summaryrefslogtreecommitdiff
path: root/src/modules/echo-cancel/adrian-aec.h
blob: e733f83b8cbfd3c062ec29fba4ae6ba3a30a4d4b (plain)
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
32
33
34
35
36
37
38
39
40
41
42
43
44
45
46
47
48
49
50
51
52
53
54
55
56
57
58
59
60
61
62
63
64
65
66
67
68
69
70
71
72
73
74
75
76
77
78
79
80
81
82
83
84
85
86
87
88
89
90
91
92
93
94
95
96
97
98
99
100
101
102
103
104
105
106
107
108
109
110
111
112
113
114
115
116
117
118
119
120
121
122
123
124
125
126
127
128
129
130
131
132
133
134
135
136
137
138
139
140
141
142
143
144
145
146
147
148
149
150
151
152
153
154
155
156
157
158
159
160
161
162
163
164
165
166
167
168
169
170
171
172
173
174
175
176
177
178
179
180
181
182
183
184
185
186
187
188
189
190
191
192
193
194
195
196
197
198
199
200
201
202
203
204
205
206
207
208
209
210
211
212
213
214
215
216
217
218
219
220
221
222
223
224
225
226
227
228
229
230
231
232
233
234
235
236
237
238
239
240
241
242
243
244
245
246
247
248
249
250
251
252
253
254
255
256
257
258
259
260
261
262
263
264
265
266
267
268
269
270
271
272
273
274
275
276
277
278
279
280
281
282
283
284
285
286
287
288
289
290
291
292
293
294
295
296
297
298
299
300
301
302
303
304
305
306
307
308
309
310
311
312
313
314
315
316
317
318
319
320
321
322
323
324
325
326
327
328
329
330
331
332
333
334
335
336
337
338
339
340
341
342
343
344
345
346
347
348
349
350
351
352
353
354
355
356
357
358
359
360
361
362
363
364
365
366
367
368
369
370
371
372
373
374
375
376
377
378
379
380
381
382
/* aec.h
 *
 * Copyright (C) DFS Deutsche Flugsicherung (2004, 2005).
 * All Rights Reserved.
 * Author: Andre Adrian
 *
 * Acoustic Echo Cancellation Leaky NLMS-pw algorithm
 *
 * Version 0.3 filter created with www.dsptutor.freeuk.com
 * Version 0.3.1 Allow change of stability parameter delta
 * Version 0.4 Leaky Normalized LMS - pre whitening algorithm
 */

#ifndef _AEC_H                  /* include only once */

#ifdef HAVE_CONFIG_H
#include <config.h>
#endif

#include <pulse/gccmacro.h>
#include <pulse/xmalloc.h>

#include <pulsecore/macro.h>

#define WIDEB 2

// use double if your CPU does software-emulation of float
#define REAL float

/* dB Values */
#define M0dB 1.0f
#define M3dB 0.71f
#define M6dB 0.50f
#define M9dB 0.35f
#define M12dB 0.25f
#define M18dB 0.125f
#define M24dB 0.063f

/* dB values for 16bit PCM */
/* MxdB_PCM = 32767 * 10 ^(x / 20) */
#define M10dB_PCM 10362.0f
#define M20dB_PCM 3277.0f
#define M25dB_PCM 1843.0f
#define M30dB_PCM 1026.0f
#define M35dB_PCM 583.0f
#define M40dB_PCM 328.0f
#define M45dB_PCM 184.0f
#define M50dB_PCM 104.0f
#define M55dB_PCM 58.0f
#define M60dB_PCM 33.0f
#define M65dB_PCM 18.0f
#define M70dB_PCM 10.0f
#define M75dB_PCM 6.0f
#define M80dB_PCM 3.0f
#define M85dB_PCM 2.0f
#define M90dB_PCM 1.0f

