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annotate dsp/tempotracking/TempoTrackV2.cpp @ 55:7fe29d8a7eaf

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* Various fixes related to the bar estimator code
author cannam
date Tue, 10 Feb 2009 16:37:11 +0000
parents 5bec06ecc88a
children a0f987c06bec
rev   line source
cannam@52 1 /* -*- c-basic-offset: 4 indent-tabs-mode: nil -*- vi:set ts=8 sts=4 sw=4: */
cannam@52 2
cannam@52 3 /*
cannam@52 4 QM DSP Library
cannam@52 5
cannam@52 6 Centre for Digital Music, Queen Mary, University of London.
cannam@52 7 This file copyright 2008-2009 Matthew Davies and QMUL.
cannam@52 8 All rights reserved.
cannam@52 9 */
cannam@52 10
cannam@52 11 #include "TempoTrackV2.h"
cannam@52 12
cannam@52 13 #include <cmath>
cannam@52 14 #include <cstdlib>
cannam@53 15 #include <iostream>
cannam@52 16
cannam@54 17 #include "maths/MathUtilities.h"
cannam@52 18
cannam@52 19 #define EPS 0.0000008 // just some arbitrary small number
cannam@52 20
cannam@54 21 TempoTrackV2::TempoTrackV2(float rate, size_t increment) :
cannam@54 22 m_rate(rate), m_increment(increment) { }
cannam@52 23 TempoTrackV2::~TempoTrackV2() { }
cannam@52 24
cannam@52 25 void
cannam@52 26 TempoTrackV2::filter_df(d_vec_t &df)
cannam@52 27 {
cannam@53 28 d_vec_t a(3);
cannam@53 29 d_vec_t b(3);
cannam@53 30 d_vec_t lp_df(df.size());
cannam@52 31
cannam@53 32 //equivalent in matlab to [b,a] = butter(2,0.4);
cannam@53 33 a[0] = 1.0000;
cannam@53 34 a[1] = -0.3695;
cannam@53 35 a[2] = 0.1958;
cannam@53 36 b[0] = 0.2066;
cannam@53 37 b[1] = 0.4131;
cannam@53 38 b[2] = 0.2066;
cannam@53 39
cannam@53 40 double inp1 = 0.;
cannam@53 41 double inp2 = 0.;
cannam@53 42 double out1 = 0.;
cannam@53 43 double out2 = 0.;
cannam@52 44
cannam@52 45
cannam@53 46 // forwards filtering
cannam@53 47 for (uint i = 0;i < df.size();i++)
cannam@53 48 {
cannam@53 49 lp_df[i] = b[0]*df[i] + b[1]*inp1 + b[2]*inp2 - a[1]*out1 - a[2]*out2;
cannam@53 50 inp2 = inp1;
cannam@53 51 inp1 = df[i];
cannam@53 52 out2 = out1;
cannam@53 53 out1 = lp_df[i];
cannam@53 54 }
cannam@52 55
cannam@53 56 // copy forwards filtering to df...
cannam@53 57 // but, time-reversed, ready for backwards filtering
cannam@53 58 for (uint i = 0;i < df.size();i++)
cannam@53 59 {
cannam@53 60 df[i] = lp_df[df.size()-i-1];
cannam@53 61 }
cannam@52 62
cannam@53 63 for (uint i = 0;i < df.size();i++)
cannam@53 64 {
cannam@53 65 lp_df[i] = 0.;
cannam@53 66 }
cannam@52 67
cannam@53 68 inp1 = 0.; inp2 = 0.;
cannam@53 69 out1 = 0.; out2 = 0.;
cannam@52 70
cannam@52 71 // backwards filetering on time-reversed df
cannam@53 72 for (uint i = 0;i < df.size();i++)
cannam@53 73 {
cannam@53 74 lp_df[i] = b[0]*df[i] + b[1]*inp1 + b[2]*inp2 - a[1]*out1 - a[2]*out2;
cannam@53 75 inp2 = inp1;
cannam@53 76 inp1 = df[i];
cannam@53 77 out2 = out1;
cannam@53 78 out1 = lp_df[i];
cannam@53 79 }
cannam@52 80
cannam@52 81 // write the re-reversed (i.e. forward) version back to df
cannam@53 82 for (uint i = 0;i < df.size();i++)
cannam@53 83 {
cannam@53 84 df[i] = lp_df[df.size()-i-1];
cannam@53 85 }
cannam@52 86 }
cannam@52 87
cannam@52 88
cannam@52 89 void
cannam@53 90 TempoTrackV2::calculateBeatPeriod(const d_vec_t &df, d_vec_t &beat_period,
cannam@53 91 d_vec_t &tempi)
cannam@52 92 {
cannam@53 93 // to follow matlab.. split into 512 sample frames with a 128 hop size
