iPhone Accelerate Framework FFT vs Matlab FFT

I do not have much math background but part of the project I am working on requires the FFT of a single vector. The matlab function fft(x) works accurately for what I need, but after trying to set up the Accelerate Framework fft functions I get completely inaccurate results. If anyone has more expertise/experience with Accelerate Framework fft I could really use some help trying to figure out what I am doing wrong. I based my fft set-up off an example I found on google, but there were no tutorials or anything that produced different results.

EDIT1: Changed around some stuff based on the answers so far. It seems to be doing calculations but it doesnt output them in any way close to that of matlab

This is the documentation for fft for matlab: http://www.mathworks.com/help/techdoc/ref/fft.html

** NOTE: for example purposes, the x array will be {1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16} in both examples

Matlab Code:

``````x = fft(x)
``````

Matlab output:

``````x =

1.0e+02 *

Columns 1 through 4

1.3600            -0.0800 + 0.4022i  -0.0800 + 0.1931i  -0.0800 + 0.1197i

Columns 5 through 8

-0.0800 + 0.0800i  -0.0800 + 0.0535i  -0.0800 + 0.0331i  -0.0800 + 0.0159i

Columns 9 through 12

-0.0800            -0.0800 - 0.0159i  -0.0800 - 0.0331i  -0.0800 - 0.0535i

Columns 13 through 16

-0.0800 - 0.0800i  -0.0800 - 0.1197i  -0.0800 - 0.1931i  -0.0800 - 0.4022i
``````

Objective C code:

``````int log2n = log2f(16);

FFTSetupD fftSetup = vDSP_create_fftsetupD (log2n, kFFTRadix2);

DSPDoubleSplitComplex fft_data;
fft_data.realp = (double *)malloc(8 * sizeof(double));
fft_data.imagp = (double *)malloc(8 * sizeof(double));

vDSP_ctoz((COMPLEX *) ffx, 2, &fft_data, 1, nOver2); //split data (1- 16) into odds and evens

vDSP_fft_zrip (fftSetup, &fft_data, 1, log2n, kFFTDirection_Forward); //fft forward

vDSP_fft_zrip (fftSetup, &fft_data, 1, log2n, kFFTDirection_Inverse); //fft inverse

vDSP_ztoc(&fft_data, 2, (COMPLEX *) ffx, 1, nOver2); //combine complex back into real numbers
``````

Objective C output:

ffx now contains:

``````272.000000
-16.000000
-16.000000
-16.000000
0.000000
0.000000
0.000000
0.000000
0.000000
10.000000
11.000000
12.000000
13.000000
14.000000
15.000000
16.000000
``````
-
Isn't the log2n value passed to vDSP_fft_zripD supposed to be an integer value? – Eelke May 30 '12 at 16:44
Yes, you need to work with FFTs which are an integer power of 2. You're passing (int)log2(10) = 3 which tells the FFT routine that your FFT size is 8. – Paul R May 30 '12 at 16:47
The parameter is of type "vDSP_Length", but I tried doing 16 elements (base 2) using an integer and comparing it to matlab and the values were still incorrect. – MrHappyAsthma May 30 '12 at 16:47
Try putting together a valid example where you pass correct parameters and replace the example above with it (assuming it still doesn't work as you expected). – Paul R May 30 '12 at 16:48
May be a really ignorant question, but you say you are filling with 1 - 16, but I see you filling with x[i]. What is x truly filled with (zeros)? – trumpetlicks May 30 '12 at 19:30

One big problem: C arrays are indexed from 0, unlike MATLAB arrays which are 1-based. So you need to change your loop from

``````for(int i = 1; i <= 16; i++)
``````

to

``````for(int i = 0; i < 16; i++)
``````

A second, big problem - you're mixing single precision (`float`) and double precision (`double`) routines. Your data is `double` so you should be using `vDSP_ctozD`, not `vDSP_ctoz`, and `vDSP_fft_zripD` rather than `vDSP_fft_zrip`, etc.

Another thing to watch out for: different FFT implementations use different definitions of the DFT formula, particularly in regard to scaling factor. It looks like the MATLAB FFT includes a 1/N scaling correction, which most other FFTs do not.

Here is a complete working example whose output matches Octave (MATLAB clone):

``````#include <stdio.h>
#include <stdlib.h>
#include <Accelerate/Accelerate.h>

int main(void)
{
const int log2n = 4;
const int n = 1 << log2n;
const int nOver2 = n / 2;

FFTSetupD fftSetup = vDSP_create_fftsetupD (log2n, kFFTRadix2);

double *input;

DSPDoubleSplitComplex fft_data;

int i;

input = malloc(n * sizeof(double));
fft_data.realp = malloc(nOver2 * sizeof(double));
fft_data.imagp = malloc(nOver2 * sizeof(double));

for (i = 0; i < n; ++i)
{
input[i] = (double)(i + 1);
}

printf("Input\n");

for (i = 0; i < n; ++i)
{
printf("%d: %8g\n", i, input[i]);
}

vDSP_ctozD((DSPDoubleComplex *)input, 2, &fft_data, 1, nOver2);

printf("FFT Input\n");

for (i = 0; i < nOver2; ++i)
{
printf("%d: %8g%8g\n", i, fft_data.realp[i], fft_data.imagp[i]);
}

vDSP_fft_zripD (fftSetup, &fft_data, 1, log2n, kFFTDirection_Forward);

printf("FFT output\n");

for (i = 0; i < nOver2; ++i)
{
printf("%d: %8g%8g\n", i, fft_data.realp[i], fft_data.imagp[i]);
}

for (i = 0; i < nOver2; ++i)
{
fft_data.realp[i] *= 0.5;
fft_data.imagp[i] *= 0.5;
}

printf("Scaled FFT output\n");

for (i = 0; i < nOver2; ++i)
{
printf("%d: %8g%8g\n", i, fft_data.realp[i], fft_data.imagp[i]);
}

printf("Unpacked output\n");

printf("%d: %8g%8g\n", 0, fft_data.realp[0], 0.0); // DC
for (i = 1; i < nOver2; ++i)
{
printf("%d: %8g%8g\n", i, fft_data.realp[i], fft_data.imagp[i]);
}
printf("%d: %8g%8g\n", nOver2, fft_data.imagp[0], 0.0); // Nyquist

return 0;
}
``````

