After taking the Discrete Fourier Transform of some samples with scipy.fftpack.fft() and plotting the magnitude of these I notice that it doesn't equal the amplitude of the original signal. Is there a relationship between the two?
Is there a way to compute the amplitude of the original signal from the Fourier coefficients without reversing the transform?
Here's an example of sin wave with amplitude 7.0 and fft amplitude 3.5
from numpy import sin, linspace, pi from pylab import plot, show, title, xlabel, ylabel, subplot from scipy import fft, arange def plotSpectrum(y,Fs): """ Plots a Single-Sided Amplitude Spectrum of y(t) """ n = len(y) # length of the signal k = arange(n) T = n/Fs frq = k/T # two sides frequency range frq = frq[range(n/2)] # one side frequency range Y = fft(y)/n # fft computing and normalization Y = Y[range(n/2)] plot(frq,abs(Y),'r') # plotting the spectrum xlabel('Freq (Hz)') ylabel('|Y(freq)|') Fs = 150.0; # sampling rate Ts = 1.0/Fs; # sampling interval t = arange(0,1,Ts) # time vector ff = 5; # frequency of the signal y = 7.0 * sin(2*pi*ff*t) subplot(2,1,1) plot(t,y) xlabel('Time') ylabel('Amplitude') subplot(2,1,2) plotSpectrum(y,Fs) show()