cannam@53 94 // calculate the acf,
cannam@53 95 // then the rcf.. and then stick the rcfs as columns of a matrix
cannam@53 96 // then call viterbi decoding with weight vector and transition matrix
cannam@53 97 // and get best path
cannam@52 98
cannam@53 99 uint wv_len = 128;
cannam@53 100 double rayparam = 43.;
cannam@52 101
cannam@53 102 // make rayleigh weighting curve
cannam@53 103 d_vec_t wv(wv_len);
cannam@53 104 for (uint i=0; i<wv.size(); i++)
cannam@52 105 {
cannam@53 106 wv[i] = (static_cast<double> (i) / pow(rayparam,2.)) * exp((-1.*pow(-static_cast<double> (i),2.)) / (2.*pow(rayparam,2.)));
cannam@52 107 }
cannam@52 108
cannam@53 109 // beat tracking frame size (roughly 6 seconds) and hop (1.5 seconds)
cannam@53 110 uint winlen = 512;
cannam@53 111 uint step = 128;
cannam@53 112
cannam@53 113 // matrix to store output of comb filter bank, increment column of matrix at each frame
cannam@53 114 d_mat_t rcfmat;
cannam@53 115 int col_counter = -1;
cannam@53 116
cannam@53 117 // main loop for beat period calculation
cannam@53 118 for (uint i=0; i<(df.size()-winlen); i+=step)
cannam@53 119 {
cannam@53 120 // get dfframe
cannam@53 121 d_vec_t dfframe(winlen);
cannam@53 122 for (uint k=0; k<winlen; k++)
cannam@53 123 {
cannam@53 124 dfframe[k] = df[i+k];
cannam@53 125 }
cannam@53 126 // get rcf vector for current frame
cannam@53 127 d_vec_t rcf(wv_len);
cannam@53 128 get_rcf(dfframe,wv,rcf);
cannam@52 129
cannam@53 130 rcfmat.push_back( d_vec_t() ); // adds a new column
cannam@53 131 col_counter++;
cannam@53 132 for (uint j=0; j<rcf.size(); j++)
cannam@53 133 {
cannam@53 134 rcfmat[col_counter].push_back( rcf[j] );
cannam@53 135 }
cannam@53 136 }
cannam@53 137
cannam@53 138 // now call viterbi decoding function
cannam@53 139 viterbi_decode(rcfmat,wv,beat_period,tempi);
cannam@52 140 }
cannam@52 141
cannam@52 142
cannam@52 143 void
cannam@52 144 TempoTrackV2::get_rcf(const d_vec_t &dfframe_in, const d_vec_t &wv, d_vec_t &rcf)
cannam@52 145 {
cannam@53 146 // calculate autocorrelation function
cannam@53 147 // then rcf
cannam@53 148 // just hard code for now... don't really need separate functions to do this
cannam@52 149
cannam@53 150 // make acf
cannam@52 151
cannam@53 152 d_vec_t dfframe(dfframe_in);
cannam@52 153
cannam@54 154 MathUtilities::adaptiveThreshold(dfframe);
cannam@52 155
cannam@53 156 d_vec_t acf(dfframe.size());
cannam@52 157
cannam@53 158
cannam@53 159 for (uint lag=0; lag<dfframe.size(); lag++)
cannam@53 160 {
cannam@53 161 double sum = 0.;
cannam@53 162 double tmp = 0.;
cannam@52 163
cannam@53 164 for (uint n=0; n<(dfframe.size()-lag); n++)
cannam@53 165 {
cannam@53 166 tmp = dfframe[n] * dfframe[n+lag];
cannam@53 167 sum += tmp;
cannam@53 168 }
cannam@53 169 acf[lag] = static_cast<double> (sum/ (dfframe.size()-lag));
cannam@53 170 }
cannam@52 171
cannam@53 172 // now apply comb filtering
cannam@53 173 int numelem = 4;
cannam@53 174
cannam@53 175 for (uint i = 2;i < rcf.size();i++) // max beat period
cannam@53 176 {
cannam@53 177 for (int a = 1;a <= numelem;a++) // number of comb elements
cannam@53 178 {
cannam@53 179 for (int b = 1-a;b <= a-1;b++) // general state using normalisation of comb elements
cannam@53 180 {
cannam@53 181 rcf[i-1] += ( acf[(a*i+b)-1]*wv[i-1] ) / (2.*a-1.); // calculate value for comb filter row
