Why my butterworth low pass filter doesn't work?
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I want to do a low pass filter, in order to test if my filter work properly, I first use a simple data to test. I compose a data with two frequency,one is 100Hz and the other is 300Hz in a cosine function. I make a low pass filter for a cut off frequceny of 300Hz, but the result seems to be wrong,the 300Hz signal still exist in my filtered data, anybody can help me to find the problem? Many thanks! here is my code:
clear;
clc;
fs=1000; % samping frequency
fc=300; % cutoff frequecny
t=0:1/fs:0.6;
xc=length(t);
f1=100; % frequency for composing my data
f2=300; % frequency for composing my data
x=cos(2*pi*f1*t)+cos(2*pi*f2*t); % raw data
n=numel(x);
f=(transpose(((0:n-1)*(fs/n)))); %Frequency
v=fft(x,n); %Discrete Fourier Transform
plot(f,real(v),'r');
grid on
Wn=2*fc/fs; % the normalized cutoff frequency for butter function
nn=6; % the order
[b,a] = butter(nn,Wn,'low');
nv=filtfilt(b,a,v);
vv=ifft(nv);
subplot(2,1,1)
plot(f,nv)
subplot(2,1,2)
plot(t,real(vv),'r')
Respuesta aceptada
Honglei Chen
el 17 de Abr. de 2012
I don't understand. I modified your code a bit to do
- Use filter operation in time domain
- Use 200Hz as cutoff frequency
- Examine magnitude of spectrum
The result looks pretty good
clear;
clc;
fs=1000; % samping frequency
fc=200; % cutoff frequecny
t=0:1/fs:0.6;
xc=length(t);
f1=100; % frequency for composing my data
f2=300; % frequency for composing my data
x=cos(2*pi*f1*t)+cos(2*pi*f2*t); % raw data
n=numel(x);
f=(transpose(((0:n-1)*(fs/n)))); %Frequency
v=fft(x,n); %Discrete Fourier Transform
plot(f,abs(v),'r');
grid on
Wn=2*fc/fs; % the normalized cutoff frequency for butter function
nn=6; % the order
[b,a] = butter(nn,Wn,'low');
nv=filter(b,a,x);
vv=fft(nv);
subplot(2,1,1)
plot(f,abs(vv));
subplot(2,1,2)
plot(t,real(nv),'r')
1 comentario
Betsey
el 17 de Abr. de 2012
Más respuestas (3)
Honglei Chen
el 17 de Abr. de 2012
0 votos
Please format your code. But just a quick note, if you set cutoff frequency at 300Hz, the 300Hz component will not be eliminated, only reduced by half.
4 comentarios
Betsey
el 17 de Abr. de 2012
Honglei Chen
el 17 de Abr. de 2012
Hi Betsey, that's the definition for cutoff frequency, which corresponds to 3dB reduction from passband. You can try setting cutoff frequency at 200Hz, then your 300Hz component should be greatly reduced.
Betsey
el 17 de Abr. de 2012
Honglei Chen
el 17 de Abr. de 2012
I looked at your code, why are you filtering v, which is the spectrum of the signal x? It should be just nv = filtfilt(b,a,x).
I'm not sure if you intentionally chose filtfilt, but you could just use filter
Finally you may want to plot abs(v) instead of real(v). After you get nv, you also want to plot abs(fft(nv)) to examine the spectrum of the output signal
Betsey
el 17 de Abr. de 2012
0 votos
1 comentario
Honglei Chen
el 17 de Abr. de 2012
Then the operation in frequency domain should be multiply, not convolution and after all, it is the same as the convolution in time domain
Betsey
el 17 de Abr. de 2012
0 votos
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