Given sampling rate `FSample`

and transform blocksize `N`

, you can calculate the frequency resolution `deltaF`

, sampling interval `deltaT`

, and total capture time `capT`

using the relationships:

```
deltaT = 1/FSample = capT/N
deltaF = 1/capT = FSample/N
```

Keep in mind also that the FFT returns value from `0`

to `FSample`

, or equivalently `-FSample/2`

to `FSample/2`

. In your plot, you're already dropping the `-FSample/2`

to `0`

part. NumPy includes a helper function to calculate all this for you: fftfreq.

For your values of `deltaT = 1 hour`

and `N = 576`

, you get `deltaF = 0.001736 cycles/hour = 0.04167 cycles/day`

, from `-0.5 cycles/hour`

to `0.5 cycles/hour`

. So if you have a magnitude peak at, say, bin 48 (and bin 528), that corresponds to a frequency component at `48*deltaF = 0.0833 cycles/hour = 2 cycles/day.`

In general, you should apply a window function to your time domain data before calculating the FFT, to reduce spectral leakage. The Hann window is almost never a bad choice. You can also use the `rfft`

function to skip the `-FSample/2, 0`

part of the output. So then, your code would be:

```
ft = np.fft.rfft(signal*np.hanning(len(signal)))
mgft = abs(ft)
xVals = np.fft.fftfreq(len(signal), d=1.0) # in hours, or d=1.0/24 in days
plot(xVals[:len(mgft)], mgft)
```