cannam@53 182 }
cannam@53 183 }
cannam@53 184 }
cannam@53 185
cannam@53 186 // apply adaptive threshold to rcf
cannam@54 187 MathUtilities::adaptiveThreshold(rcf);
cannam@53 188
cannam@53 189 double rcfsum =0.;
cannam@53 190 for (uint i=0; i<rcf.size(); i++)
cannam@53 191 {
cannam@53 192 rcf[i] += EPS ;
cannam@53 193 rcfsum += rcf[i];
cannam@53 194 }
cannam@52 195
cannam@53 196 // normalise rcf to sum to unity
cannam@53 197 for (uint i=0; i<rcf.size(); i++)
cannam@52 198 {
cannam@53 199 rcf[i] /= (rcfsum + EPS);
cannam@52 200 }
cannam@52 201 }
cannam@52 202
cannam@52 203 void
cannam@53 204 TempoTrackV2::viterbi_decode(const d_mat_t &rcfmat, const d_vec_t &wv, d_vec_t &beat_period, d_vec_t &tempi)
cannam@52 205 {
cannam@53 206 // following Kevin Murphy's Viterbi decoding to get best path of
cannam@53 207 // beat periods through rfcmat
cannam@52 208
cannam@53 209 // make transition matrix
cannam@53 210 d_mat_t tmat;
cannam@53 211 for (uint i=0;i<wv.size();i++)
cannam@53 212 {
cannam@53 213 tmat.push_back ( d_vec_t() ); // adds a new column
cannam@53 214 for (uint j=0; j<wv.size(); j++)
cannam@53 215 {
cannam@53 216 tmat[i].push_back(0.); // fill with zeros initially
cannam@53 217 }
cannam@53 218 }
cannam@53 219
cannam@53 220 // variance of Gaussians in transition matrix
cannam@53 221 // formed of Gaussians on diagonal - implies slow tempo change
cannam@53 222 double sigma = 8.;
cannam@53 223 // don't want really short beat periods, or really long ones
cannam@53 224 for (uint i=20;i <wv.size()-20; i++)
cannam@53 225 {
cannam@53 226 for (uint j=20; j<wv.size()-20; j++)
cannam@53 227 {
cannam@53 228 double mu = static_cast<double>(i);
cannam@53 229 tmat[i][j] = exp( (-1.*pow((j-mu),2.)) / (2.*pow(sigma,2.)) );
cannam@53 230 }
cannam@53 231 }
cannam@52 232
cannam@53 233 // parameters for Viterbi decoding... this part is taken from
cannam@53 234 // Murphy's matlab
cannam@52 235
cannam@53 236 d_mat_t delta;
cannam@53 237 i_mat_t psi;
cannam@53 238 for (uint i=0;i <rcfmat.size(); i++)
cannam@53 239 {
cannam@53 240 delta.push_back( d_vec_t());
cannam@53 241 psi.push_back( i_vec_t());
cannam@53 242 for (uint j=0; j<rcfmat[i].size(); j++)
cannam@53 243 {
cannam@53 244 delta[i].push_back(0.); // fill with zeros initially
cannam@53 245 psi[i].push_back(0); // fill with zeros initially
cannam@53 246 }
cannam@53 247 }
cannam@52 248
cannam@52 249
cannam@53 250 uint T = delta.size();
cannam@53 251 uint Q = delta[0].size();
cannam@52 252
cannam@53 253 // initialize first column of delta
cannam@52 254 for (uint j=0; j<Q; j++)
cannam@52 255 {
cannam@53 256 delta[0][j] = wv[j] * rcfmat[0][j];
cannam@53 257 psi[0][j] = 0;
cannam@52 258 }
cannam@53 259
cannam@52 260 double deltasum = 0.;
cannam@52 261 for (uint i=0; i<Q; i++)
cannam@52 262 {
cannam@53 263 deltasum += delta[0][i];
cannam@52 264 }
cannam@52 265 for (uint i=0; i<Q; i++)
cannam@52 266 {
cannam@53 267 delta[0][i] /= (deltasum + EPS);
cannam@52 268 }
cannam@52 269
cannam@52 270
cannam@53 271 for (uint t=1; t<T; t++)
cannam@53 272 {
cannam@53 273 d_vec_t tmp_vec(Q);
cannam@52 274
cannam@53 275 for (uint j=0; j<Q; j++)
cannam@53 276 {
cannam@53 277 for (uint i=0; i<Q; i++)
cannam@53 278 {
cannam@53 279 tmp_vec[i] = delta[t-1][i] * tmat[j][i];
cannam@53 280 }
cannam@53 281
cannam@53 282 delta[t][j] = get_max_val(tmp_vec);