#define MAXPCM 32767.0f

/* Design constants (Change to fine tune the algorithms */

/* The following values are for hardware AEC and studio quality
 * microphone */

/* NLMS filter length in taps (samples). A longer filter length gives
 * better Echo Cancellation, but maybe slower convergence speed and
 * needs more CPU power (Order of NLMS is linear) */
#define NLMS_LEN  (100*WIDEB*8)

/* Vector w visualization length in taps (samples).
 * Must match argv value for wdisplay.tcl */
#define DUMP_LEN  (40*WIDEB*8)

/* minimum energy in xf. Range: M70dB_PCM to M50dB_PCM. Should be equal
 * to microphone ambient Noise level */
#define NoiseFloor M55dB_PCM

/* Leaky hangover in taps.
 */
#define Thold (60 * WIDEB * 8)

// Adrian soft decision DTD
// left point. X is ratio, Y is stepsize
#define STEPX1 1.0
#define STEPY1 1.0
// right point. STEPX2=2.0 is good double talk, 3.0 is good single talk.
#define STEPX2 2.5
#define STEPY2 0
#define ALPHAFAST (1.0f / 100.0f)
#define ALPHASLOW (1.0f / 20000.0f)



/* Ageing multiplier for LMS memory vector w */
#define Leaky 0.9999f

/* Double Talk Detector Speaker/Microphone Threshold. Range <=1
 * Large value (M0dB) is good for Single-Talk Echo cancellation,
 * small value (M12dB) is good for Doulbe-Talk AEC */
#define GeigelThreshold M6dB

/* for Non Linear Processor. Range >0 to 1. Large value (M0dB) is good
 * for Double-Talk, small value (M12dB) is good for Single-Talk */
#define NLPAttenuation M12dB

/* Below this line there are no more design constants */

typedef struct IIR_HP IIR_HP;

/* Exponential Smoothing or IIR Infinite Impulse Response Filter */
struct IIR_HP {
  REAL x;
};

static  IIR_HP* IIR_HP_init(void) {
    IIR_HP *i = pa_xnew(IIR_HP, 1);
    i->x = 0.0f;
    return i;
  }

static  REAL IIR_HP_highpass(IIR_HP *i, REAL in) {
    const REAL a0 = 0.01f;      /* controls Transfer Frequency */
    /* Highpass = Signal - Lowpass. Lowpass = Exponential Smoothing */
    i->x += a0 * (in - i->x);
    return in - i->x;
  }

typedef struct FIR_HP_300Hz FIR_HP_300Hz;

#if WIDEB==1
/* 17 taps FIR Finite Impulse Response filter
 * Coefficients calculated with
 * www.dsptutor.freeuk.com/KaiserFilterDesign/KaiserFilterDesign.html
 */
class FIR_HP_300Hz {
  REAL z[18];

public:
   FIR_HP_300Hz() {
    memset(this, 0, sizeof(FIR_HP_300Hz));
  }

  REAL highpass(REAL in) {
    const REAL a[18] = {
    // Kaiser Window FIR Filter, Filter type: High pass
    // Passband: 300.0 - 4000.0 Hz, Order: 16
    // Transition band: 75.0 Hz, Stopband attenuation: 10.0 dB
    -0.034870606, -0.039650206, -0.044063766, -0.04800318,
    -0.051370874, -0.054082647, -0.056070227, -0.057283327,
    0.8214126, -0.057283327, -0.056070227, -0.054082647,
    -0.051370874, -0.04800318, -0.044063766, -0.039650206,
    -0.034870606, 0.0
    };
    memmove(z + 1, z, 17 * sizeof(REAL));
    z[0] = in;
    REAL sum0 = 0.0, sum1 = 0.0;
    int j;

    for (j = 0; j < 18; j += 2) {
      // optimize: partial loop unrolling
      sum0 += a[j] * z[j];
      sum1 += a[j + 1] * z[j + 1];
    }
    return sum0 + sum1;
  }
};

