# Problem description

I have employed the convolution theorem to calculate convolutions efficiently. Suppose there are two real signals `s1`

and `s2`

of length `N`

each. Then I can obtain the convolution from

```
import numpy as np
import numpy.fft as fft
size = len(s1)
fft_size = int(2 ** np.ceil(np.log2(2 * size - 1))) #The size for the FFT algorithm
S1 = fft.rfft(s1, fft_size) #Take FTs
S2 = fft.rfft(s2, fft_size)
convolution = fft.irfft(S1 * S2) #Take IFT
```

However, if I have a `k`

singals the `fft_size`

must be modified to read

```
fft_size = int(2 ** np.ceil(np.log2(k * size - 1)))
```

in order to avoid circular overlap.

Unfortunately, I do not know `k`

a priori. One option is to choose a maximum value `k_max`

but I would prefer to not have to use large amounts of memory if not absolutely necessary and I would prefer to not evaluate the FT again every time k changes.

# Question

Is it possible to do one of the following

- Take the FFT of the signal for
`k=1`

and "zero pad in Fourier space" as necessary? - Prevent circular wrapping in the FFT?