cannam@52 283
cannam@53 284 psi[t][j] = get_max_ind(tmp_vec);
cannam@53 285
cannam@53 286 delta[t][j] *= rcfmat[t][j];
cannam@53 287 }
cannam@52 288
cannam@53 289 // normalise current delta column
cannam@53 290 double deltasum = 0.;
cannam@53 291 for (uint i=0; i<Q; i++)
cannam@53 292 {
cannam@53 293 deltasum += delta[t][i];
cannam@53 294 }
cannam@53 295 for (uint i=0; i<Q; i++)
cannam@53 296 {
cannam@53 297 delta[t][i] /= (deltasum + EPS);
cannam@53 298 }
cannam@53 299 }
cannam@52 300
cannam@53 301 i_vec_t bestpath(T);
cannam@53 302 d_vec_t tmp_vec(Q);
cannam@53 303 for (uint i=0; i<Q; i++)
cannam@53 304 {
cannam@53 305 tmp_vec[i] = delta[T-1][i];
cannam@53 306 }
cannam@52 307
cannam@53 308 // find starting point - best beat period for "last" frame
cannam@53 309 bestpath[T-1] = get_max_ind(tmp_vec);
cannam@53 310
cannam@53 311 // backtrace through index of maximum values in psi
cannam@53 312 for (uint t=T-2; t>0 ;t--)
cannam@53 313 {
cannam@53 314 bestpath[t] = psi[t+1][bestpath[t+1]];
cannam@53 315 }
cannam@52 316
cannam@53 317 // weird but necessary hack -- couldn't get above loop to terminate at t >= 0
cannam@53 318 bestpath[0] = psi[1][bestpath[1]];
cannam@52 319
cannam@53 320 uint lastind = 0;
cannam@53 321 for (uint i=0; i<T; i++)
cannam@53 322 {
cannam@53 323 uint step = 128;
cannam@53 324 for (uint j=0; j<step; j++)
cannam@53 325 {
cannam@53 326 lastind = i*step+j;
cannam@53 327 beat_period[lastind] = bestpath[i];
cannam@53 328 }
cannam@55 329 std::cerr << "bestpath[" << i << "] = " << bestpath[i] << " (used for beat_periods " << i*step << " to " << i*step+step-1 << ")" << std::endl;
cannam@53 330 }
cannam@52 331
cannam@53 332 //fill in the last values...
cannam@53 333 for (uint i=lastind; i<beat_period.size(); i++)
cannam@53 334 {
cannam@53 335 beat_period[i] = beat_period[lastind];
cannam@53 336 }
cannam@52 337
cannam@53 338 for (uint i = 0; i < beat_period.size(); i++)
cannam@52 339 {
cannam@54 340 tempi.push_back((60. * m_rate / m_increment)/beat_period[i]);
cannam@52 341 }
cannam@52 342 }
cannam@52 343
cannam@52 344 double
cannam@52 345 TempoTrackV2::get_max_val(const d_vec_t &df)
cannam@52 346 {
cannam@53 347 double maxval = 0.;
cannam@53 348 for (uint i=0; i<df.size(); i++)
cannam@52 349 {
cannam@53 350 if (maxval < df[i])
cannam@53 351 {
cannam@53 352 maxval = df[i];
cannam@53 353 }
cannam@52 354 }
cannam@52 355
cannam@53 356 return maxval;
cannam@52 357 }
cannam@52 358
cannam@52 359 int
cannam@52 360 TempoTrackV2::get_max_ind(const d_vec_t &df)
cannam@52 361 {
cannam@53 362 double maxval = 0.;
cannam@53 363 int ind = 0;
cannam@53 364 for (uint i=0; i<df.size(); i++)
cannam@52 365 {
cannam@53 366 if (maxval < df[i])
cannam@53 367 {
cannam@53 368 maxval = df[i];
cannam@53 369 ind = i;
cannam@53 370 }
cannam@52 371 }
cannam@53 372
cannam@53 373 return ind;
cannam@52 374 }
cannam@52 375
cannam@52 376 void
cannam@52 377 TempoTrackV2::normalise_vec(d_vec_t &df)
cannam@52 378 {
cannam@53 379 double sum = 0.;
cannam@53 380 for (uint i=0; i<df.size(); i++)
cannam@53 381 {
cannam@53 382 sum += df[i];
cannam@53 383 }
cannam@53 384
cannam@53 385 for (uint i=0; i<df.size(); i++)
cannam@53 386 {
cannam@53 387 df[i]/= (sum + EPS);
cannam@53 388 }
cannam@52 389 }
cannam@52 390
cannam@52 391 void
cannam@52 392 TempoTrackV2::calculateBeats(const d_vec_t &df, const d_vec_t &beat_period,
