8

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
17

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

Your Answer

By clicking “Post Your Answer”, you agree to our terms of service, privacy policy and cookie policy

Not the answer you're looking for? Browse other questions tagged or ask your own question.