gusbro is suggesting is the median value. The difference will depend on the distribution of values in your image. –  Mark Ransom Jan 13 '12 at 17:28
Well, then if anyone else could help here, it'd be great. –  user1131662 Jan 13 '12 at 17:29
show 5 more comments

If your algorithm works properly for white backgrounds but fails for black backgrounds, you simply need to detect when you have a black background and invert the values. If you assume the background value will be more common, you can simply count the number of 1s and 0s in the result; if the 0s are greater, invert the result.

-
Well, the white background is more common, but of course I need all exceptions to work properly. The most frustrating is that everything is very dependable. I hope I'll get away just with this inverting, but just in case it won't work I decided to ask –  user1131662 Jan 13 '12 at 17:40