I'm trying to get some grip on Python's fft functionality, and one of the weird things that I've stumbled on is that Parseval's theorem doesn't seem to apply, as it gives a difference of about 50 now, while it should be 0.

```
import numpy as np
import matplotlib.pyplot as plt
import scipy.fftpack as fftpack
pi = np.pi
tdata = np.arange(5999.)/300
dt = tdata[1]-tdata[0]
datay = np.sin(pi*tdata)+2*np.sin(pi*2*tdata)
N = len(datay)
fouriery = abs(fftpack.rfft(datay))/N
freqs = fftpack.rfftfreq(len(datay), d=(tdata[1]-tdata[0]))
df = freqs[1] - freqs[0]
parceval = sum(datay**2)*dt - sum(fouriery**2)*df
print parceval
plt.plot(freqs, fouriery, 'b-')
plt.xlim(0,3)
plt.show()
```

I'm pretty sure that it's a normalisation factor, but I don't seem to be able to find it, as all the information I can find about this function is the scipy.fftpack.rfft documentation.