Earlier I read about mozjpeg. A project from Mozilla to create a jpeg encoder that is more efficient, i.e. creates smaller files.

As I understand (jpeg) codecs, a jpeg encoder would need to create files that use an encoding scheme that can also be decoded by other jpeg codecs. So how is it possible to improve the codec without breaking compatibility with other codecs?

Mozilla does mention that the first step for their encoder is to add functionality that can detect the most efficient encoding scheme for a certain image, which would not break compatibility. However, they intend to add more functionality, first of which is "trellis quantization", which seems to be a highly technical algorithm to do something (I don't understand).

I'm also not entirely sure this quetion belongs on stack overflow, it might also fit superuser, since the question is not specifically about programming. So if anyone feels it should be on superuser, feel free to move this question


JPEG is somewhat unique in that it involves a series of compression steps. There are two that provide the most opportunities for reducing the size of the image.

The first is sampling. In JPEG one usually converts from RGB to YCbCR. In RGB, each component is equal in value. In YCbCr, the Y component is much more important than the Cb and Cr components. If you sample the later at 4 to 1, a 4x4 block of pixels gets reduced from 16+16+16 to 16+1+1. Just by sampling you have reduced the size of the data to be compressed by nearly 1/3.

The other is quantization. You take the sampled pixel values, divide them into 8x8 blocks and perform the Discrete Cosine transform on them. In 8bpp this takes 8x8 8-bit data and converts it to 8x8 16 bit data (inverse compression at that point).

The DCT process tends to produce larger values in the upper right corner and smaller values (close to zero) towards the lower left corner. The upper right coefficients are more valuable than the lower left coefficients.

The 16-bit values are then "quantized" (division in plain english).

The compression process defines an 8x8 quantization matrix. Divide the corresponding entry in the DCT coefficients by the value in the quantization matrix. Because this is integer division, the small values will go to zero. Long runs of zero values are combined using run-length compression. The more consecutive zeros you get, the better the compression.

Generally, the quantization values are much higher at the lower left than in the upper right. You try to force these DCT coefficients to be zero unless they are very large.

This is where much of the loss (not all of it though) comes from in JPEG.

The trade off is to get as many zeros as you can without noticeably degrading the image.

The choice of quantization matrices is the major factor in compression. Most JPEG libraries present a "quality" setting to the user. This translates into the selection of a quantization matrices in the encoder. If someone could devise better quantization matrices, you could get better compression.

This book explains the JPEG process in plain English:


  • So, if I understand you correctly, one could run a new algorithm on an image that better decides what data to throw away? And you can throw away as much as you'd like, as long as you correctly write your data in the jpeg format? – Simon Verbeke Mar 8 '14 at 21:31
  • That's pretty much correct. You would have to run this process over uncompressed JPEG data. Each time you decompress with different quantization tables you loss more data. At the high level, you say "What is the most data I can discard while varying the image by no more than X". – user3344003 Mar 10 '14 at 20:09
  • I think you might be confusing the right/left sides on the DCT matrix. In the most common writing, the "most valuable" values are on the top left, not the top right. – Display Name Oct 24 '17 at 7:21

JPEG provides you multiple options. E.g. you can use standard Huffman tables or you can generate Huffman tables optimal for a specific image. The same goes for quantization tables. You can also switch to using arithmetic coding instead of Huffman coding for entropy encoding. The patents covering arithmetic coding as used in JPEG have expired. All of these options are lossless (no additional loss of data). One of the options used by Mozilla is instead of using baseline JPEG compression they use progressive JPEG compression. You can play with how many frequencies you have in each scan (SS, spectral selection) as well as number of bits used for each frequency (SA, successive approximation). Consecutive scans will have additional frequencies and or addition bits for each frequency. Again all of these different options are lossless. For the standard images used for JPEG switching to progressive encoding improved compression from 41 KB per image to 37 KB. But that is just for one setting of SS and SA. Given the speed of computers today you could automatically try many many different options and choose the best one.

Although hardly used the original JPEG standard had a lossless mode. There were 7 different choices for predictors. Today you would compress using each of the 7 choices and pick the best one. Use the same principle for what I outlined above. And remember non of them encounter additional loss of data. Switching between them is lossless.

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