sv-dependency-builds: src/fftw-3.3.5/doc/html/Real

annotate src/fftw-3.3.5/doc/html/Real_002ddata-DFTs.html @ 84:08ae793730bd

Add null config files

author	Chris Cannam
date	Mon, 02 Mar 2020 14:03:47 +0000
parents	2cd0e3b3e1fd
children

rev	line source
Chris@42	1 <!DOCTYPE html PUBLIC "-//W3C//DTD HTML 4.01 Transitional//EN" "http://www.w3.org/TR/html4/loose.dtd">
Chris@42	2 <html>
Chris@42	3 <!-- This manual is for FFTW
Chris@42	4 (version 3.3.5, 30 July 2016).
Chris@42	5
Chris@42	6 Copyright (C) 2003 Matteo Frigo.
Chris@42	7
Chris@42	8 Copyright (C) 2003 Massachusetts Institute of Technology.
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Chris@42	10 Permission is granted to make and distribute verbatim copies of this
Chris@42	11 manual provided the copyright notice and this permission notice are
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Chris@42	24 <head>
Chris@42	25 <title>FFTW 3.3.5: Real-data DFTs</title>
Chris@42	26
Chris@42	27 <meta name="description" content="FFTW 3.3.5: Real-data DFTs">
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Chris@42	37 <link href="Real_002ddata-DFT-Array-Format.html#Real_002ddata-DFT-Array-Format" rel="next" title="Real-data DFT Array Format">
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Chris@42	69 </head>
Chris@42	70
Chris@42	71 <body lang="en" bgcolor="#FFFFFF" text="#000000" link="#0000FF" vlink="#800080" alink="#FF0000">
Chris@42	72 <a name="Real_002ddata-DFTs"></a>
Chris@42	73 <div class="header">
Chris@42	74 <p>
Chris@42	75 Next: <a href="Real_002ddata-DFT-Array-Format.html#Real_002ddata-DFT-Array-Format" accesskey="n" rel="next">Real-data DFT Array Format</a>, Previous: <a href="Planner-Flags.html#Planner-Flags" accesskey="p" rel="prev">Planner Flags</a>, Up: <a href="Basic-Interface.html#Basic-Interface" accesskey="u" rel="up">Basic Interface</a>   [<a href="index.html#SEC_Contents" title="Table of contents" rel="contents">Contents</a>][<a href="Concept-Index.html#Concept-Index" title="Index" rel="index">Index</a>]</p>
Chris@42	76 </div>
Chris@42	77 <hr>
Chris@42	78 <a name="Real_002ddata-DFTs-1"></a>
Chris@42	79 <h4 class="subsection">4.3.3 Real-data DFTs</h4>
Chris@42	80
Chris@42	81 <div class="example">
Chris@42	82 <pre class="example">fftw_plan fftw_plan_dft_r2c_1d(int n0,
Chris@42	83 double in, fftw_complex out,
Chris@42	84 unsigned flags);
Chris@42	85 fftw_plan fftw_plan_dft_r2c_2d(int n0, int n1,
Chris@42	86 double in, fftw_complex out,
Chris@42	87 unsigned flags);
Chris@42	88 fftw_plan fftw_plan_dft_r2c_3d(int n0, int n1, int n2,
Chris@42	89 double in, fftw_complex out,
Chris@42	90 unsigned flags);
Chris@42	91 fftw_plan fftw_plan_dft_r2c(int rank, const int *n,
Chris@42	92 double in, fftw_complex out,
Chris@42	93 unsigned flags);
Chris@42	94 </pre></div>
Chris@42	95 <a name="index-fftw_005fplan_005fdft_005fr2c_005f1d-1"></a>
Chris@42	96 <a name="index-fftw_005fplan_005fdft_005fr2c_005f2d-1"></a>
Chris@42	97 <a name="index-fftw_005fplan_005fdft_005fr2c_005f3d-1"></a>
Chris@42	98 <a name="index-fftw_005fplan_005fdft_005fr2c-1"></a>
Chris@42	99 <a name="index-r2c-2"></a>
Chris@42	100
Chris@42	101 <p>Plan a real-input/complex-output discrete Fourier transform (DFT) in
Chris@42	102 zero or more dimensions, returning an <code>fftw_plan</code> (see <a href="Using-Plans.html#Using-Plans">Using Plans</a>).
Chris@42	103 </p>
