I implemented a simple low pass filter in matlab using a forward and backward fft. It works in principle, but the minimum and maximum values differ from the original.

signal = data;
%% fourier spectrum
% number of elements in fft
NFFT = 1024;
% fft of data
Y = fft(signal,NFFT)/L;
% plot(freq_spectrum)

%% apply filter
fullw = zeros(1, numel(Y));
fullw( 1 : 20 ) = 1;
filteredData = Y.*fullw;

%% invers fft
iY = ifft(filteredData,NFFT);
% amplitude is in abs part
fY = abs(iY);
% use only the length of the original data
fY = fY(1:numel(signal));
filteredSignal = fY * NFFT; % correct maximum

clf; hold on;
plot(signal, 'g-')
plot(filteredSignal ,'b-')
hold off;

the resulting image looks like this

enter image description here

What am I doing wrong? If I normalize both data the filtered signal looks correct.

  • 1
    your filter needs to be symmetric as the signal is. why do you expect min and max to not change? there's no reason to. – thang Mar 2 '15 at 16:35
  • 2
    Note that trying to apply a "brick wall" filter like this in the frequency domain will produce nasty artefacts - you need to use a smooth function in the frequency domain (typically a window function). Note also that your filter gain is not normalised, and as @thang notes, your filter should be symmetric, otherwise you'll get complex time domain output data. – Paul R Mar 2 '15 at 16:42

Just to remind ourselves of how MATLAB stores frequency content for Y = fft(y,N):

  • Y(1) is the constant offset
  • Y(2:N/2 + 1) is the set of positive frequencies
  • Y(N/2 + 2:end) is the set of negative frequencies... (normally we would plot this left of the vertical axis)

In order to make a true low pass filter, we must preserve both the low positive frequencies and the low negative frequencies.

Here's an example of doing this with a multiplicative rectangle filter in the frequency domain, as you've done:

% make our noisy function
t = linspace(1,10,1024);
x = -(t-5).^2  + 2;
y = awgn(x,0.5); 
Y = fft(y,1024);

r = 20; % range of frequencies we want to preserve

rectangle = zeros(size(Y));
rectangle(1:r+1) = 1;               % preserve low +ve frequencies
y_half = ifft(Y.*rectangle,1024);   % +ve low-pass filtered signal
rectangle(end-r+1:end) = 1;         % preserve low -ve frequencies
y_rect = ifft(Y.*rectangle,1024);   % full low-pass filtered signal

hold on;
plot(t,y,'g--'); plot(t,x,'k','LineWidth',2); plot(t,y_half,'b','LineWidth',2); plot(t,y_rect,'r','LineWidth',2);
legend('noisy signal','true signal','+ve low-pass','full low-pass','Location','southwest')

enter image description here

The full low-pass fitler does a better job but you'll notice that the reconstruction is a bit "wavy". This is because multiplication with a rectangle function in the frequency domain is the same as a convolution with a sinc function in the time domain. Convolution with a sinc fucntion replaces every point with a very uneven weighted average of its neighbours, hence the "wave" effect.

A gaussian filter has nicer low-pass filter properties because the fourier transform of a gaussian is a gaussian. A gaussian decays to zero nicely so it doesn't include far-off neighbours in the weighted average during convolution. Here is an example with a gaussian filter preserving the positive and negative frequencies:

gauss = zeros(size(Y));
sigma = 8;                           % just a guess for a range of ~20
gauss(1:r+1) = exp(-(1:r+1).^ 2 / (2 * sigma ^ 2));  % +ve frequencies
gauss(end-r+1:end) = fliplr(gauss(2:r+1));           % -ve frequencies
y_gauss = ifft(Y.*gauss,1024);

hold on;
plot(t,x,'k','LineWidth',2); plot(t,y_rect,'r','LineWidth',2); plot(t,y_gauss,'c','LineWidth',2);
legend('true signal','full low-pass','gaussian','Location','southwest')

enter image description here

As you can see, the reconstruction is much better this way.

  • 1
    Very nice explanation. I admit that I tend to forget that the fourier space is folded and filtering needs to be done on both sides. – Matthias Pospiech Mar 3 '15 at 8:18

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