#else

/* 35 taps FIR Finite Impulse Response filter
 * Passband 150Hz to 4kHz for 8kHz sample rate, 300Hz to 8kHz for 16kHz
 * sample rate.
 * Coefficients calculated with
 * www.dsptutor.freeuk.com/KaiserFilterDesign/KaiserFilterDesign.html
 */
struct FIR_HP_300Hz {
  REAL z[36];
};

static  FIR_HP_300Hz* FIR_HP_300Hz_init(void) {
    FIR_HP_300Hz *ret = pa_xnew(FIR_HP_300Hz, 1);
    memset(ret, 0, sizeof(FIR_HP_300Hz));
    return ret;
  }

static  REAL FIR_HP_300Hz_highpass(FIR_HP_300Hz *f, REAL in) {
    REAL sum0 = 0.0, sum1 = 0.0;
    int j;
    const REAL a[36] = {
      // Kaiser Window FIR Filter, Filter type: High pass
      // Passband: 150.0 - 4000.0 Hz, Order: 34
      // Transition band: 34.0 Hz, Stopband attenuation: 10.0 dB
      -0.016165324, -0.017454365, -0.01871232, -0.019931411,
      -0.021104068, -0.022222936, -0.02328091, -0.024271343,
      -0.025187887, -0.02602462, -0.026776174, -0.027437767,
      -0.028004972, -0.028474221, -0.028842418, -0.029107114,
      -0.02926664, 0.8524841, -0.02926664, -0.029107114,
      -0.028842418, -0.028474221, -0.028004972, -0.027437767,
      -0.026776174, -0.02602462, -0.025187887, -0.024271343,
      -0.02328091, -0.022222936, -0.021104068, -0.019931411,
      -0.01871232, -0.017454365, -0.016165324, 0.0
    };
    memmove(f->z + 1, f->z, 35 * sizeof(REAL));
    f->z[0] = in;

    for (j = 0; j < 36; j += 2) {
      // optimize: partial loop unrolling
      sum0 += a[j] * f->z[j];
      sum1 += a[j + 1] * f->z[j + 1];
    }
    return sum0 + sum1;
  }
#endif

typedef struct IIR1 IIR1;

/* Recursive single pole IIR Infinite Impulse response High-pass filter
 *
 * Reference: The Scientist and Engineer's Guide to Digital Processing
 *
 * 	output[N] = A0 * input[N] + A1 * input[N-1] + B1 * output[N-1]
 *
 *      X  = exp(-2.0 * pi * Fc)
 *      A0 = (1 + X) / 2
 *      A1 = -(1 + X) / 2
 *      B1 = X
 *      Fc = cutoff freq / sample rate
 */
struct IIR1 {
  REAL in0, out0;
  REAL a0, a1, b1;
};

#if 0
  IIR1() {
    memset(this, 0, sizeof(IIR1));
  }
#endif

static  IIR1* IIR1_init(REAL Fc) {
    IIR1 *i = pa_xnew(IIR1, 1);
    i->b1 = expf(-2.0f * M_PI * Fc);
    i->a0 = (1.0f + i->b1) / 2.0f;
    i->a1 = -(i->a0);
    i->in0 = 0.0f;
    i->out0 = 0.0f;
    return i;
  }

static  REAL IIR1_highpass(IIR1 *i, REAL in) {
    REAL out = i->a0 * in + i->a1 * i->in0 + i->b1 * i->out0;
    i->in0 = in;
    i->out0 = out;
    return out;
  }


#if 0
/* Recursive two pole IIR Infinite Impulse Response filter
 * Coefficients calculated with
 * http://www.dsptutor.freeuk.com/IIRFilterDesign/IIRFiltDes102.html
 */
class IIR2 {
  REAL x[2], y[2];

public:
   IIR2() {
    memset(this, 0, sizeof(IIR2));
  }

  REAL highpass(REAL in) {
    // Butterworth IIR filter, Filter type: HP
    // Passband: 2000 - 4000.0 Hz, Order: 2
    const REAL a[] = { 0.29289323f, -0.58578646f, 0.29289323f };
    const REAL b[] = { 1.3007072E-16f, 0.17157288f };
    REAL out =
      a[0] * in + a[1] * x[0] + a[2] * x[1] - b[0] * y[0] - b[1] * y[1];

    x[1] = x[0];
    x[0] = in;
    y[1] = y[0];
    y[0] = out;
    return out;
  }
};
#endif


