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annotate src/OnsetDetectionFunction.cpp @ 53:338f5eb29e41

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Small syntax change for array arguments so they are pointers rather than array[]. Just personal preference.
author Adam Stark <adamstark@users.noreply.github.com>
date Wed, 22 Jan 2014 01:34:04 +0000
parents 45231107c9d6
children baf35f208814
rev   line source
adamstark@38 1 //=======================================================================
adamstark@38 2 /** @file OnsetDetectionFunction.cpp
adamstark@38 3 * @brief A class for calculating onset detection functions
adamstark@38 4 * @author Adam Stark
adamstark@38 5 * @copyright Copyright (C) 2008-2014 Queen Mary University of London
adamstark@38 6 *
adamstark@38 7 * This program is free software: you can redistribute it and/or modify
adamstark@38 8 * it under the terms of the GNU General Public License as published by
adamstark@38 9 * the Free Software Foundation, either version 3 of the License, or
adamstark@38 10 * (at your option) any later version.
adamstark@38 11 *
adamstark@38 12 * This program is distributed in the hope that it will be useful,
adamstark@38 13 * but WITHOUT ANY WARRANTY; without even the implied warranty of
adamstark@38 14 * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
adamstark@38 15 * GNU General Public License for more details.
adamstark@38 16 *
adamstark@38 17 * You should have received a copy of the GNU General Public License
adamstark@38 18 * along with this program. If not, see <http://www.gnu.org/licenses/>.
adamstark@38 19 */
adamstark@38 20 //=======================================================================
adamstark@38 21
adamstark@38 22 #include <math.h>
adamstark@38 23 #include "OnsetDetectionFunction.h"
adamstark@38 24
adamstark@52 25 //=======================================================================
adamstark@38 26 OnsetDetectionFunction :: OnsetDetectionFunction(int arg_hsize,int arg_fsize,int arg_df_type,int arg_win_type)
adamstark@38 27 {
adamstark@38 28 // indicate that we have not initialised yet
adamstark@38 29 initialised = 0;
adamstark@38 30
adamstark@38 31 // set pi
adamstark@38 32 pi = 3.14159265358979;
adamstark@38 33
adamstark@38 34 // initialise with arguments to constructor
adamstark@38 35 initialise(arg_hsize,arg_fsize,arg_df_type,arg_win_type);
adamstark@38 36 }
adamstark@38 37
adamstark@38 38
adamstark@52 39 //=======================================================================
adamstark@38 40 OnsetDetectionFunction :: ~OnsetDetectionFunction()
adamstark@38 41 {
adamstark@38 42 // destroy fft plan
adamstark@38 43 fftw_destroy_plan(p);
adamstark@38 44 fftw_free(in);
adamstark@38 45 fftw_free(out);
adamstark@38 46
adamstark@38 47 // deallocate memory
adamstark@38 48 delete [] frame;
adamstark@38 49 frame = NULL;
adamstark@38 50 delete [] window;
adamstark@38 51 window = NULL;
adamstark@38 52 delete [] wframe;
adamstark@38 53 wframe = NULL;
adamstark@38 54 delete [] mag;
adamstark@38 55 mag = NULL;
adamstark@38 56 delete [] mag_old;
adamstark@38 57 mag_old = NULL;
adamstark@38 58 delete [] phase;
adamstark@38 59 phase = NULL;
adamstark@38 60 delete [] phase_old;
adamstark@38 61 phase_old = NULL;
adamstark@38 62 delete [] phase_old_2;
adamstark@38 63 phase_old_2 = NULL;
adamstark@38 64 }
adamstark@38 65
adamstark@52 66 //=======================================================================
adamstark@38 67 void OnsetDetectionFunction :: initialise(int arg_hsize,int arg_fsize,int arg_df_type,int arg_win_type)
