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I think the the title is self explanatory. Although I search actually for the blackest and reddest pixel by columns, I guess answering the first automatically answers the second.

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If your representation is RGB you may find the "nearest" to (0,0,0) and (255,0,0). Take note that "nearest" is as ill-defined as "blackest", but it can be defined is a math sense as a distance. You have to chose a suitable distance, though –  belisarius Mar 10 '11 at 14:49
    
If by "blackest" you mean the least bright pixel, you can use the following formula for luminance and search for the lowest luminance value pixel: Y = 0.2126 R + 0.7152 G + 0.0722 B (from Wikipedia) –  Tal Pressman Mar 10 '11 at 15:00

3 Answers 3

up vote 3 down vote accepted

Assuming that your bitmap stores colors in RGB color format (not YCbCr or CYMK) and further assuming that 8 bits are used per color component, the pixel closest to (0,0,0) is the blackest and the pixel closest to (255,0,0) is the reddest. Assuming that this is not really new information to you, I guess your question is rather how to calculate "the distance", so you can find out which one is the closest, correct?

To find out what the blackest pixel is, RGB might not be an optimal color representation; I'd prefer HSL for that. A pixel in HSL format consists of three values, H is the hue (the base color), S is the saturation (how much "gray" is mixed into the color) and L is the lightness (basically the brightness). The pixel with the lowest L value (L is between 1.0 and 0.0) would then be closest to black; two pixels with different H/S values, but same L value are equally "black", even though they might have different colors.

To find out which pixel is closest to red, you'd compare the HSL values of the pixels and search for the pixel with a H value closest to 0.0 degree (since 0.0 degree is red and H is between 0.0 and 360.0 degree, however 360.0 degree equals 0.0 degree), an S value closest to 1.0 (since 1.0 means full color, while 0.0 means fully gray) and an L value closest to 0.5 (since 0.0 would be black and 1.0 would be white).

E.g. in HSL dark yellow is 49.5/0.893/0.497, dark blue is 248.3/0.601/0.373, so you can clearly see that the dark blue pixel has a brightness (= lightness) of 0.373, the dark yellow one of only 0.497, thus the dark blue one is definitely "darker" than the yellow one (closer to black), which solves your first question.

Which pixel is redder? Red is 0.0/1.0/0.5. You can calculate for each component how much it is off of the ideal red pixel. Whether you "weight" all components equally or whether you consider hue (color) difference as more important than other differences (and by what factor) is rather up to your definition of red. You can exclusively go by hue if you want.

This page has a nice recipe on how to convert RGB step by step to HSL (and back again, if you have to): http://130.113.54.154/~monger/hsl-rgb.html

To give you an idea of how the HSL color space looks like, here are some pictures from Wikipedia that try to visualize this color space:

http://upload.wikimedia.org/wikipedia/commons/c/cb/HSL_color_solid_cylinder_alpha_lowgamma.png

and

http://upload.wikimedia.org/wikipedia/commons/a/a0/Hsl-hsv_models.svg

HSV is an alternative color space that shares some properties with HSL, however I personally prefer HSL. Both use the same definition of hue H, but they use very different definitions of saturation and thus also a different definitions of lightness/brightness.

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You can us a 3 dimensional distance equation on your RGB image(r=x,g=y,b=x). So to get the closest to black p1=(0,0,0) and is the current pixel color. The closest pixel to black will be the one with the smallest distance. For red replace p1 with (255,0,0) and repeat.

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Try (255,0,255) and (255,255,0}, both equally distant or "red". The euclidean distance in not near to what the eye senses. But that depends on your "reddish" definition, of course –  belisarius Mar 10 '11 at 15:16
    
Yeah, the main issue here is complimentary colors being created and the fact that Yellow appears less red than Cyan. Perhaps you also want to give weight to the difference between p2.r-p2.g as any pixel where the red and yellow are close are going to look yellow. So the point you are looking at(p2) has 255-|p2.r-p2.g| added to it's weight to push you away from yellowish colors. Not sure about this though. –  kramthegram Mar 10 '11 at 16:02
    
you're right. I only tried to point out the difficulties in the definition of "your-color"-ish things. Perhaps for black and white are somewhat easier in HSL representation, but the rest are not. I also doubt that two humans will classify the same way in the general case. –  belisarius Mar 10 '11 at 16:08

I found a very interesting article on the topic here

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