# “Standard” RGB to Grayscale Conversion

I'm trying to write a converters algorithm that takes a JPEG image and returns its PGM (Portable Gray Map) version. The problem is that I can't understand how the "official" JPG->PGM convertitors work in terms of what value to assign to the final pixel (i guess, 0->255) starting from the classic RGB format.

At the beginning, I used this formula (it's the same used by OpenCV's CV_RGB2GRAY conversion):

0.30*R + 0.59*G + 0.11*B = val

I wrote a simple code to test my results: it takes a color image and its PGM version (already converted using GIMP). Then it converts the color image using the previous formula. The goal is to have a grayscale image that is pixel-to-pixel equal to the PGM input.

At this point, it does not return the same values. Can you help me?

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Have you already had a look at wikipedia: Grayscale? – MrSmith42 Jul 12 '13 at 14:23
Are you sure that's what it does? What if it just decodes the Y plane and ignores the colour-coefficients? You'd have different noise, and the factors may be different. – harold Jul 12 '13 at 14:33
Sorry, I don't understand your post – alessandro.francesconi Jul 12 '13 at 14:58

The problem is that I can't understand how the "official" JPG->PGM convertitors work in terms of what value to assign to the final pixel (i guess, 0->255) starting from the classic RGB format.

There is likely a gamma adjustment in the conversion those "official" tools are using.
That is, it is not just a linear transform.

See this Wikipedia section for the details: Converting color to grayscale

I believe you want to use the formula for `Csrgb`.
Try it out and see if it matches the results you're expecting.

Basically, you'll do this:

1. Take `R, G, B` color (each in `[0,1]` range)
• If they're in the range `0..255` instead, simply divide by `255.0`
2. Compute `Clinear = 0.2126 R + 0.7152 G + 0.0722 B`
• This is likely the linear transform you were applying before
3. Compute `Csrgb` according to it's formula, based on `Clinear`
• This is the nonlinear gamma correction piece you were missing
• Check out this WolframAlpha plot
• `Csrgb = 12.92 Clinear` when `Clinear <= 0.0031308`
• `Csrgb = 1.055 Clinear1/2.4 - 0.055` when `Clinear > 0.0031308`
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@alessandro.francesconi I updated the answer a little bit to spell out the exact steps, since the Wikipedia page could be a little cryptic if you're not familiar with some of the basic color science. – Timothy Shields Jul 12 '13 at 16:31
@alessandro.francesconi I also added a WolframAlpha plot for you so that you can see the nonlinear shape of the gamma correction. – Timothy Shields Jul 12 '13 at 16:39

In theory, with a few pixels (3, in this case), you can determine what their algorithm is doing. Juste pick your three pixel (p1, p2, p3), their RGB value and their PGM gray value, and you have:

RedConstant * p1.redValue + GreenConstant * p1.greenValue + BlueConstant * p1.blueValue = p1.grayValue

RedConstant * p2.redValue + GreenConstant * p2.greenValue + BlueConstant * p2.blueValue = p2.grayValue

RedConstant * p3.redValue + GreenConstant * p3.greenValue + BlueConstant * p3.blueValue = p3.grayValue.

Then solve this problem (look up "equation solver" or something) and see what are the constants they use.

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Thanks but, no, it doesn't work. I put 3 pixel values and solved a three-equations system. It results in three constants that are good for those equations and not for a fourth pixel. – alessandro.francesconi Jul 12 '13 at 14:19
1) Are you sure you picked the same pixels for RGB and gray value? 2) from this article: tannerhelland.com/3643/grayscale-image-algorithm-vb6 I saw that they were several different RGB-to-PGM algorithm. Try them all and try to discover which one is used. Good luck! – Fabinout Jul 12 '13 at 14:27
What if I tell you that I didn't find any valid method? – alessandro.francesconi Jul 12 '13 at 14:51
Well, GIMP probably use their own weird algorithm, what is the real purpose of trying to recreate exactly their converter? – Fabinout Jul 12 '13 at 15:05
The process of PGM convertion is a subpart of a longer algorithm. After some tests, I've seen that the results of such algorithm are better if I use a "GIMP" PGM image as input, and not a simpler version created with all those methods. So I though that the real PGM format describes pixel values in a way that seem to be more... "manageable" by my algorithm. I've also tried to look at GIMP's code, I've found a possible convertion point but it's not so readable... – alessandro.francesconi Jul 12 '13 at 16:20