Its quite difficult since the quality of your images are so low, but you could try an iterative global thresholding approach as follows:

- Randomly select an initial estimate threshold T (usually as the mean).
- Segment the signal using T, which will yield two groups, G1 consisting of all points with values<=T and G2 consisting of points with value>T.
- Compute the average distance between points of G1 and T, and points of G2 and T.
- Compute a new threshold value T=(M1+M2)/2
- Repeat steps 2 through 4 until the change of T is smaller enough.

The trick is not to apply it to the whole image, but to break up the image into blocks of (for example) 5x5 and apply it to the blocks individually which would give you:

Below is an implementation in R which I'm sure you could reproduce

getT = function(y){
t = mean(y)
mu1 = mean(y[y>=t])
mu2 = mean(y[y 1){
cmu1 = mean(y[y>=t])
cmu2 = mean(y[y 1 & cmu1 == mu1 & cmu2 == mu2){
print(paste('done t=', t))
return(t)
break;
}else{
mu1 = cmu1
mu2 = cmu2
t = (mu1 + mu2)/2
print(paste('new t=', t))
}
i = i+1
}
}
r = seq(1, nrow(image), by=5)
c = seq(1, ncol(image), by=5)
r[length(r)] = nrow(image)
c[length(c)] = ncol(image)
y = image
for(i in 2:length(r) ){
for(j in 2:length(c) ){
block = image[r[i-1]:r[i], c[j-1]:c[j]]
t = getT(block)
y[r[i-1]:r[i], c[j-1]:c[j]] = (block>t)+0
}
}
display(y)

Disclamer: I've never done any reall image processing and only read the remarks on the link you posted.– Cemafor Apr 30 '13 at 20:48