1mlib_SignalIFFTW_1(3MLIB) mediaLib Library Functions mlib_SignalIFFTW_1(3MLIB)
2
6 mlib_SignalIFFTW_1, mlib_SignalIFFTW_1_S16_S16, mlib_Sig‐
7 nalIFFTW_1_S16C_S16C, mlib_SignalIFFTW_1_S16_S16C, mlib_Sig‐
8 nalIFFTW_1_S16, mlib_SignalIFFTW_1_S16C, mlib_SignalIFFTW_1_F32_F32,
9 mlib_SignalIFFTW_1_F32C_F32C, mlib_SignalIFFTW_1_F32_F32C, mlib_Sig‐
10 nalIFFTW_1_F32, mlib_SignalIFFTW_1_F32C - signal Inverse Fast Fourier
11 Transform with windowing (IFFTW)
12
14 cc [ flag... ] file... -lmlib [ library... ]
15 #include <mlib.h>
16 mlib_status mlib_SignalIFFTW_1_S16_S16(mlib_s16 *dstr, mlib_s16 *dsti,
18 const mlib_s16 *srcr, const mlib_s16 *srci, const mlib_s16 *window,
19 mlib_s32 order);
20 mlib_status mlib_SignalIFFTW_1_S16C_S16C(mlib_s16 *dstc,
23 const mlib_s16 *srcc,
24 const mlib_s16 *window, mlib_s32 order);
25 mlib_status mlib_SignalIFFTW_1_S16_S16C(mlib_s16 *dstr,
28 const mlib_s16 *srcc,
29 const mlib_s16 *window, mlib_s32 order);
30 mlib_status mlib_SignalIFFTW_1_S16(mlib_s16 *srcdstr, mlib_s16 *srcdsti,
33 const mlib_s16 *window, mlib_s32 order);
34 mlib_status mlib_SignalIFFTW_1_S16C(mlib_s16 *srcdstc,
37 const mlib_s16 *window,
38 mlib_s32 order);
39 mlib_status mlib_SignalIFFTW_1_F32_F32(mlib_f32 *dstr,
42 mlib_f32 *dsti,
43 const mlib_f32 *srcr, const mlib_f32 *srci, const mlib_f32 *window,
44 mlib_s32 order);
45 mlib_status mlib_SignalIFFTW_1_F32C_F32C(mlib_f32 *dstc,
48 const mlib_f32 *srcc,
49 const mlib_f32 *window, mlib_s32 order);
50 mlib_status mlib_SignalIFFTW_1_F32_F32C(mlib_f32 *dstr,
53 const mlib_f32 *srcc,
54 const mlib_f32 *window, mlib_s32 order);
55 mlib_status mlib_SignalIFFTW_1_F32(mlib_f32 *srcdstr, mlib_f32 *srcdsti,
58 const mlib_f32 *window, mlib_s32 order);
59 mlib_status mlib_SignalIFFTW_1_F32C(mlib_f32 *srcdstc,
62 const mlib_f32 *window,
63 mlib_s32 order);
64
67 Each of the functions in this group performs Inverse Fast Fourier
68 Transform with windowing (IFFTW).
69 The FFTW functions use the following equation:
72 1 N-1
74 dst[k] = ---- SUM {src[n] * window[n] * exp(-j2*PI*n*k/N)}
75 C1 n=0
76 and the IFFTW functions use the following equation:
80 1 N-1
82 dst[n] = ---- SUM {src[k] * window[k] * exp(j2*PI*n*k/N)}
83 C2 k=0
84 where
88 k = 0, 1, ..., (N - 1)
90 n = 0, 1, ..., (N - 1)
91 N = 2**order
92 The signal FFTW/IFFTW functions can be categorized into four groups
96 according to the ScaleMode in the function names in the following form:
97 mlib_Signal[FFTW|IFFTW]_ScaleMode_OutType_InType_OpMode()
99 mlib_Signal[FFTW|IFFTW]_ScaleMode_DataType_OpMode()
100 The scaling factors C1 and C2 used in the equations are defined as fol‐
104 lows:
105 o For ScaleMode = 1, C1 = 1 and C2 = 2**order.
107 o For ScaleMode = 2, C1 = 2**order and C2 = 1.
109 o For ScaleMode = 3, C1 = C2 = 2**(order/2) when order is
111 even, or C1 = 2**((order+1)/2) and C2 = 2**((order-1)/2)
112 when order is odd.
113 o For ScaleMode = 4, C1 = 2**P and C2 = 2**Q, where P and Q
115 are adaptive scaling factors and are generated by the func‐
116 tions.
117 For functions with only real parts for the source signal, the imaginary
120 parts are assumed to be all zero. For functions with only real parts
121 for the destination signal, the imaginary parts are discarded. The
122 functions with only one data type in their names perform the operation
123 in place.
124
126 Each function takes some of the following arguments:
127 dstr Destination signal array that contains the real parts.
129 dsti Destination signal array that contains the imaginary parts.
132 srcr Source signal array that contains the real parts.
135 srci Source signal array that contains the imaginary parts.
138 dstc Complex destination signal array. dstc[2*i] contains the
141 real parts, and dstc[2*i+1] contains the imaginary parts.
142 srcc Complex source signal array. srcc[2*i] contains the real
145 parts, and srcc[2*i+1] contains the imaginary parts.
146 srcdstr Source and destination signal array that contains the real
149 parts.
150 srcdsti Source and destination signal array that contains the imagi‐
153 nary parts.
154 srcdstc Complex source and destination signal array. srcdstc[2*i]
157 contains the real parts, and srcdstc[2*i+1] contains the
158 imaginary parts.
159 window Window coefficient array with 2**order real elements. The
162 window coefficients are in Q15 format for the S16 data type,
163 or in float format for the F32 data type.
164 order Order of the transformation. The base-2 logarithm of the
167 number of data samples.
168
171 Each function returns MLIB_SUCCESS if successful. Otherwise it returns
172 MLIB_FAILURE.
173
175 See attributes(5) for descriptions of the following attributes:
176 ┌─────────────────────────────┬─────────────────────────────┐
181 │ ATTRIBUTE TYPE │ ATTRIBUTE VALUE │
182 ├─────────────────────────────┼─────────────────────────────┤
183 │Interface Stability │Committed │
184 ├─────────────────────────────┼─────────────────────────────┤
185 │MT-Level │MT-Safe │
186 └─────────────────────────────┴─────────────────────────────┘
187
189 mlib_SignalFFTW_1(3MLIB), mlib_SignalFFTW_2(3MLIB), mlib_Sig‐
190 nalFFTW_3(3MLIB), mlib_SignalFFTW_4(3MLIB), mlib_SignalIFFTW_2(3MLIB),
191 mlib_SignalIFFTW_3(3MLIB), mlib_SignalIFFTW_4(3MLIB), attributes(5)
192SunOS 5.11 2 Mar 2007 mlib_SignalIFFTW_1(3MLIB)