Why JPEG compression processes image by 8x8 blocks instead of applying Discrete Cosine Transform to the whole image?


3 Answers 3


8 X 8 was chosen after numerous experiments with other sizes.

The conclusions of experiments are: 1. Any matrices of sizes greater than 8 X 8 are harder to do mathematical operations (like transforms etc..) or not supported by hardware or take longer time. 2. Any matrices of sizes less than 8 X 8 dont have enough information to continue along with the pipeline. It results in bad quality of the compressed image.

  • The link is dead. Is there another source?
    – Itai
    Nov 14, 2018 at 8:33
  • Then it stands to reason that in an updated spec, 16x16 blocks or 32x32 blocks would be more efficient. Sep 1, 2022 at 16:09

Because, that would take "forever" to decode. I don't remember fully now, but I think you need at least as many coefficients as there are pixels in the block. If you code the whole image as a single block I think you need to, for every pixel, iterate through all the DCT coefficients.

I'm not very good at big O calculations but I guess the complexity would be O("forever"). ;-)

For modern video codecs I think they've started using 16x16 blocks instead.

  • 3
    If you need to iterate on everything every iteration, it's O(n^2), not "forever", which is O(n!).
    – Triang3l
    Dec 19, 2012 at 10:45
  • I'm not sure about "forever" - I have a program, called "FourierPainter" and it performs the Fourier transformation and back to image in a split second. The whole image, mind you. And Fourier is not much different from DCT, makes slightly more calculations even (keep imaginary values as phases, whilst DCT doesn't). You can download the Fourier Painter yourself and check it: jcrystal.com/products/fp
    – shal
    May 2, 2018 at 12:36
  • Not really. It takes O(N log N) to do a full DCT, and O(N log M) with fixed M<<N to decode the image in 8x8 blocks. Oct 1, 2022 at 17:42

One good reason is that images (or at least the kind of images humans like to look at) have a high degree of information correlation locally, but not globally.

Every relatively smooth patch of skin, or piece of sky or grass or wall eventually ends in a sharp edge and is replaced by something entirely different. This means you still need a high frequency cutoff in order to represent the image adequately rather than just blur it out.

Now, because Fourier-like transforms like DCT "jumble" all the spacial information, you wouldn't be able to throw away any intermediate coefficients either, nor the high-frequency components "you don't like".

There are of course other ways to try to discard visual noise and reconstruct edges at the same time by preserving high frequency components only when needed, or do some iterative reconstruction of the image at finer levels of detail. You might want to look into space-scale representation and wavelet transforms.

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