adamstark@38 68 {
adamstark@38 69 if (initialised == 1) // if we have already initialised some buffers and an FFT plan
adamstark@38 70 {
adamstark@38 71 //////////////////////////////////
adamstark@38 72 // TIDY UP FIRST - If initialise is called after the class has been initialised
adamstark@38 73 // then we want to free up memory and cancel existing FFT plans
adamstark@38 74
adamstark@38 75 // destroy fft plan
adamstark@38 76 fftw_destroy_plan(p);
adamstark@38 77 fftw_free(in);
adamstark@38 78 fftw_free(out);
adamstark@38 79
adamstark@38 80
adamstark@38 81 // deallocate memory
adamstark@38 82 delete [] frame;
adamstark@38 83 frame = NULL;
adamstark@38 84 delete [] window;
adamstark@38 85 window = NULL;
adamstark@38 86 delete [] wframe;
adamstark@38 87 wframe = NULL;
adamstark@38 88 delete [] mag;
adamstark@38 89 mag = NULL;
adamstark@38 90 delete [] mag_old;
adamstark@38 91 mag_old = NULL;
adamstark@38 92 delete [] phase;
adamstark@38 93 phase = NULL;
adamstark@38 94 delete [] phase_old;
adamstark@38 95 phase_old = NULL;
adamstark@38 96 delete [] phase_old_2;
adamstark@38 97 phase_old_2 = NULL;
adamstark@38 98
adamstark@38 99 ////// END TIDY UP ///////////////
adamstark@38 100 //////////////////////////////////
adamstark@38 101 }
adamstark@38 102
adamstark@38 103 hopsize = arg_hsize; // set hopsize
adamstark@38 104 framesize = arg_fsize; // set framesize
adamstark@38 105
adamstark@38 106 df_type = arg_df_type; // set detection function type
adamstark@38 107
adamstark@38 108 // initialise buffers
adamstark@38 109 frame = new double[framesize];
adamstark@38 110 window = new double[framesize];
adamstark@38 111 wframe = new double[framesize];
adamstark@38 112
adamstark@38 113 mag = new double[framesize];
adamstark@38 114 mag_old = new double[framesize];
adamstark@38 115
adamstark@38 116 phase = new double[framesize];
adamstark@38 117 phase_old = new double[framesize];
adamstark@38 118 phase_old_2 = new double[framesize];
adamstark@38 119
adamstark@38 120
adamstark@38 121 // set the window to the specified type
adamstark@38 122 switch (arg_win_type){
adamstark@38 123 case 0:
adamstark@38 124 set_win_rectangular(); // Rectangular window
adamstark@38 125 break;
adamstark@38 126 case 1:
adamstark@38 127 set_win_hanning(); // Hanning Window
adamstark@38 128 break;
adamstark@38 129 case 2:
adamstark@38 130 set_win_hamming(); // Hamming Window
adamstark@38 131 break;
adamstark@38 132 case 3:
adamstark@38 133 set_win_blackman(); // Blackman Window
adamstark@38 134 break;
adamstark@38 135 case 4:
adamstark@38 136 set_win_tukey(); // Tukey Window
adamstark@38 137 break;
adamstark@38 138 default:
adamstark@38 139 set_win_hanning(); // DEFAULT: Hanning Window
adamstark@38 140 }
adamstark@38 141
adamstark@38 142
adamstark@38 143
adamstark@38 144
adamstark@38 145 // initialise previous magnitude spectrum to zero
adamstark@38 146 for (int i = 0;i < framesize;i++)
adamstark@38 147 {
adamstark@38 148 mag_old[i] = 0.0;
adamstark@38 149 phase_old[i] = 0.0;
adamstark@38 150 phase_old_2[i] = 0.0;
adamstark@38 151 frame[i] = 0.0;
adamstark@38 152 }
adamstark@38 153
adamstark@38 154 energy_sum_old = 0.0; // initialise previous energy sum value to zero
adamstark@38 155
adamstark@38 156 /* Init fft */
adamstark@38 157 in = (fftw_complex*) fftw_malloc(sizeof(fftw_complex) * framesize); // complex array to hold fft data
adamstark@38 158 out = (fftw_complex*) fftw_malloc(sizeof(fftw_complex) * framesize); // complex array to hold fft data
