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<!DOCTYPE html PUBLIC "-//W3C//DTD HTML 4.01 Transitional//EN" "http://www.w3.org/TR/html4/loose.dtd">
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<html>
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<!-- This manual is for FFTW
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(version 3.3.10, 10 December 2020).
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Copyright (C) 2003 Matteo Frigo.
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Copyright (C) 2003 Massachusetts Institute of Technology.
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Permission is granted to make and distribute verbatim copies of this
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manual provided the copyright notice and this permission notice are
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preserved on all copies.
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manual under the conditions for verbatim copying, provided that the
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<head>
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<meta http-equiv="Content-Type" content="text/html; charset=utf-8">
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<title>One-Dimensional DFTs of Real Data (FFTW 3.3.10)</title>
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<meta name="description" content="One-Dimensional DFTs of Real Data (FFTW 3.3.10)">
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<link href="index.html" rel="start" title="Top">
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<link href="Concept-Index.html" rel="index" title="Concept Index">
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<link href="index.html#SEC_Contents" rel="contents" title="Table of Contents">
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<link href="Tutorial.html" rel="up" title="Tutorial">
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<link href="Multi_002dDimensional-DFTs-of-Real-Data.html" rel="next" title="Multi-Dimensional DFTs of Real Data">
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<link href="Complex-Multi_002dDimensional-DFTs.html" rel="prev" title="Complex Multi-Dimensional DFTs">
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</head>
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<body lang="en">
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<span id="One_002dDimensional-DFTs-of-Real-Data"></span><div class="header">
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<p>
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Next: <a href="Multi_002dDimensional-DFTs-of-Real-Data.html" accesskey="n" rel="next">Multi-Dimensional DFTs of Real Data</a>, Previous: <a href="Complex-Multi_002dDimensional-DFTs.html" accesskey="p" rel="prev">Complex Multi-Dimensional DFTs</a>, Up: <a href="Tutorial.html" accesskey="u" rel="up">Tutorial</a> [<a href="index.html#SEC_Contents" title="Table of contents" rel="contents">Contents</a>][<a href="Concept-Index.html" title="Index" rel="index">Index</a>]</p>
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</div>
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<hr>
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<span id="One_002dDimensional-DFTs-of-Real-Data-1"></span><h3 class="section">2.3 One-Dimensional DFTs of Real Data</h3>
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<p>In many practical applications, the input data <code>in[i]</code> are purely
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real numbers, in which case the DFT output satisfies the “Hermitian”
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<span id="index-Hermitian"></span>
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redundancy: <code>out[i]</code> is the conjugate of <code>out[n-i]</code>. It is
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possible to take advantage of these circumstances in order to achieve
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roughly a factor of two improvement in both speed and memory usage.
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</p>
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<p>In exchange for these speed and space advantages, the user sacrifices
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some of the simplicity of FFTW’s complex transforms. First of all, the
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input and output arrays are of <em>different sizes and types</em>: the
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input is <code>n</code> real numbers, while the output is <code>n/2+1</code>
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complex numbers (the non-redundant outputs); this also requires slight
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“padding” of the input array for
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<span id="index-padding"></span>
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in-place transforms. Second, the inverse transform (complex to real)
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has the side-effect of <em>overwriting its input array</em>, by default.
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Neither of these inconveniences should pose a serious problem for
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users, but it is important to be aware of them.
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</p>
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<p>The routines to perform real-data transforms are almost the same as
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those for complex transforms: you allocate arrays of <code>double</code>
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and/or <code>fftw_complex</code> (preferably using <code>fftw_malloc</code> or
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<code>fftw_alloc_complex</code>), create an <code>fftw_plan</code>, execute it as
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many times as you want with <code>fftw_execute(plan)</code>, and clean up
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with <code>fftw_destroy_plan(plan)</code> (and <code>fftw_free</code>). The only
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differences are that the input (or output) is of type <code>double</code>
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and there are new routines to create the plan. In one dimension:
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</p>
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<div class="example">
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<pre class="example">fftw_plan fftw_plan_dft_r2c_1d(int n, double *in, fftw_complex *out,
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unsigned flags);
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fftw_plan fftw_plan_dft_c2r_1d(int n, fftw_complex *in, double *out,
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unsigned flags);
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</pre></div>
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<span id="index-fftw_005fplan_005fdft_005fr2c_005f1d"></span>
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<span id="index-fftw_005fplan_005fdft_005fc2r_005f1d"></span>
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<p>for the real input to complex-Hermitian output (<em>r2c</em>) and
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complex-Hermitian input to real output (<em>c2r</em>) transforms.
