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For example, say I have a 2D array of pixels (in other words, an image) and I want to arrange them into groups so that the number of groups will add up perfectly to a certain number (say, the total items in another 2D array of pixels). At the moment, what I try is using a combination of ratios and pixels, but this fails on anything other than perfect integer ratios (so 1:2, 1:3, 1:4, etc). When it does fail, it just scales it to the integer less than it, so, for example, a 1:2.93 ratio scale would be using a 1:2 scale with part of the image cut off. I'd rather not do this, so what are some algorithms I could use that do not get into Matrix Multipication? I remember seeing something similar to what I described at first mentioned, but I cannot find it. Is this an NP-type problem?

For example, say I have a 12-by-12 pixel image and I want to split it up into exactly 64 sub-images of n-by-m size. Through analysis one could see that I could break it up into 8 2-by-2 sub-images, and 56 2-by-1 sub-images in order to get that exact number of sub-images. So, in other words, I would get 8+56=64 sub-images using all 4(8)+56(2)=144 pixels.

Similarly, if I had a 13 by 13 pixel image and I wanted to 81 sub-images of n-by-m size, I would need to break it up into 4 2-by-2 sub-images, 76 2-by-1 sub-images, and 1 1-by-1 sub-image to get the exact number of sub-images needed. In other words, 4(4)+76(2)+1=169 and 4+76+1=81.

Yet another example, if I wanted to split the same 13 by 13 image into 36 sub-images of n-by-m size, I would need 14 4-by-2 sub-images, 7 2-by-2 sub-images, 14 2-by-1 sub-images, and 1 1-by-1 sub-image. In other words, 8(13)+4(10)+2(12)+1=169 and 13+10+12+1=36.

Of course, the image need not be square, and neither the amount of sub-images, but neither should not be prime. In addition, the amount of sub-images should be less than the number of pixels in the image. I'd probably want to stick to powers of two for the width and height of the sub-images for ease of translating one larger sub image into multiple sub images, but if I can find an algorithm which didn't do that it'd be better. That is basically what I'm trying to find an algorithm for.

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I don't know if I understand your question. Let's say you have a 10x10 pixels image, and you want to divide it into 9 sub-images. Since pixels are discrete entities, the only solution that I see is that you generate 9 sub-images of size 3x3, which obviously cut part of the original image out. –  MarcoS Apr 29 '11 at 6:08
    
That is what I'm trying to do, actually. Of course, that would make things slightly harder, but I'd probably have a lot more groups of 1 pixel than any others. –  Smartboy Apr 29 '11 at 6:12

2 Answers 2

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I understand that you want to split a rectabgular image of a given size, into n rectangular sub-images. Let say that you have:

  • an image of size w * h
  • and you want to split into n sub-images of size x * y

I think that what you want is

R = { (x, y) | x in [1..w], y in [1..h], x * y == (w * h) / n }

That is the set of pairs (x, y) such that x * y is equal to (w * h) / n, where / is the integer division. Also, you probably want to take the x * y rectangle having the smallest perimeter, i.e. the smallest value of x + y.

For the three examples in the questions:

  • splitting a 12 x 12 image into 64 sub-images, you get R = {(1,2),(2,1)}, and so you have either 64 1 x 2 sub-images, or 64 2 x 1 sub-images

  • splitting a 13 x 13 image into 81 sub-images, you het R = {(1,2),(2,1)}, and so you have either 64 1 x 2 sub-images, or 64 2 x 1 sub-images

  • splitting a 13 x 13 image into 36 sub-images, you het R = {(1,4),(2,2),(4,1)}, and so you could use 36 2 x 2 sub-images (smallest perimeter)

For every example, you can of course combine different size of rectangles.

If you want to do something else, maybe tiling your original image, you may want to have a look at rectangle tiling algorithms

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Wouldn't that create all the sub-images of the same size? If so, that is not what I want since I know that for some groups will have to be different sizes in order to total up to the certain amount of groups I needed. –  Smartboy Apr 29 '11 at 13:41
    
@Smartboy: yes, my solution gives sub-images having the same size (x, y). I'm afraid I don't understand your additional constraint about groups having different sizes. Could you perhaps edit your question, and clarify it with an example? –  MarcoS Apr 29 '11 at 14:07
    
@MarcoS I edited it and hopefully clarified what I am trying to do with a couple examples. Does that help? –  Smartboy Apr 29 '11 at 15:33
    
@Smartboy: I edited my answer. I hope this helps. –  MarcoS May 2 '11 at 7:44
    
It does, thanks. :) –  Smartboy May 4 '11 at 15:28

If you don't care about the subimages being differently sized, a simple way to do this is repeatedly splitting subimages in two. Every new split increases the number of subimages by one.

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