adamstark@38 159 p = fftw_plan_dft_1d(framesize, in, out, FFTW_FORWARD, FFTW_ESTIMATE); // FFT plan initialisation
adamstark@38 160
adamstark@38 161 initialised = 1;
adamstark@38 162 }
adamstark@38 163
adamstark@52 164 //=======================================================================
adamstark@38 165 void OnsetDetectionFunction :: set_df_type(int arg_df_type)
adamstark@38 166 {
adamstark@38 167 df_type = arg_df_type; // set detection function type
adamstark@38 168 }
adamstark@38 169
adamstark@52 170 //=======================================================================
adamstark@53 171 double OnsetDetectionFunction :: getDFsample(double *inputbuffer)
adamstark@38 172 {
adamstark@38 173 double df_sample;
adamstark@38 174
adamstark@38 175 // shift audio samples back in frame by hop size
adamstark@38 176 for (int i = 0; i < (framesize-hopsize);i++)
adamstark@38 177 {
adamstark@38 178 frame[i] = frame[i+hopsize];
adamstark@38 179 }
adamstark@38 180
adamstark@38 181 // add new samples to frame from input buffer
adamstark@38 182 int j = 0;
adamstark@38 183 for (int i = (framesize-hopsize);i < framesize;i++)
adamstark@38 184 {
adamstark@38 185 frame[i] = inputbuffer[j];
adamstark@38 186 j++;
adamstark@38 187 }
adamstark@38 188
adamstark@38 189 switch (df_type){
adamstark@38 190 case 0:
adamstark@38 191 df_sample = energy_envelope(); // calculate energy envelope detection function sample
adamstark@38 192 break;
adamstark@38 193 case 1:
adamstark@38 194 df_sample = energy_difference(); // calculate half-wave rectified energy difference detection function sample
adamstark@38 195 break;
adamstark@38 196 case 2:
adamstark@38 197 df_sample = spectral_difference(); // calculate spectral difference detection function sample
adamstark@38 198 break;
adamstark@38 199 case 3:
adamstark@38 200 df_sample = spectral_difference_hwr(); // calculate spectral difference detection function sample (half wave rectified)
adamstark@38 201 break;
adamstark@38 202 case 4:
adamstark@38 203 df_sample = phase_deviation(); // calculate phase deviation detection function sample (half wave rectified)
adamstark@38 204 break;
adamstark@38 205 case 5:
adamstark@38 206 df_sample = complex_spectral_difference(); // calcualte complex spectral difference detection function sample
adamstark@38 207 break;
adamstark@38 208 case 6:
adamstark@38 209 df_sample = complex_spectral_difference_hwr(); // calcualte complex spectral difference detection function sample (half-wave rectified)
adamstark@38 210 break;
adamstark@38 211 case 7:
adamstark@38 212 df_sample = high_frequency_content(); // calculate high frequency content detection function sample
adamstark@38 213 break;
adamstark@38 214 case 8:
adamstark@38 215 df_sample = high_frequency_spectral_difference(); // calculate high frequency spectral difference detection function sample
adamstark@38 216 break;
adamstark@38 217 case 9:
adamstark@38 218 df_sample = high_frequency_spectral_difference_hwr(); // calculate high frequency spectral difference detection function (half-wave rectified)
adamstark@38 219 break;
adamstark@38 220 default:
adamstark@38 221 df_sample = 1.0;
adamstark@38 222 }
adamstark@38 223
adamstark@38 224 return df_sample;
adamstark@38 225 }
adamstark@38 226
adamstark@38 227
adamstark@52 228 //=======================================================================
adamstark@38 229 void OnsetDetectionFunction :: perform_FFT()
adamstark@38 230 {
adamstark@38 231 int fsize2 = (framesize/2);
adamstark@38 232
adamstark@38 233 // window frame and copy to complex array, swapping the first and second half of the signal
