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Effectively my question boils down to the following. In steganography, when one hides information in the DWT coefficients of an image, how can he obtain integer values for the pixels after taking the IDWT?

I've reached the point of frustration because I have read many papers so far and most aren't even clear on this. Most of the time the algorithm is summarised as:

  • convert secret text/image to binary (plus whatever encryption, e.g. Huffman encoding)

  • take DWT of cover image

  • hide binary data in the DWT coefficients

  • IDWT to obtain stego image with hidden data

Unfortunately, unless I am missing something this is how clear most papers tend to be. The problem is that somewhere in the transformations floating numbers appear. All the papers I've read use the 2D Haar transformation. But I've seen that in different forms and some papers don't even bother giving the equations for the sum and difference. For example, given a row in an array, I have seen it like:

[ A B C D E F ] -> [ (A+B) (C+D) (E+F) (A-B) (C-D) (E-F) ]

But I have also seen it as the average and difference, i.e. (A+B)/2 and (A-B) or even the sum and mean difference, i.e. (A+B) and (A-B)/2.

Needless to say, applying it in 2D you eventually have to divide by 4 somewhere. This is actually no problem with an image because all the pixels are initially integers and IDWT(DWT(image)) will give you back integers. The problem comes when you fiddle with the DWT coefficients. Because of the binary nature of the secret, when you obtain your stego image you will have pixel values with .00, .25, .50 and .75. This is a problem because when an image is saved all the intensity values are stored as integers. So when the receiver analyses the image, he has lost pixel information which in turn has globally affected the DWT coefficients.

This is infuriating because it seems to be either a trivial step for whoever does DWT steganography or a taboo. I've seen very few papers openly discussing this issue after the magic step of take-the-IDWT-and-boom-stego-image-you're-done. Some methods aren't even clear to me. One group said that you need to encode these floating differences in four values, say 00, 01, 10 and 11. Do this for every pixel, add this information somewhere in the file (e.g. in the description tag) and send it off all together. Other than the obvious security issue of this information being easily detected or lost to modification, a 512x512 cover image will require 512x512x2 ~ half a million 0s and 1s!

Another problem apparently with changing the DWT coefficients is the underflow/overflow of pixel intensity. After the inverse transformation the values may be just outside the [0,255] range. This will cause normalising all pixels when saving the image. What people have offered as a solution is adjusting the cover image before taking the DWT. Adjust the following intensities 0->1, 1->2, 255->254 and 254->253 and the rest of the values stay the same. That way after taking the inverse DWT no intensities will lie outside [0,255]. I guess it's a solution but is there anything better?


The only way I can make it work is if the forward transform is sum = (A+B)/2 and diff = (A-B)/2. and round the coefficients. After that any transform will give integers. However, also taking into account the hidden bits (0 or 1) in the coefficients, in restoring the original image the pixel values will be off anything from -4 to +4. This gives an intensity range [-4,259] which has be dealt with as discussed above. Without even accounting for overflowing the overall process changes most pixels by a few values that I can't seem to get any peak signal-to-noise ratio (PSNR) above 45 db. In contrast, if I keep everything as floats and use sum = A-B and diff = A-B for the forward transform, at the end comparing the cover and stego images I get PSNR ~ 55 db.

Example papers

[1] Rubén Castillo Soria, F., Fernández Torres, G., & Algredo-Badillo, I. (2012). A Lossless Data Hiding Technique based on AES-DWT.

[2] Nag, A., Biswas, S., Sarkar, D., & Sarkar, P. P. (2011). A novel technique for image steganography based on DWT and Huffman encoding. International Journal of Computer Science and Security, 4(6), 561-570.

[3] Ghasemi, E., Shanbehzadeh, J., & ZahirAzami, B. (2011, February). A steganographic method based on Integer Wavelet Transform and Genetic Algorithm. In Communications and Signal Processing (ICCSP), 2011 International Conference on (pp. 42-45). IEEE.

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1 Answer 1

up vote 2 down vote accepted

It turns out what I needed was the Integer Wavelet Transform (for Haar) which many describe as a lifting scheme. For the forward transform, the equations are:

sum = floor( (A+B)/2 )

diff = A-B

And for inverse:

A = sum + floor( (diff+1)/2 )

B = sum - floor( diff/2 )

All the values throughout the whole process are integers. The reason it works is because the equations have information about the even and odd parts and so there is no loss of information from rounding down. Even if one embeds binary information to the DWT coefficients and then take the inverse transform, the pixel intensities will differ from the original by -1, 0 or 1. Consequently, there are only values of 256 and -1 to worry about the underflow/overflow.

Now this problem becomes more manageable. The simplest solution I can think of is to embed the data normally and after the inverse transform go through the pixels and adjust any excess to 0 or 255. By noting the adjustment as binary (0 for -1 and 1 for +1) and the pixel indices, one can send this information. For example, one could write all this as a concatenated string of i, j, adj, etc, where i and j are the pixel indices with 3 digits in base 16 and adj is either 0 or 1. This string can then be further compressed, transformed or encrypted to make the repeating indices more obscure. Though circumstantial, in my case I had only 187 under/overflows, a staggering <1% of my original 0 and 255 values.

Now that the integer transform issue has been sorted, there are more solutions to the excess problem. Generally, one has to consider an embedding algorithm which tends to change fewer bits than random chance, e.g., matrix embedding. Or the use of searching algorithms that decide which cover image, or section of a specific cover image will result to the fewest changes based on the message to be encoded. A flavour of what I have been reading:

Soleimanpourmoghadam, M., Nezamabadi-pour, H., Farsangi, M. M., & Mahyabadi, M. (2012, May). A more secure steganography method based on pair-wise LSB matching via a quantum gravitational search algorithm. In Artificial Intelligence and Signal Processing (AISP), 2012 16th CSI International Symposium on (pp. 034-038). IEEE.

In conclusion, my faith in academia has been restored. It's interesting to note that the supermajority of the papers I've read are from Asia and the wording some times isn't polished enough. But that's just floor(half excuses).

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