torch.fft.rfft¶
-
torch.fft.
rfft
(input, n=None, dim=- 1, norm=None, *, out=None) → Tensor¶ Computes the one dimensional Fourier transform of real-valued
input
.The FFT of a real signal is Hermitian-symmetric,
X[i] = conj(X[-i])
so the output contains only the positive frequencies below the Nyquist frequency. To compute the full output, usefft()
Note
Supports torch.half on CUDA with GPU Architecture SM53 or greater. However it only supports powers of 2 signal length in every transformed dimension.
- Parameters
input (Tensor) – the real input tensor
n (int, optional) – Signal length. If given, the input will either be zero-padded or trimmed to this length before computing the real FFT.
dim (int, optional) – The dimension along which to take the one dimensional real FFT.
norm (str, optional) –
Normalization mode. For the forward transform (
rfft()
), these correspond to:"forward"
- normalize by1/n
"backward"
- no normalization"ortho"
- normalize by1/sqrt(n)
(making the FFT orthonormal)
Calling the backward transform (
irfft()
) with the same normalization mode will apply an overall normalization of1/n
between the two transforms. This is required to makeirfft()
the exact inverse.Default is
"backward"
(no normalization).
- Keyword Arguments
out (Tensor, optional) – the output tensor.
Example
>>> t = torch.arange(4) >>> t tensor([0, 1, 2, 3]) >>> torch.fft.rfft(t) tensor([ 6.+0.j, -2.+2.j, -2.+0.j])
Compare against the full output from
fft()
:>>> torch.fft.fft(t) tensor([ 6.+0.j, -2.+2.j, -2.+0.j, -2.-2.j])
Notice that the symmetric element
T[-1] == T[1].conj()
is omitted. At the Nyquist frequencyT[-2] == T[2]
is it’s own symmetric pair, and therefore must always be real-valued.