adamstark@38 234 for (int i = 0;i < fsize2;i++)
adamstark@38 235 {
adamstark@38 236 in[i][0] = frame[i+fsize2] * window[i+fsize2];
adamstark@38 237 in[i][1] = 0.0;
adamstark@38 238 in[i+fsize2][0] = frame[i] * window[i];
adamstark@38 239 in[i+fsize2][1] = 0.0;
adamstark@38 240 }
adamstark@38 241
adamstark@38 242 // perform the fft
adamstark@38 243 fftw_execute(p);
adamstark@38 244 }
adamstark@38 245
adamstark@38 246 ////////////////////////////////////////////////////////////////////////////////////////////////
adamstark@38 247 ////////////////////////////////////////////////////////////////////////////////////////////////
adamstark@38 248 ////////////////////////////// Methods for Detection Functions /////////////////////////////////
adamstark@38 249
adamstark@52 250 //=======================================================================
adamstark@38 251 double OnsetDetectionFunction :: energy_envelope()
adamstark@38 252 {
adamstark@38 253 double sum;
adamstark@38 254
adamstark@38 255 sum = 0; // initialise sum
adamstark@38 256
adamstark@38 257 // sum the squares of the samples
adamstark@38 258 for (int i = 0;i < framesize;i++)
adamstark@38 259 {
adamstark@38 260 sum = sum + (frame[i]*frame[i]);
adamstark@38 261 }
adamstark@38 262
adamstark@38 263 return sum; // return sum
adamstark@38 264 }
adamstark@38 265
adamstark@52 266 //=======================================================================
adamstark@38 267 double OnsetDetectionFunction :: energy_difference()
adamstark@38 268 {
adamstark@38 269 double sum;
adamstark@38 270 double sample;
adamstark@38 271
adamstark@38 272 sum = 0; // initialise sum
adamstark@38 273
adamstark@38 274 // sum the squares of the samples
adamstark@38 275 for (int i = 0;i < framesize;i++)
adamstark@38 276 {
adamstark@38 277 sum = sum + (frame[i]*frame[i]);
adamstark@38 278 }
adamstark@38 279
adamstark@38 280 sample = sum - energy_sum_old; // sample is first order difference in energy
adamstark@38 281
adamstark@38 282 energy_sum_old = sum; // store energy value for next calculation
adamstark@38 283
adamstark@38 284 if (sample > 0)
adamstark@38 285 {
adamstark@38 286 return sample; // return difference
adamstark@38 287 }
adamstark@38 288 else
adamstark@38 289 {
adamstark@38 290 return 0;
adamstark@38 291 }
adamstark@38 292 }
adamstark@38 293
adamstark@52 294 //=======================================================================
adamstark@38 295 double OnsetDetectionFunction :: spectral_difference()
adamstark@38 296 {
adamstark@38 297 double diff;
adamstark@38 298 double sum;
adamstark@38 299
adamstark@38 300 // perform the FFT
adamstark@38 301 perform_FFT();
adamstark@38 302
adamstark@38 303 // compute first (N/2)+1 mag values
adamstark@38 304 for (int i = 0;i < (framesize/2)+1;i++)
adamstark@38 305 {
adamstark@38 306 mag[i] = sqrt(pow(out[i][0],2) + pow(out[i][1],2));
adamstark@38 307 }
adamstark@38 308 // mag spec symmetric above (N/2)+1 so copy previous values
adamstark@38 309 for (int i = (framesize/2)+1;i < framesize;i++)
adamstark@38 310 {
adamstark@38 311 mag[i] = mag[framesize-i];
adamstark@38 312 }
adamstark@38 313
adamstark@38 314 sum = 0; // initialise sum to zero
adamstark@38 315
adamstark@38 316 for (int i = 0;i < framesize;i++)
adamstark@38 317 {
adamstark@38 318 // calculate difference
adamstark@38 319 diff = mag[i] - mag_old[i];
adamstark@38 320
adamstark@38 321 // ensure all difference values are positive
adamstark@38 322 if (diff < 0)
adamstark@38 323 {
adamstark@38 324 diff = diff*-1;
