Why does hilbert tranformer give a phase-shifted but amplitude-reduced signal?

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Yuzhen Lu il 10 Nov 2017

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Commentato: 叶 il 12 Dic 2022

I have performed hilbert transform by using a FIR hilbert filter rather than the matlab built-in hilbert function. An example code is as follows:

fx = 10;
t = linspace(0,1,512);
x = 0.5*cos(2*pi*fx*t); %sampled signal
h = firpm(26,[0.1 0.8],[1 1],'h');   % hilbert filter
xh = conv(x,h,'same'); %hilbert transform of x
figure;
plot(t, [x;xh]); legend('Original','Transformed');

The resulting figure is given as follows:

How to address the problem to obtain the result equivalent to that by using hilbert function ?

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Honglei Chen il 13 Nov 2017

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Apri in MATLAB Online

The phase shift is expected so I assume you are talking about the amplitude? This is because the filter is not ideal. If you do a

fvtool(h)

You can see that the magnitude response is not unity when the frequency is close to DC or Nyquest. In your case, the signal frequency is 10 and the sampling rate is 512, so that is close to DC so you see the attenuation. if you change your sampling rate to, say, 128, then the result would be similar to what you get from hilbert.

HTH

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Yuzhen Lu il 14 Nov 2017

Modificato: Yuzhen Lu il 14 Nov 2017

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Thanks!

Based on such analysis, if the passband is set such that the frequency of interest is covered, an amplitude-preserved signal should be recovered. But in practice it does not, as you see below. The FIR hilbert filter seems incomparable to the hiltert function based on Fourier transform anyway, and both cannot shed the Gibbs artifacts.

fx = 10;
t = linspace(0,1,512);
x = 0.5*cos(2*pi*fx*t); %sampled signal
h = firpm(26,[0.01 0.99],[1 1],'h'); % hilbert filter with a modifed passband
xh = conv(x,h,'same'); %hilbert transform of x
xh2 = (rms(x)/rms(xh))*xh; %amplitude corrrection based on RMS
figure;
plot(t,xh,'b-',t, xh2,'r-',t,imag(hilbert(x)),'c'); 
legend('Hilbert filter','Amplitude Corrected','Hilbert transform','Location','best');
figure;
plot(t,sqrt(xh.^2+x.^2),'b-',t,sqrt(xh2.^2+x.^2),'r-',t,abs(hilbert(x)),'c'); 
legend('Hilbert filter','Amplitude Corrected','Hilbert transform','Location','best');