‘My problem is -- after low pass filtering amplitude of the demodulated signal (19) becomes 2 times higher than original signal y (40).’
It really is not.
Here, I changed the first subplot so that ylim went from 0 to the previous maximum value of ylim, and that demonstrates that the amplitude is actually 1½ times higher than the demodulated signal, so the demodulated signal amplitude is actually 66% of the original signal. That can be seen in the RMS calculations (added at the end of the code).
This is of course to be expected, since much of the signal energy was removed in the filtering process.
fs = 100; % sampling frequency (Hz)
Ts = 1/fs;
f1 = 10; % Hz
f2 = 20;
f3 = 30;
t=(1:1000)*Ts; % time
t=t';
noise = (30*rand(1000, 1));
y = 10.*sin(2*pi*f1*t)+20*sin(2*pi*f2*t)+30*sin(2*pi*f3*t) + noise; % Noisy input signal
s = abs(fft(y)./500);
f = (1:length(y))/length(y).*fs;
f=f';
mod=y.*(exp(-1i*2*pi*f2*t)); % complex demodulation
[b,a] = butter(10,f2/(fs/2),'low'); % Butterworth filer
s4a = filtfilt(b,a,imag(mod));
s4b = filtfilt(b,a,real(mod));
s4 = sqrt(s4a.^2+s4b.^2); % Demodulated Amplitude
phase = atan2(s4a, s4b); % Demodulated Phase
subplot(3,1,1);
plot(t,y)
title('Noisy input signal');
xlabel('t')
grid
ylim([0 max(ylim)])
subplot(3,1,2);
plot(f,s)
title('FFT Spectrum of Input signal');
xlabel('f, Hz')
grid
subplot(3,1,3);
plot(t,s4)
title('Amplitude Demodulated signal at 20 Hz');
xlabel('t')
grid
Original_RMS = rms(y)
Filtered_RMS = rms(s4)
Filtered_RMS/Original_RMS
.