adamstark@38 325 }
adamstark@38 326
adamstark@38 327 // add difference to sum
adamstark@38 328 sum = sum+diff;
adamstark@38 329
adamstark@38 330 // store magnitude spectrum bin for next detection function sample calculation
adamstark@38 331 mag_old[i] = mag[i];
adamstark@38 332 }
adamstark@38 333
adamstark@38 334 return sum;
adamstark@38 335 }
adamstark@38 336
adamstark@52 337 //=======================================================================
adamstark@38 338 double OnsetDetectionFunction :: spectral_difference_hwr()
adamstark@38 339 {
adamstark@38 340 double diff;
adamstark@38 341 double sum;
adamstark@38 342
adamstark@38 343 // perform the FFT
adamstark@38 344 perform_FFT();
adamstark@38 345
adamstark@38 346 // compute first (N/2)+1 mag values
adamstark@38 347 for (int i = 0;i < (framesize/2)+1;i++)
adamstark@38 348 {
adamstark@38 349 mag[i] = sqrt(pow(out[i][0],2) + pow(out[i][1],2));
adamstark@38 350 }
adamstark@38 351 // mag spec symmetric above (N/2)+1 so copy previous values
adamstark@38 352 for (int i = (framesize/2)+1;i < framesize;i++)
adamstark@38 353 {
adamstark@38 354 mag[i] = mag[framesize-i];
adamstark@38 355 }
adamstark@38 356
adamstark@38 357 sum = 0; // initialise sum to zero
adamstark@38 358
adamstark@38 359 for (int i = 0;i < framesize;i++)
adamstark@38 360 {
adamstark@38 361 // calculate difference
adamstark@38 362 diff = mag[i] - mag_old[i];
adamstark@38 363
adamstark@38 364 // only add up positive differences
adamstark@38 365 if (diff > 0)
adamstark@38 366 {
adamstark@38 367 // add difference to sum
adamstark@38 368 sum = sum+diff;
adamstark@38 369 }
adamstark@38 370
adamstark@38 371
adamstark@38 372
adamstark@38 373 // store magnitude spectrum bin for next detection function sample calculation
adamstark@38 374 mag_old[i] = mag[i];
adamstark@38 375 }
adamstark@38 376
adamstark@38 377 return sum;
adamstark@38 378 }
adamstark@38 379
adamstark@38 380
adamstark@52 381 //=======================================================================
adamstark@38 382 double OnsetDetectionFunction :: phase_deviation()
adamstark@38 383 {
adamstark@38 384 double dev,pdev;
adamstark@38 385 double sum;
adamstark@38 386
adamstark@38 387 // perform the FFT
adamstark@38 388 perform_FFT();
adamstark@38 389
adamstark@38 390 sum = 0; // initialise sum to zero
adamstark@38 391
adamstark@38 392 // compute phase values from fft output and sum deviations
adamstark@38 393 for (int i = 0;i < framesize;i++)
adamstark@38 394 {
adamstark@38 395 // calculate phase value
adamstark@38 396 phase[i] = atan2(out[i][1],out[i][0]);
adamstark@38 397
adamstark@38 398 // calculate magnitude value
adamstark@38 399 mag[i] = sqrt(pow(out[i][0],2) + pow(out[i][1],2));
adamstark@38 400
adamstark@38 401
adamstark@38 402 // if bin is not just a low energy bin then examine phase deviation
adamstark@38 403 if (mag[i] > 0.1)
adamstark@38 404 {
adamstark@38 405 dev = phase[i] - (2*phase_old[i]) + phase_old_2[i]; // phase deviation
adamstark@38 406 pdev = princarg(dev); // wrap into [-pi,pi] range
adamstark@38 407
adamstark@38 408 // make all values positive
adamstark@38 409 if (pdev < 0)
adamstark@38 410 {
adamstark@38 411 pdev = pdev*-1;
adamstark@38 412 }
adamstark@38 413
adamstark@38 414 // add to sum
adamstark@38 415 sum = sum + pdev;
adamstark@38 416 }
adamstark@38 417
adamstark@38 418 // store values for next calculation
adamstark@38 419 phase_old_2[i] = phase_old[i];
adamstark@38 420 phase_old[i] = phase[i];
adamstark@38 421 }
adamstark@38 422
adamstark@38 423 return sum;
adamstark@38 424 }
