Thanks in advance for any help on this subject. I've recently been trying to work out Parseval's theorem for discrete fourier transforms when noise is included. I based my code from this code.
What I expected to see is that (as when no noise is included) the total power in the frequency domain is half that of the total power in the time-domain, as I have cut off the negative frequencies.
However, as more noise is added to the time-domain signal, the total power of the fourier transform of the signal+noise becomes much less than half of the total power of the signal+noise.
My code is as follows:
import numpy as np import numpy.fft as nf import matplotlib.pyplot as plt def findingdifference(randomvalues): n = int(1e7) #number of points tmax = 40e-3 #measurement time f1 = 30e6 #beat frequency t = np.linspace(-tmax,tmax,num=n) #define time axis dt = t-t #time spacing gt = np.sin(2*np.pi*f1*t)+randomvalues #make a sin + noise fftfreq = nf.fftfreq(n,dt) #defining frequency (x) axis hkk = nf.fft(gt) # fourier transform of sinusoid + noise hkn = nf.fft(randomvalues) #fourier transform of just noise fftfreq = fftfreq[fftfreq>0] #only taking positive frequencies hkk = hkk[fftfreq>0] hkn = hkn[fftfreq>0] timedomain_p = sum(abs(gt)**2.0)*dt #parseval's theorem for time freqdomain_p = sum(abs(hkk)**2.0)*dt/n # parseval's therom for frequency difference = (timedomain_p-freqdomain_p)/timedomain_p*100 #percentage diff tdomain_pn = sum(abs(randomvalues)**2.0)*dt #parseval's for time fdomain_pn = sum(abs(hkn)**2.0)*dt/n # parseval's for frequency difference_n = (tdomain_pn-fdomain_pn)/tdomain_pn*100 #percent diff return difference,difference_n def definingvalues(max_amp,length): noise_amplitude = np.linspace(0,max_amp,length) #defining noise amplitude difference = np.zeros((2,len(noise_amplitude))) randomvals = np.random.random(int(1e7)) #defining noise for i in range(len(noise_amplitude)): difference[:,i] = (findingdifference(noise_amplitude[i]*randomvals)) return noise_amplitude,difference def figure(max_amp,length): noise_amplitude,difference = definingvalues(max_amp,length) plt.figure() plt.plot(noise_amplitude,difference[0,:],color='red') plt.plot(noise_amplitude,difference[1,:],color='blue') plt.xlabel('Noise_Variable') plt.ylabel(r'Difference in $\%$') plt.show() return figure(max_amp=3,length=21)
My final graph looks like this figure. Am I doing something wrong when working this out? Is there an physical reason that this trend occurs with added noise? Is it to do with doing a fourier transform on a not perfectly sinusoidal signal? The reason I am doing this is to understand a very noisy sinusoidal signal that I have real data for.