cannam@52 393 d_vec_t &beats)
cannam@52 394 {
cannam@53 395 d_vec_t cumscore(df.size()); // store cumulative score
cannam@53 396 i_vec_t backlink(df.size()); // backlink (stores best beat locations at each time instant)
cannam@53 397 d_vec_t localscore(df.size()); // localscore, for now this is the same as the detection function
cannam@52 398
cannam@53 399 for (uint i=0; i<df.size(); i++)
cannam@52 400 {
cannam@53 401 localscore[i] = df[i];
cannam@53 402 backlink[i] = -1;
cannam@52 403 }
cannam@52 404
cannam@53 405 double tightness = 4.;
cannam@53 406 double alpha = 0.9;
cannam@52 407
cannam@53 408 // main loop
cannam@53 409 for (uint i=0; i<localscore.size(); i++)
cannam@53 410 {
cannam@53 411 int prange_min = -2*beat_period[i];
cannam@53 412 int prange_max = round(-0.5*beat_period[i]);
cannam@52 413
cannam@53 414 // transition range
cannam@53 415 d_vec_t txwt (prange_max - prange_min + 1);
cannam@53 416 d_vec_t scorecands (txwt.size());
cannam@52 417
cannam@53 418 for (uint j=0;j<txwt.size();j++)
cannam@53 419 {
cannam@53 420 double mu = static_cast<double> (beat_period[i]);
cannam@53 421 txwt[j] = exp( -0.5*pow(tightness * log((round(2*mu)-j)/mu),2));
cannam@52 422
cannam@53 423 // IF IN THE ALLOWED RANGE, THEN LOOK AT CUMSCORE[I+PRANGE_MIN+J
cannam@53 424 // ELSE LEAVE AT DEFAULT VALUE FROM INITIALISATION: D_VEC_T SCORECANDS (TXWT.SIZE());
cannam@52 425
cannam@53 426 int cscore_ind = i+prange_min+j;
cannam@53 427 if (cscore_ind >= 0)
cannam@53 428 {
cannam@53 429 scorecands[j] = txwt[j] * cumscore[cscore_ind];
cannam@53 430 }
cannam@53 431 }
cannam@52 432
cannam@53 433 // find max value and index of maximum value
cannam@53 434 double vv = get_max_val(scorecands);
cannam@53 435 int xx = get_max_ind(scorecands);
cannam@52 436
cannam@53 437 cumscore[i] = alpha*vv + (1.-alpha)*localscore[i];
cannam@53 438 backlink[i] = i+prange_min+xx;
cannam@55 439
cannam@55 440 std::cerr << "backlink[" << i << "] <= " << backlink[i] << std::endl;
cannam@53 441 }
cannam@53 442
cannam@53 443 // STARTING POINT, I.E. LAST BEAT.. PICK A STRONG POINT IN cumscore VECTOR
cannam@53 444 d_vec_t tmp_vec;
cannam@53 445 for (uint i=cumscore.size() - beat_period[beat_period.size()-1] ; i<cumscore.size(); i++)
cannam@53 446 {
cannam@53 447 tmp_vec.push_back(cumscore[i]);
cannam@53 448 }
cannam@53 449
cannam@53 450 int startpoint = get_max_ind(tmp_vec) + cumscore.size() - beat_period[beat_period.size()-1] ;
cannam@53 451
cannam@53 452 // USE BACKLINK TO GET EACH NEW BEAT (TOWARDS THE BEGINNING OF THE FILE)
cannam@53 453 // BACKTRACKING FROM THE END TO THE BEGINNING.. MAKING SURE NOT TO GO BEFORE SAMPLE 0
cannam@53 454 i_vec_t ibeats;
cannam@53 455 ibeats.push_back(startpoint);
cannam@55 456 std::cerr << "startpoint = " << startpoint << std::endl;
cannam@53 457 while (backlink[ibeats.back()] > 0)
cannam@53 458 {
cannam@55 459 std::cerr << "backlink[" << ibeats.back() << "] = " << backlink[ibeats.back()] << std::endl;
cannam@53 460 ibeats.push_back(backlink[ibeats.back()]);
cannam@53 461 }
cannam@52 462
cannam@53 463 // REVERSE SEQUENCE OF IBEATS AND STORE AS BEATS
cannam@53 464 for (uint i=0; i<ibeats.size(); i++)
cannam@53 465 {
cannam@53 466 beats.push_back( static_cast<double>(ibeats[ibeats.size()-i-1]) );
cannam@53 467 }
cannam@52 468 }
cannam@52 469
cannam@52 470