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()
```