Output is:

``````Input
0:        1
1:        2
2:        3
3:        4
4:        5
5:        6
6:        7
7:        8
8:        9
9:       10
10:       11
11:       12
12:       13
13:       14
14:       15
15:       16
FFT Input
0:        1       2
1:        3       4
2:        5       6
3:        7       8
4:        9      10
5:       11      12
6:       13      14
7:       15      16
FFT output
0:      272     -16
1:      -16 80.4374
2:      -16 38.6274
3:      -16 23.9457
4:      -16      16
5:      -16 10.6909
6:      -16 6.62742
7:      -16  3.1826
Scaled FFT output
0:      136      -8
1:       -8 40.2187
2:       -8 19.3137
3:       -8 11.9728
4:       -8       8
5:       -8 5.34543
6:       -8 3.31371
7:       -8  1.5913
Unpacked output
0:      136       0
1:       -8 40.2187
2:       -8 19.3137
3:       -8 11.9728
4:       -8       8
5:       -8 5.34543
6:       -8 3.31371
7:       -8  1.5913
8:       -8       0
``````

Comparing with Octave we get:

``````octave-3.4.0:15> x = [ 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16 ]
x =

1    2    3    4    5    6    7    8    9   10   11   12   13   14   15   16

octave-3.4.0:16> fft(x)
ans =

Columns 1 through 7:

136.0000 +   0.0000i    -8.0000 +  40.2187i    -8.0000 +  19.3137i    -8.0000 +  11.9728i    -8.0000 +   8.0000i    -8.0000 +   5.3454i    -8.0000 +   3.3137i

Columns 8 through 14:

-8.0000 +   1.5913i    -8.0000 +   0.0000i    -8.0000 -   1.5913i    -8.0000 -   3.3137i    -8.0000 -   5.3454i    -8.0000 -   8.0000i    -8.0000 -  11.9728i

Columns 15 and 16:

-8.0000 -  19.3137i    -8.0000 -  40.2187i

octave-3.4.0:17>
``````

Note that the outputs from 9 to 16 are just a complex conjugate mirror image or the bottom 8 terms, as is the expected case with a real-input FFT.

Note also that we needed to scale the vDSP FFT by a factor of 2 - this is due to the fact that it's a real-to-complex FFT, which is based on an N/2 point complex-to-complex FFT, hence the outputs are scaled by N/2, whereas a normal FFT would be scaled by N.

-
I adjusted that. Didnt even notice the mistake, but it didn't fix my issue. – MrHappyAsthma May 31 '12 at 16:53
@MrHappyAsthma: OK - see edited answer above which now includes a full working example. – Paul R Jun 1 '12 at 9:19
Thank you so much for all of your help! That works for what I need. I found the documentation on this stuff quite confusing but you really helped clarify everything. You are the man! – MrHappyAsthma Jun 1 '12 at 17:43

I think it could also be an array packing issue. I have just been looking at their sample code, and I see they keep calling conversion routines like

``````vDSP_ctoz
``````

I dont think it is the full answer yet, but I also agree with Paul R.

By the way, just curiously if you go to Wolfram Alpha, they give a completely different answer for FFT{1,2,3,4,5,6,7,8,9,10,11,12,13,14,15,16}

-
I added vDSP_ctoz and vDSP_ztoc commands to convert from complex to real and vice versa. That you for that. It seems to be doing much more calculations than mostly all 0's before. However, it is still not accurate compared to matlab. (As for wolfram alpha being different, they might use a different Radix or something. All i know is that if I run the necessary calculations for my program on matlab, their fft(x) functions as I need it. So i am trying to replicate theirs as closely as possible). – MrHappyAsthma May 31 '12 at 17:28
What are the outputs from your program at this point, now that it is doing more work? It still could be a radix or weighting issue. – trumpetlicks May 31 '12 at 17:42
I updated the original post to contain the new outputs. – MrHappyAsthma May 31 '12 at 19:09

In MATLAB, it looks like you're doing an fft of 16 real values {1+0i, 2+0i, 3+0i, etc...} whereas in Accelerate you're doing an fft of 8 complex values {1+2i, 3+4i, 5+6i, etc...}

-
Do you know how I can make it so that I can do all real values on accelerate aswell? – MrHappyAsthma Jun 1 '12 at 5:50
@bob: no - he's trying to use a real-to-complex FFT which uses a weird packed format for the real-only input data – Paul R Jun 1 '12 at 12:35