Multi-Dimensional DFTs of Real Data

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2.4 Multi-Dimensional DFTs of Real Data

Multi-dimensional DFTs of real data use the following planner routines: cannam@95: cannam@95:

cannam@95: as well as the corresponding c2r routines with the input/output cannam@95: types swapped. These routines work similarly to their complex cannam@95: analogues, except for the fact that here the complex output array is cut cannam@95: roughly in half and the real array requires padding for in-place cannam@95: transforms (as in 1d, above). cannam@95: cannam@95:

As before, n is the logical size of the array, and the cannam@95: consequences of this on the the format of the complex arrays deserve cannam@95: careful attention. cannam@95: Suppose that the real data has dimensions n₀ × n₁ × n₂ × … × n_d-1 (in row-major order). cannam@95: Then, after an r2c transform, the output is an n₀ × n₁ × n₂ × … × (n_d-1/2 + 1) array of cannam@95: fftw_complex values in row-major order, corresponding to slightly cannam@95: over half of the output of the corresponding complex DFT. (The division cannam@95: is rounded down.) The ordering of the data is otherwise exactly the cannam@95: same as in the complex-DFT case. cannam@95: cannam@95:

For out-of-place transforms, this is the end of the story: the real cannam@95: data is stored as a row-major array of size n₀ × n₁ × n₂ × … × n_d-1 and the complex cannam@95: data is stored as a row-major array of size n₀ × n₁ × n₂ × … × (n_d-1/2 + 1). cannam@95: cannam@95:

For in-place transforms, however, extra padding of the real-data array cannam@95: is necessary because the complex array is larger than the real array, cannam@95: and the two arrays share the same memory locations. Thus, for cannam@95: in-place transforms, the final dimension of the real-data array must cannam@95: be padded with extra values to accommodate the size of the complex cannam@95: data—two values if the last dimension is even and one if it is odd. cannam@95: That is, the last dimension of the real data must physically contain cannam@95: 2 * (n_d-1/2+1)double values (exactly enough to hold the complex data). cannam@95: This physical array size does not, however, change the logical cannam@95: array size—only cannam@95: n_d-1values are actually stored in the last dimension, and cannam@95: n_d-1is the last dimension passed to the plan-creation routine. cannam@95: cannam@95:

For example, consider the transform of a two-dimensional real array of cannam@95: size n0 by n1. The output of the r2c transform is a cannam@95: two-dimensional complex array of size n0 by n1/2+1, where cannam@95: the y dimension has been cut nearly in half because of cannam@95: redundancies in the output. Because fftw_complex is twice the cannam@95: size of double, the output array is slightly bigger than the cannam@95: input array. Thus, if we want to compute the transform in place, we cannam@95: must pad the input array so that it is of size n0 by cannam@95: 2*(n1/2+1). If n1 is even, then there are two padding cannam@95: elements at the end of each row (which need not be initialized, as they cannam@95: are only used for output). cannam@95: cannam@95:

The following illustration depicts the input and output arrays just cannam@95: described, for both the out-of-place and in-place transforms (with the cannam@95: arrows indicating consecutive memory locations): cannam@95:

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These transforms are unnormalized, so an r2c followed by a c2r cannam@95: transform (or vice versa) will result in the original data scaled by cannam@95: the number of real data elements—that is, the product of the cannam@95: (logical) dimensions of the real data. cannam@95: cannam@95: cannam@95:

(Because the last dimension is treated specially, if it is equal to cannam@95: 1 the transform is not equivalent to a lower-dimensional cannam@95: r2c/c2r transform. In that case, the last complex dimension also has cannam@95: size 1 (=1/2+1), and no advantage is gained over the cannam@95: complex transforms.) cannam@95: cannam@95: cannam@95: cannam@95: