# Decomposing an image into two frequency components using DCT?

I am a beginner in digital image processing field, recently I am working on a project where I have to decompose an image into two frequency components namely (low and high) using DCT. I searched a lot on web and I found that MATLAB has a built-in function for Discrete Cosine Transform which is used like this:

``````dct_img = dct2(img);
``````

where `img` is input image and `dct_img` is resultant DCT of `img`.

Question

My question is, "How can I decompose the dct_img into two frequency components namely low and high frequency components".

• down voters please mention your comments, its a difficult question for me, hopefully not for you, :) Mar 11, 2014 at 10:10
• Not the downvoter, but I guess you got the downvote because you cross-posted in DSP forum. Anyway it's a good question on fundamental stuffs, and +1. Thanks Mar 14, 2014 at 15:01

As you've mentioned, `dct2` and `idct2` will do most of the job for you. The question that remains is then: What is high frequency and what is low frequency content? The coefficients after the 2 dimensional transform will actually represent two frequencies each (one in x- and one in y-direction). The following figure shows the bases for each coefficient in an 8x8 discrete cosine transform:

Therefore, that question of low vs. high can be answered in different ways. A common way, which is also used in the JPEG encoding, proceeds diagonally from zero-frequency downto the max as shown above. As we can see in the following example that is mostly motivated because natural images are largely located in the "top left" corner of "low" frequencies. It is certainly worth looking at the result of `dct2` and play around with the actual choice of your regions for high and low.

In the following I'm dividing the spectrum diagonally and also plotting the DCT coefficients - in logarithmic scale because otherwise we would just see one big peak around `(1,1)`. In the example I'm cutting far above half of the coefficients (adjustable with `cutoff`) we can see that the high-frequency part ("HF") still contains some relevant image information. If you set `cutoff` to `0` or below only noise of small amplitude will be left.

``````%// Load an image
%// Transform
Orig_T = dct2(Orig);
%// Split between high- and low-frequency in the spectrum (*)
cutoff = round(0.5 * 256);
High_T = fliplr(tril(fliplr(Orig_T), cutoff));
Low_T = Orig_T - High_T;
%// Transform back
High = idct2(High_T);
Low = idct2(Low_T);

%// Plot results
figure, colormap gray
subplot(3,2,1), imagesc(Orig), title('Original'), axis square, colorbar
subplot(3,2,2), imagesc(log(abs(Orig_T))), title('log(DCT(Original))'),  axis square, colorbar

subplot(3,2,3), imagesc(log(abs(Low_T))), title('log(DCT(LF))'), axis square, colorbar
subplot(3,2,4), imagesc(log(abs(High_T))), title('log(DCT(HF))'), axis square, colorbar

subplot(3,2,5), imagesc(Low), title('LF'), axis square, colorbar
subplot(3,2,6), imagesc(High), title('HF'), axis square, colorbar
``````

(*) Note on `tril`: The lower triangle-function operates with respect to the mathematical diagonal from top-left to bottom-right, since I want the other diagonal I'm flipping left-right before and afterwards.

Also note that this kind of operations are not usually applied to entire images, but rather to blocks of e.g. 8x8. Have a look at `blockproc` and this article.

• @mbschenkel, will this work for images of size MxN too?? (where M is not equal to N) Apr 6, 2018 at 7:18
• @MayankTiwari: Conceptually this is independent on the image size, in particular if you operate on sub-blocks as mentioned in the last sentence: Then you just need to brake it down into `m*n` square sub-blocks such that `M=K*m, N=K*n`. The specific code however was written as an illustration, and may not work for the general case. Is that the reason for your question? Apr 8, 2018 at 11:23

An easy example:

``````I2 = dct_img;
I2(8:end,8:end) = 0;
I3 = idct2(I2);
imagesc(I3)
``````

`I3` can be seen as the image after low pass filter (the low frequency components), then `idct2(dct_img - I2)` can be viewed as high frequency.