in a nutshell: I can't extract meaningful light intensities out of RGB values from JPEG photos, and trying to account for gamma correction or sRGB only makes matters worse.
I'm doing a toy project, which involves processing a bunch of photo images, shot with an intervalometer. Basically, I want to make a time lapse out of them, with some corrections so that the clips are neater. I use Canon dSLRs.
I need a function, which, given a JPEG file, figures out the "average scene brightness". The result should be a simple number; no need to be expressed in any absolute photometric unit, I'm doing only relative comparisons. So, for example, you take a picture of some room, and the function returns, say, "5.0". Then you add a second light bulb to the lighting, exactly the same type as the first, placed next to it, and shoot again. The function should now give you "10.0".
So, my current implementation of this function combines several things: ISO speed, shutter speed, aperture (extracted from EXIF) and the average image brightness. The Exif stuff is obviously more important, because, in automatic modes, the camera would try to use such and such settings, so the image brightness comes around the mid-gray point. Yet, the ISO/Shutter/Aperture settings all have a resolution of 1/3 stop or less, thus detecting the image brightness is important for "fine tuning".
As I was doing it, I was getting some visibly bogus results, and the more I dug in, the more puzzled I got. So in the end I set up an "almost serious" experiment:
Test setup: A simple wall in a room, lit with an incandescent lamp, the illumination is quite even. Used two cameras to compare the results: 5D with a 50mm prime, 350D with a 35mm prime. Distance to the wall: around 3 metres. All photos are shot at 1/10 s shutter speed. Camera settings: manual, "faithful mode" (no enhancements, no saturation or contrast bump), Tungsten WB, no custom functions, JPEG-Fine, sRGB colorspace. The lenses have no filters. The illumination doesn't change, I only vary the ISO and aperture settings. Here are the results I got:
Avg Spd ISO Aperture 1. 0.3507, 0.10, 100, f/2.8 2. 0.5382, 0.10, 200, f/2.8 3. 0.3557, 0.10, 200, f/4.0 4. 0.2709, 0.10, 200, f/5.0 5. 0.2118, 0.10, 200, f/5.6 6. 0.1718, 0.10, 200, f/6.3 7. 0.1459, 0.10, 200, f/7.1 8. 0.1112, 0.10, 200, f/8.0 9. 0.0883, 0.10, 200, f/9.0
The first column is the average pixel value (straight from JPEG), averaged over the whole image, with conversion to grayscale as (R+G+B)/3. The colors are normalized in the [0..1] range by dividing the [0..255] range by 255. So, between 1) and 2), I only change the ISO settings, the image should become twice as bright, but the average pixel value only goes up 53% (there aren't any overexposed areas).
2..3: Aperture one stop down, so the image should become half as bright, so 1) and 3) agree (the extra brightness is probably due to reduced vignetting)
3..5: Again, one stop down, 5) should be half as bright as 3)
5..8: Same, should be half (this is basically okay though).
All this is very, very strange. Btw, the results between the two cameras are in agreement, suggesting that this isn't just a peculiarity of the specific model.
This is without applying any gamma correction. The JPEG reading code is in C++ and basically follows the IJG sample code (the
djpeg utility). Now, JPEG saves gamma-corrected values, so the pixel values should be treated as values in the sRGB color space (get source pixels, convert to [0..1], and apply the sRGB->linear RGB transform. Let's try that:
Avg Spd ISO Aperture 1. 0.1140, 0.10, 100, f/2.8 2. 0.2746, 0.10, 200, f/2.8 3. 0.1175, 0.10, 200, f/4.0 4. 0.0682, 0.10, 200, f/5.0 5. 0.0424, 0.10, 200, f/5.6 6. 0.0287, 0.10, 200, f/6.3 7. 0.0213, 0.10, 200, f/7.1 8. 0.0133, 0.10, 200, f/8.0 9. 0.0092, 0.10, 200, f/9.0
I also tried "plain" gamma correction (gamma = 2.2), the results are very similar to the sRGB-correction case.
So I am very, very puzzled. Can someone please explain how the RGB intensities from camera JPEGs should really be interpreted as, since I'm out of ideas :)