Chris@42	104 <p>Once you have created a plan for a certain transform type and
Chris@42	105 parameters, then creating another plan of the same type and parameters,
Chris@42	106 but for different arrays, is fast and shares constant data with the
Chris@42	107 first plan (if it still exists).
Chris@42	108 </p>
Chris@42	109 <p>The planner returns <code>NULL</code> if the plan cannot be created. A
Chris@42	110 non-<code>NULL</code> plan is always returned by the basic interface unless
Chris@42	111 you are using a customized FFTW configuration supporting a restricted
Chris@42	112 set of transforms, or if you use the <code>FFTW_PRESERVE_INPUT</code> flag
Chris@42	113 with a multi-dimensional out-of-place c2r transform (see below).
Chris@42	114 </p>
Chris@42	115 <a name="Arguments-1"></a>
Chris@42	116 <h4 class="subsubheading">Arguments</h4>
Chris@42	117 <ul>
Chris@42	118 <li> <code>rank</code> is the rank of the transform (it should be the size of the
Chris@42	119 array <code>*n</code>), and can be any non-negative integer. (See <a href="Complex-Multi_002dDimensional-DFTs.html#Complex-Multi_002dDimensional-DFTs">Complex Multi-Dimensional DFTs</a>, for the definition of “rank”.) The
Chris@42	120 ‘<samp>_1d</samp>’, ‘<samp>_2d</samp>’, and ‘<samp>_3d</samp>’ planners correspond to a
Chris@42	121 <code>rank</code> of <code>1</code>, <code>2</code>, and <code>3</code>, respectively. The rank
Chris@42	122 may be zero, which is equivalent to a rank-1 transform of size 1, i.e. a
Chris@42	123 copy of one real number (with zero imaginary part) from input to output.
Chris@42	124
Chris@42	125 </li><li> <code>n0</code>, <code>n1</code>, <code>n2</code>, or <code>n[0..rank-1]</code>, (as appropriate
Chris@42	126 for each routine) specify the size of the transform dimensions. They
Chris@42	127 can be any positive integer. This is different in general from the
Chris@42	128 <em>physical</em> array dimensions, which are described in <a href="Real_002ddata-DFT-Array-Format.html#Real_002ddata-DFT-Array-Format">Real-data DFT Array Format</a>.
Chris@42	129
Chris@42	130 <ul class="no-bullet">
Chris@42	131 <li>- FFTW is best at handling sizes of the form
Chris@42	132 2<sup>a</sup> 3<sup>b</sup> 5<sup>c</sup> 7<sup>d</sup>
Chris@42	133 11<sup>e</sup> 13<sup>f</sup>,where <em>e+f</em> is either <em>0</em> or <em>1</em>, and the other exponents
Chris@42	134 are arbitrary. Other sizes are computed by means of a slow,
Chris@42	135 general-purpose algorithm (which nevertheless retains <i>O</i>(<i>n</i> log <i>n</i>) performance even for prime sizes). (It is possible to customize FFTW
Chris@42	136 for different array sizes; see <a href="Installation-and-Customization.html#Installation-and-Customization">Installation and Customization</a>.)
Chris@42	137 Transforms whose sizes are powers of <em>2</em> are especially fast, and
Chris@42	138 it is generally beneficial for the <em>last</em> dimension of an r2c/c2r
Chris@42	139 transform to be <em>even</em>.
Chris@42	140 </li></ul>
Chris@42	141
Chris@42	142 </li><li> <code>in</code> and <code>out</code> point to the input and output arrays of the
Chris@42	143 transform, which may be the same (yielding an in-place transform).
Chris@42	144 <a name="index-in_002dplace-3"></a>
Chris@42	145 These arrays are overwritten during planning, unless
Chris@42	146 <code>FFTW_ESTIMATE</code> is used in the flags. (The arrays need not be