// Extention in taps to reduce mem copies
#define NLMS_EXT  (10*8)

// block size in taps to optimize DTD calculation
#define DTD_LEN   16

typedef struct AEC AEC;

struct AEC {
  // Time domain Filters
  IIR_HP *acMic, *acSpk;        // DC-level remove Highpass)
  FIR_HP_300Hz *cutoff;         // 150Hz cut-off Highpass
  REAL gain;                    // Mic signal amplify
  IIR1 *Fx, *Fe;                // pre-whitening Highpass for x, e

  // Adrian soft decision DTD (Double Talk Detector)
  REAL dfast, xfast;
  REAL dslow, xslow;

  // NLMS-pw
  REAL x[NLMS_LEN + NLMS_EXT];  // tap delayed loudspeaker signal
  REAL xf[NLMS_LEN + NLMS_EXT]; // pre-whitening tap delayed signal
  REAL w_arr[NLMS_LEN + (16 / sizeof(REAL))]; // tap weights
  REAL *w;                      // this will be a 16-byte aligned pointer into w_arr
  int j;                        // optimize: less memory copies
  double dotp_xf_xf;            // double to avoid loss of precision
  float delta;                  // noise floor to stabilize NLMS

  // AES
  float aes_y2;                 // not in use!

  // w vector visualization
  REAL ws[DUMP_LEN];            // tap weights sums
  int fdwdisplay;               // TCP file descriptor
  int dumpcnt;                  // wdisplay output counter

  // variables are public for visualization
  int hangover;
  float stepsize;

  // vfuncs that are picked based on processor features available
  REAL (*dotp) (REAL[], REAL[]);
};

/* Double-Talk Detector
 *
 * in d: microphone sample (PCM as REALing point value)
 * in x: loudspeaker sample (PCM as REALing point value)
 * return: from 0 for doubletalk to 1.0 for single talk
 */
static  float AEC_dtd(AEC *a, REAL d, REAL x);

static  void AEC_leaky(AEC *a);

/* Normalized Least Mean Square Algorithm pre-whitening (NLMS-pw)
 * The LMS algorithm was developed by Bernard Widrow
 * book: Haykin, Adaptive Filter Theory, 4. edition, Prentice Hall, 2002
 *
 * in d: microphone sample (16bit PCM value)
 * in x_: loudspeaker sample (16bit PCM value)
 * in stepsize: NLMS adaptation variable
 * return: echo cancelled microphone sample
 */
static  REAL AEC_nlms_pw(AEC *a, REAL d, REAL x_, float stepsize);

  AEC* AEC_init(int RATE, int have_vector);

/* Acoustic Echo Cancellation and Suppression of one sample
 * in   d:  microphone signal with echo
 * in   x:  loudspeaker signal
 * return:  echo cancelled microphone signal
 */
  int AEC_doAEC(AEC *a, int d_, int x_);

PA_GCC_UNUSED static  float AEC_getambient(AEC *a) {
    return a->dfast;
  }
static  void AEC_setambient(AEC *a, float Min_xf) {
    a->dotp_xf_xf -= a->delta;  // subtract old delta
    a->delta = (NLMS_LEN-1) * Min_xf * Min_xf;
    a->dotp_xf_xf += a->delta;  // add new delta
  }
PA_GCC_UNUSED static  void AEC_setgain(AEC *a, float gain_) {
    a->gain = gain_;
  }
#if 0
  void AEC_openwdisplay(AEC *a);
#endif
PA_GCC_UNUSED static  void AEC_setaes(AEC *a, float aes_y2_) {
    a->aes_y2 = aes_y2_;
  }

#define _AEC_H
#endif