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I'm playing with octave's fft functions, and I can't really figure out how to scale their output: I use the following (very short) code to approximate a function:

function y = f(x)
    y = x .^ 2;

Y = f(X);
# plot(X, Y);

F = fft(Y);
S = [0:2047]/2048;

function points = approximate(input, count)
    size    = size(input)(2);
    fourier = [fft(input)(1:count) zeros(1, size-count)];
    points  = ifft(fourier);

Y = f(X); plot(X, Y, X, approximate(Y, 10));

Basically, what it does is take a function, compute the image of an interval, fft-it, then keep a few harmonics, and ifft the result. Yet I get a plot that is vertically compressed (the vertical scale of the output is wrong). Any ideas?

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2 Answers 2

up vote 3 down vote accepted

You are probably doing it wrong. You remove all the "negative" frequencies in your code. You should keep both positive and negative low frequencies. Here is a code in python and the result. The plot has the right scale.

alt text

The code:

from __future__ import division

from scipy.signal import fft, ifft
import numpy as np

def approximate(signal, cutoff):
    fourier = fft(signal)
    size = len(signal)
    # remove all frequencies except ground + offset positive, and offset negative:
    fourier[1+cutoff:-cutoff] = 0
    return ifft(fourier)

def quad(x):
    return x**2

from pylab import plot

X = np.arange(-4096,4096)/64
Y = quad(X)

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Olivier, you rock :) That's exactly what I needed, Thanks! –  CFP May 8 '10 at 13:03
Although, what does the use of the negative -cutoff subscript do? –  CFP May 8 '10 at 17:35
CFP, glad you like it! -cutoff means the "cutoff to last" index, i.e., -1 means the last index. So the slice [size/2,-cutoff] means leave everything from half, except the cutoff last. A neater way would have been: fourier[cutoff+1:-cutoff]=0. –  Olivier Verdier May 8 '10 at 17:45
I had to use scipy.fftpack instead of scipy.signal. And I got /usr/local/lib/python2.7/dist-packages/numpy/core/numeric.py:460: ComplexWarning: Casting complex values to real discards the imaginary part return array(a, dtype, copy=False, order=order). And it did not plot anything (you should probably add show()). –  moose Jul 2 at 17:44
Why do you calculate size? –  moose Jul 2 at 17:47

You are throwing out the second half of the transform. The transform is Hermitian symmetric for real-valued inputs and you have to keep those lines. Try this:

function points = approximate(inp, count)
    fourier = fft(inp);
    fourier((count+1):(length(fourier)-count+1)) = 0;
    points  = real(ifft(fourier)); %# max(imag(ifft(fourier))) should be around eps(real(...))

The inverse transform will invariably have some tiny imaginary part due to numerical computation error, hence the real extraction.

Note that input and size are keywords in Octave; clobbering them with your own variables is a good way to get really weird bugs down the road!

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Great, thanks! I got it now. Do you know of good documentation sources about fft? –  CFP May 8 '10 at 13:04

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