Chris@42	147 initialized, but they must be allocated.) For an in-place transform, it
Chris@42	148 is important to remember that the real array will require padding,
Chris@42	149 described in <a href="Real_002ddata-DFT-Array-Format.html#Real_002ddata-DFT-Array-Format">Real-data DFT Array Format</a>.
Chris@42	150 <a name="index-padding-2"></a>
Chris@42	151
Chris@42	152 </li><li> <a name="index-flags-3"></a>
Chris@42	153 <code>flags</code> is a bitwise OR (‘<samp>\|</samp>’) of zero or more planner flags,
Chris@42	154 as defined in <a href="Planner-Flags.html#Planner-Flags">Planner Flags</a>.
Chris@42	155
Chris@42	156 </li></ul>
Chris@42	157
Chris@42	158 <p>The inverse transforms, taking complex input (storing the non-redundant
Chris@42	159 half of a logically Hermitian array) to real output, are given by:
Chris@42	160 </p>
Chris@42	161 <div class="example">
Chris@42	162 <pre class="example">fftw_plan fftw_plan_dft_c2r_1d(int n0,
Chris@42	163 fftw_complex in, double out,
Chris@42	164 unsigned flags);
Chris@42	165 fftw_plan fftw_plan_dft_c2r_2d(int n0, int n1,
Chris@42	166 fftw_complex in, double out,
Chris@42	167 unsigned flags);
Chris@42	168 fftw_plan fftw_plan_dft_c2r_3d(int n0, int n1, int n2,
Chris@42	169 fftw_complex in, double out,
Chris@42	170 unsigned flags);
Chris@42	171 fftw_plan fftw_plan_dft_c2r(int rank, const int *n,
Chris@42	172 fftw_complex in, double out,
Chris@42	173 unsigned flags);
Chris@42	174 </pre></div>
Chris@42	175 <a name="index-fftw_005fplan_005fdft_005fc2r_005f1d-1"></a>
Chris@42	176 <a name="index-fftw_005fplan_005fdft_005fc2r_005f2d"></a>
Chris@42	177 <a name="index-fftw_005fplan_005fdft_005fc2r_005f3d"></a>
Chris@42	178 <a name="index-fftw_005fplan_005fdft_005fc2r"></a>
Chris@42	179 <a name="index-c2r-2"></a>
Chris@42	180
Chris@42	181 <p>The arguments are the same as for the r2c transforms, except that the
Chris@42	182 input and output data formats are reversed.
Chris@42	183 </p>
Chris@42	184 <p>FFTW computes an unnormalized transform: computing an r2c followed by a
Chris@42	185 c2r transform (or vice versa) will result in the original data
Chris@42	186 multiplied by the size of the transform (the product of the logical
Chris@42	187 dimensions).
Chris@42	188 <a name="index-normalization-6"></a>
Chris@42	189 An r2c transform produces the same output as a <code>FFTW_FORWARD</code>
Chris@42	190 complex DFT of the same input, and a c2r transform is correspondingly
Chris@42	191 equivalent to <code>FFTW_BACKWARD</code>. For more information, see <a href="What-FFTW-Really-Computes.html#What-FFTW-Really-Computes">What FFTW Really Computes</a>.
Chris@42	192 </p>
Chris@42	193 <hr>
Chris@42	194 <div class="header">
Chris@42	195 <p>
Chris@42	196 Next: <a href="Real_002ddata-DFT-Array-Format.html#Real_002ddata-DFT-Array-Format" accesskey="n" rel="next">Real-data DFT Array Format</a>, Previous: <a href="Planner-Flags.html#Planner-Flags" accesskey="p" rel="prev">Planner Flags</a>, Up: <a href="Basic-Interface.html#Basic-Interface" accesskey="u" rel="up">Basic Interface</a>   [<a href="index.html#SEC_Contents" title="Table of contents" rel="contents">Contents</a>][<a href="Concept-Index.html#Concept-Index" title="Index" rel="index">Index</a>]</p>
Chris@42	197 </div>
Chris@42	198
Chris@42	199
Chris@42	200
Chris@42	201 </body>
Chris@42	202 </html>

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