# How to convert RGB code to 8 simple intervals (possible ?)

I'm working on my Final Bachelor Project in Computer Science and for now I'm in a dead end. Here is what I got stuck on:

I'm trying to classify any color (rgb code) in any of 8 (eight) simple colors. In short terms I need to find 8 intervals where any colour can be placed and be considered a basic color (red, blue, green, black, yellow, purple, grey, brown ).

example:
(18,218,23) to be classified as "green"
(81,,214,85) also "green"
but
(15,52,16) needs to be "black"
(110,117,110) needs to be "grey"

So there are 256 x 256 x 256 possible colors and I need to divide them in 8 (intervals) basic colors.

I'm waiting for some suggestions.

Cheers !

To be clear (as I've seen in comments) I'm looking for a particular set of 8 colors (red, black, green, brown, blue, purple, grey, yellow). Sorry for the orange above !

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Um... no it doesn't. You can specify ranges in your if-else blocks... For example, black could mean something like <60, <60, <60, etc. –  Tanvir Ahmed May 30 '12 at 18:51
What about calculating the distance of the colour that is to be classified to each of the eight "primary" colours? If you do this, you should keep in mind that short distances in the RGB space do not necessarily correspond to human perception. For that, you should convert to LUV or a similar space. –  Gnosophilon May 30 '12 at 18:52
How you can do this depends on exactly which colours you want to classify as what. Then again, once you determine that, you pretty much already have your algorithm right there. –  harold May 30 '12 at 18:53
Whichever way you end up choosing will for some colours be subjectively wrong to some people anyway. People don't really agree on how to label colours that are "in between" proper colours. –  harold May 30 '12 at 19:01

Based on your example, I'd start with determining whether all components are approximately the same, or does on stand out. If they are about the same, then decide if the values are small enough to be black or not, then it's grey. If one value is different from the other two, then it is easy to check which is different and pick one of six possible colors accordingly.

Alternatively, set each component to either 0 or 1 according to a threshold, then you have 8 combinations to map to 8 colors.

``````threshold = 100:
(18,218,23)   -> (0, 1, 0) - to be classified as "green"
(81,214,85)   -> (0, 1, 0) - also "green"
(15,52,16)    -> (0, 0, 0) - to be "black"
(110,117,110) -> (1, 1, 1) - to be "grey"
``````
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This a great idea ! Thank you so much ! It's simple and light!weight –  VladU May 30 '12 at 19:06
You're welcome. –  ysap May 30 '12 at 19:09
@VladU: You asked for "red, blue, orange, black, yellow, purple, grey, brown", but ysap's algorithm (though fast and simple) gives "black, blue, green, seagreen, red, purple, yellow/orange, white/grey" –  Mooing Duck May 30 '12 at 19:32
@MooingDuck - I agree with you on that, but again, note that the example vectors are different from the colors in the table (missing green), so my assumption is that this is not really a photographic algorithm exercise but rather an introductory exercise in programming. As which, the principle here is more important. again - if the colors in the list are actually required, then my method is not the appropriate one (w/o colorspace conversion). –  ysap May 30 '12 at 19:37
@VladU: if the specific colors aren't important, then I would definitely go with this answer. (Also please add that information to the question for future visitors) –  Mooing Duck May 30 '12 at 19:42

Don't know too much about Color scheme but calculating Euclidean distance would be a good solution.

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No - full Red (255,0,0) full Blue(0,0,255) and Grey(140,140,140) are all the same Euclidean distance from black –  Martin Beckett May 30 '12 at 19:15
@MartinBeckett: I don't immediately see the relevance of that. My first response to this question would be exactly this. Sure, a tiny number of colors might be equidistant from one or more of the "basic colors", in which case one can be arbitrarily selected. –  Mooing Duck May 30 '12 at 20:30

Don't do this in RGB, convert to a more convenient color space HSV is probably easiest - then the 8 "colors" are simply 8 intervals along the Hue axis.

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Thanks Martin. This seems pretty good solution. I'll do more research about HSV color space. –  VladU May 30 '12 at 19:11
the wikipedia article includes enough info to do this (done it many times myself!) –  andrew cooke May 30 '12 at 19:48

RGB is horrible for this kind of thing, so your first step should be converting the color to a Lab color space. You can find many open implementations of this conversion online. Once you have your Lab color, everything becomes very simple. The three values become coordinates in three dimensions which you can easily section according to color - check out the images in the wikipedia link.

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I think that HSV may be better for this problem. –  user502144 May 30 '12 at 19:05
What makes you think that? HSV is a step in the right direction, but is not a very good representation of the human color perception, which is what we are after. –  qwertyboy May 30 '12 at 19:08
@qwertyboy - but if you are dividing RGB values into only 8 colors then details of human perception probably aren't top of the list! HSV maps simple 'color' into a single angle –  Martin Beckett May 30 '12 at 19:11
@martin - I disagree. It's not detailed perception, but it's still perception. We want everything that a person calls "blue" to be close together, and that's best achieved (to my knowledge) with Lab colors. I agree, however, that the improvement may be small, and HSV is far cheaper to compute. –  qwertyboy May 30 '12 at 19:19