# I need to diff two images to see what color(s) are different. Any medium level algorithms?

If I have two images which are both the left side view of a the same shoe in different styles, how can I determine by which color(s) they differ? Perhaps it's a shoe in two styles, one style has pink laces and a white side, the other has white laces and a yellow side. I want:

Image One Colors: C1=Pink, C2=White

Image Two Colors: C1=White, C2=Yellow

No super high level algorithms, but I don't need actual implemented code either. Perhaps just loops, data structures, conditions..

The actual shoe part of the image will be on a white background. These will be photographs similar to what you'd see on endless.com or zappos.com so they're very similar, but require some tolerance.

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For some reason quantisation, buckets and content-based image retrieval are springing to mind. Just looking for an old coursework which may help shed some light... –  brumScouse Oct 26 '10 at 21:33
This sounds like it might be quite a nightmare. Unless the shoes are exactly in the same place and orientation, you're going to need some pretty sophisticated stuff. (Of course, if you just want major colors, that could be simple.) –  JoshD Oct 26 '10 at 21:51
Position and orientation are easy. Do edge walking to find the shoe on the background, put bounding boxes around the shoes, line up the boxes. –  MStodd Oct 26 '10 at 22:08

Since it sounds like you only want to tell what colours they differ by (without regard to shape etc.) and that you expect the shapes will be highly similar (though not identical), I would:

1. Compute colour histograms for each image (you may need 3 histograms each for R, G, B)
2. Subtract them (`z = abs(x - y)` for each colour)
3. Identify peaks in the resulting histogram(s)

When a significant area is coloured differently in each image, this will give you two high peaks in the final histogram(s). (Drop the `abs()` if you need to tell which is which.)

[EDIT] As jilles de wit suggests, it's better to look at frequencies of (R, G, B) triples instead of individual colours (i.e. for each image create one big histogram of size 256*256*256 instead of 3 size-256 histograms). But in this case the histogram vector is huge and likely to be mainly filled with zeros, so it is a good idea to quantise the intensities down from 256 to say 16 levels, giving a more manageable 16*16*16 vector.

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That's an interesting approach. Sounds like it should do the job. –  MStodd Oct 27 '10 at 16:58
Don't do separate histograms for R, G and B. The combination of R,G,B makes the colour. A red shoe with yellow laces on a black background would lead to peaks in both the R,G and B histograms around 255 and 0 and you wouldn't know which colour caused them (could be red, blue and green, or green and purple, or red and cyan, etc.) Otherwise, finding peaks in the histogram is the most sensible approach. –  jilles de wit Oct 28 '10 at 14:14
@jilles: Do you mean recording the frequency of each (R, G, B) triple? That sounds like a good idea. In that case some quantisation is probably helpful to avoid dealing with highly sparse 256*256*256 vectors. –  j_random_hacker Oct 28 '10 at 14:36
Yes, that is exactly what I mean, including quantisation. –  jilles de wit Oct 29 '10 at 12:02