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I use CUFFT to perform FFT Real-to-Complex(R2C) and iFFT Complex-to-Real operations(C2R).

As you know, performing FFT R2C to 2D image, you will get the 2D frequency spectrum of this image, moreover you will get the data of spectrum with size of N1 * (N2/2 + 1), according to ( http://docs.nvidia.com/cuda/cufft/index.html#unique_1110380025 ). If you will display the spectrum, you can notice that the pieces of spectrum is shifted in vertical direction(3) and forms only the right part of frequency spectrum, because we have the non-redundant spectrum data. We have the only N1 * (N2/2 + 1) due to we obtain complex values from real and hermitian symmetry is implied http://en.wikipedia.org/wiki/Hermitian_symmetry.

So, you are able to obtain the image, using C2R operation on the obtained spectrum, in result it will give you the image with size of N1 * N2 (1).

Now, let's consider my case.

I reconstruct 2D frequency spectrum from non-redundant spectrum data (4). This is topic of computed tomography, so I will not dig to details. I just say that it is possible to reconstruct the image from its projections, which were obtained under certain angles. In this case, there are 800 projections which covers angles from 0 to 180 and according to "Projection-slice theorem" it is possible to reconstruct the object, using this finite number of projections.

In general, I reconstruct the right part of spectrum in the center at coordinates (0, N1/2). So, for the successful result the FFT requires to shift the top and bottom spectrum data in the opposite directions (if we produce the spectrum by our own).

As the spectrum data was shifted, I use FFT on this and get the reconstructed image (2), the same as when I get spectrum from R2C operation but in this case, I reconstructed the spectrum by my own.

In this case, I got the reconstructed image, but it was(2) not what I expected(1). After this fault, I tied to shift the spectrum data in various direction but no one gave me the correct result. I tried to place the data on mine spectrum(4) in the same way as it on the spectrum produced by R2C operation(3).

Moreover, I tried to mirror spectrum in various directions(5). The best result(6) I got, when I cut the bottom part of the spectrum(7), it gave me unfinished reconstruction of the target object (1).

The main idea of this question: How I should shift spectrum data, to get the reconstructed image?

Target image (Reconstructed with another method) (1) Traget image

Bad reconstruction of the target object (2) Bad reconstruction of the target object

Spectrum is obtained with cuFFT - Real-to-Complex(3) Spectrum is obtained with cuFFT - Real-to-Complex

Reconstructed spectrum is placed as previous (4) Reconstructed spectrum is placed as previous

Mirrored reconstructed spectrum (5) Mirrored reconstructed spectrum

Reconstruction with a half of spectrum (6) Reconstruction with a half of spectrum

A half of spectrum (7) A half of spectrum used for (6)

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This is a very hard to follow question as written. Could you try and make it a little easier for others to follow? –  talonmies Mar 21 '13 at 12:01
@talonmies I have rephrased the question. –  Roman Shkarin Mar 21 '13 at 13:06
cufft and FFTW should be able to produce pretty similar results. Are you able to get proper results with FFTW? If so, describing how you did that should be instructive to how you might do the same thing with cufft. –  Robert Crovella Mar 21 '13 at 15:11
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