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I want to use a GPU-accelerated algorithm, to perform a fast and memory saving dft. But, when I perform the gpu::dft, the destination matrix is scaled as it is explained in the documentation. How I can avoid this problem with the scaling of the width to dft_size.width / 2 + 1? Also, why is it scaled like this? My Code for the DFT is this:

cv::gpu::GpuMat d_in, d_out;
d_in = in;
d_out.create(d_in.size(), CV_32FC2 );
cv::gpu::dft( d_in, d_out, d_in.Size );

where in is a CV_32FC1 matrix, which is 512x512.

The best solution would be a destination matrix which has the size d_in.size and the type CV_32FC2.

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2 Answers 2

up vote 4 down vote accepted

This is due to complex conjugate symmetry that is present in the output of an FFT. Intel IPP has a good description of this packing (the same packing is used by OpenCV). The OpenCV dft function also describes this packing.

So, from the gpu::dft documentation we have:

If the source matrix is complex and the output is not specified as real, the destination matrix is complex and has the dft_size size and CV_32FC2 type.

So, make sure you pass a complex matrix to the gpu::dft function if you don't want it to be packed. You will need to set the second channel to all zeros:

Mat realData;

// ... get your real data...

Mat cplxData = Mat::zeros(realData.size(), realData.type());

vector<Mat> channels;

Mat fftInput;
merge(channels, fftInput);

GpuMat fftGpu(fftInput.size(), fftInput.type());

// do the gpu::dft here...

There is a caveat though...you get about a 30-40% performance boost when using CCS packed data, so you will lose some performance by using the full-complex output.

Hope that helps!

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Thanks a lot for the explanations. This works! If I'll have very big pictures someday, I'll change to the CCS packed data format. Also thanks for the links. –  reinhar2 Dec 19 '11 at 15:27
No problem! Glad to help :) –  mevatron Dec 19 '11 at 16:29
I'd just like to add that OpenCV's gpu::dft does NOT use Intel's CCS format, unlike the non-gpu dft function. Instead it uses cuFFT's packed format. The difference is that CCS is a single channel image of the same dimensions as the real image, and cuFFT is a two-channel image at roughly half the width. –  may5694 Jul 17 '14 at 15:46

Scaling is done for obtaining the result within the range of +/- 1.0. This is the most useful form for most applications that need to deal with frequency representation of the data. For retrieving a result which is not scaled just don't enable the DFT_SCALE flag.


The width of the result is scaled, because it is symmetric. So all you have to do is append the former values in a symmetric fashion.

The spectrum is symmetric, because at half of the width the sampling theorem is fulfilled. For example a 2048 point DFT for a signal source with a samplerate of 48 kHz can only represent values up to 24 kHz and this value is represented at half of the width.

Also for reference take a look at Spectrum Analysis Using the Discrete Fourier Transform.

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I don't mean the scaling of the values of the result of the dft. I mean the scaling of the width of the result. –  reinhar2 Dec 19 '11 at 14:47
Ah, now i've got it. Made an edit. –  Sebastian Dressler Dec 19 '11 at 14:55
yeah...there is my problem: just imagine I have got a 8x8 matrix and I would transform it. My result would be 5x8 and not 4x8. This means, there are columns, I don't have to mirror. –  reinhar2 Dec 19 '11 at 15:12
This has nothing to do with the input, but with the output. Take a look at the answer of @mevatron, maybe that helps. –  Sebastian Dressler Dec 19 '11 at 15:15
Thanks for your help, too. It was just a thingof the CCS packing I didn't know about. Also thanks for the link. –  reinhar2 Dec 19 '11 at 15:31

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