torch.fft.rfft2¶
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torch.fft.rfft2(input, s=None, dim=(- 2, - 1), norm=None, *, out=None) → Tensor¶ Computes the 2-dimensional discrete Fourier transform of real
input. Equivalent torfftn()but FFTs only the last two dimensions by default.The FFT of a real signal is Hermitian-symmetric,
X[i, j] = conj(X[-i, -j]), so the fullfft2()output contains redundant information.rfft2()instead omits the negative frequencies in the last dimension.- Parameters
input (Tensor) – the input tensor
s (Tuple[int], optional) – Signal size in the transformed dimensions. If given, each dimension
dim[i]will either be zero-padded or trimmed to the lengths[i]before computing the real FFT. If a length-1is specified, no padding is done in that dimension. Default:s = [input.size(d) for d in dim]dim (Tuple[int], optional) – Dimensions to be transformed. Default: last two dimensions.
norm (str, optional) –
Normalization mode. For the forward transform (
rfft2()), these correspond to:"forward"- normalize by1/n"backward"- no normalization"ortho"- normalize by1/sqrt(n)(making the real FFT orthonormal)
Where
n = prod(s)is the logical FFT size. Calling the backward transform (irfft2()) with the same normalization mode will apply an overall normalization of1/nbetween the two transforms. This is required to makeirfft2()the exact inverse.Default is
"backward"(no normalization).
- Keyword Arguments
out (Tensor, optional) – the output tensor.
Example
>>> t = torch.rand(10, 10) >>> rfft2 = torch.fft.rfft2(t) >>> rfft2.size() torch.Size([10, 6])
Compared against the full output from
fft2(), we have all elements up to the Nyquist frequency.>>> fft2 = torch.fft.fft2(t) >>> torch.testing.assert_close(fft2[..., :6], rfft2, check_stride=False)
The discrete Fourier transform is separable, so
rfft2()here is equivalent to a combination offft()andrfft():>>> two_ffts = torch.fft.fft(torch.fft.rfft(t, dim=1), dim=0) >>> torch.testing.assert_close(rfft2, two_ffts, check_stride=False)