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<span id="index-r2c"></span>
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<span id="index-c2r"></span>
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Unlike the complex DFT planner, there is no <code>sign</code> argument.
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Instead, r2c DFTs are always <code>FFTW_FORWARD</code> and c2r DFTs are
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always <code>FFTW_BACKWARD</code>.
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<span id="index-FFTW_005fFORWARD-1"></span>
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<span id="index-FFTW_005fBACKWARD-1"></span>
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(For single/long-double precision
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<code>fftwf</code> and <code>fftwl</code>, <code>double</code> should be replaced by
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<code>float</code> and <code>long double</code>, respectively.)
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<span id="index-precision-1"></span>
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</p>
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<p>Here, <code>n</code> is the “logical” size of the DFT, not necessarily the
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physical size of the array. In particular, the real (<code>double</code>)
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array has <code>n</code> elements, while the complex (<code>fftw_complex</code>)
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array has <code>n/2+1</code> elements (where the division is rounded down).
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For an in-place transform,
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<span id="index-in_002dplace-1"></span>
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<code>in</code> and <code>out</code> are aliased to the same array, which must be
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big enough to hold both; so, the real array would actually have
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<code>2*(n/2+1)</code> elements, where the elements beyond the first
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<code>n</code> are unused padding. (Note that this is very different from
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the concept of “zero-padding” a transform to a larger length, which
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changes the logical size of the DFT by actually adding new input
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data.) The <em>k</em>th element of the complex array is exactly the
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same as the <em>k</em>th element of the corresponding complex DFT. All
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positive <code>n</code> are supported; products of small factors are most
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efficient, but an <i>O</i>(<i>n</i> log <i>n</i>)
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algorithm is used even for prime sizes.
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</p>
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<p>As noted above, the c2r transform destroys its input array even for
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out-of-place transforms. This can be prevented, if necessary, by
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including <code>FFTW_PRESERVE_INPUT</code> in the <code>flags</code>, with
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unfortunately some sacrifice in performance.
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<span id="index-flags-1"></span>
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<span id="index-FFTW_005fPRESERVE_005fINPUT"></span>
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This flag is also not currently supported for multi-dimensional real
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DFTs (next section).
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</p>
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<p>Readers familiar with DFTs of real data will recall that the 0th (the
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“DC”) and <code>n/2</code>-th (the “Nyquist” frequency, when <code>n</code> is
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even) elements of the complex output are purely real. Some
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implementations therefore store the Nyquist element where the DC
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imaginary part would go, in order to make the input and output arrays
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the same size. Such packing, however, does not generalize well to
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multi-dimensional transforms, and the space savings are miniscule in
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any case; FFTW does not support it.
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</p>
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<p>An alternative interface for one-dimensional r2c and c2r DFTs can be
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found in the ‘<samp>r2r</samp>’ interface (see <a href="The-Halfcomplex_002dformat-DFT.html">The Halfcomplex-format DFT</a>), with “halfcomplex”-format output that <em>is</em> the same size
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(and type) as the input array.
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<span id="index-halfcomplex-format"></span>
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That interface, although it is not very useful for multi-dimensional
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transforms, may sometimes yield better performance.
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</p>
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<hr>
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<div class="header">
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<p>
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Next: <a href="Multi_002dDimensional-DFTs-of-Real-Data.html" accesskey="n" rel="next">Multi-Dimensional DFTs of Real Data</a>, Previous: <a href="Complex-Multi_002dDimensional-DFTs.html" accesskey="p" rel="prev">Complex Multi-Dimensional DFTs</a>, Up: <a href="Tutorial.html" accesskey="u" rel="up">Tutorial</a> [<a href="index.html#SEC_Contents" title="Table of contents" rel="contents">Contents</a>][<a href="Concept-Index.html" title="Index" rel="index">Index</a>]</p>
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</div>
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</body>
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</html>
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