adamstark@38 425
adamstark@52 426 //=======================================================================
adamstark@38 427 double OnsetDetectionFunction :: complex_spectral_difference()
adamstark@38 428 {
adamstark@38 429 double dev,pdev;
adamstark@38 430 double sum;
adamstark@38 431 double mag_diff,phase_diff;
adamstark@38 432 double value;
adamstark@38 433
adamstark@38 434 // perform the FFT
adamstark@38 435 perform_FFT();
adamstark@38 436
adamstark@38 437 sum = 0; // initialise sum to zero
adamstark@38 438
adamstark@38 439 // compute phase values from fft output and sum deviations
adamstark@38 440 for (int i = 0;i < framesize;i++)
adamstark@38 441 {
adamstark@38 442 // calculate phase value
adamstark@38 443 phase[i] = atan2(out[i][1],out[i][0]);
adamstark@38 444
adamstark@38 445 // calculate magnitude value
adamstark@38 446 mag[i] = sqrt(pow(out[i][0],2) + pow(out[i][1],2));
adamstark@38 447
adamstark@38 448
adamstark@38 449 // phase deviation
adamstark@38 450 dev = phase[i] - (2*phase_old[i]) + phase_old_2[i];
adamstark@38 451
adamstark@38 452 // wrap into [-pi,pi] range
adamstark@38 453 pdev = princarg(dev);
adamstark@38 454
adamstark@38 455
adamstark@38 456 // calculate magnitude difference (real part of Euclidean distance between complex frames)
adamstark@38 457 mag_diff = mag[i] - mag_old[i];
adamstark@38 458
adamstark@38 459 // calculate phase difference (imaginary part of Euclidean distance between complex frames)
adamstark@38 460 phase_diff = -mag[i]*sin(pdev);
adamstark@38 461
adamstark@38 462
adamstark@38 463
adamstark@38 464 // square real and imaginary parts, sum and take square root
adamstark@38 465 value = sqrt(pow(mag_diff,2) + pow(phase_diff,2));
adamstark@38 466
adamstark@38 467
adamstark@38 468 // add to sum
adamstark@38 469 sum = sum + value;
adamstark@38 470
adamstark@38 471
adamstark@38 472 // store values for next calculation
adamstark@38 473 phase_old_2[i] = phase_old[i];
adamstark@38 474 phase_old[i] = phase[i];
adamstark@38 475 mag_old[i] = mag[i];
adamstark@38 476 }
adamstark@38 477
adamstark@38 478 return sum;
adamstark@38 479 }
adamstark@38 480
adamstark@52 481 //=======================================================================
adamstark@38 482 double OnsetDetectionFunction :: complex_spectral_difference_hwr()
adamstark@38 483 {
adamstark@38 484 double dev,pdev;
adamstark@38 485 double sum;
adamstark@38 486 double mag_diff,phase_diff;
adamstark@38 487 double value;
adamstark@38 488
adamstark@38 489 // perform the FFT
adamstark@38 490 perform_FFT();
adamstark@38 491
adamstark@38 492 sum = 0; // initialise sum to zero
adamstark@38 493
adamstark@38 494 // compute phase values from fft output and sum deviations
adamstark@38 495 for (int i = 0;i < framesize;i++)
adamstark@38 496 {
adamstark@38 497 // calculate phase value
adamstark@38 498 phase[i] = atan2(out[i][1],out[i][0]);
adamstark@38 499
adamstark@38 500 // calculate magnitude value
adamstark@38 501 mag[i] = sqrt(pow(out[i][0],2) + pow(out[i][1],2));
adamstark@38 502
adamstark@38 503
adamstark@38 504 // phase deviation
adamstark@38 505 dev = phase[i] - (2*phase_old[i]) + phase_old_2[i];
adamstark@38 506
adamstark@38 507 // wrap into [-pi,pi] range
adamstark@38 508 pdev = princarg(dev);
adamstark@38 509
adamstark@38 510
adamstark@38 511 // calculate magnitude difference (real part of Euclidean distance between complex frames)
adamstark@38 512 mag_diff = mag[i] - mag_old[i];
adamstark@38 513
adamstark@38 514 // if we have a positive change in magnitude, then include in sum, otherwise ignore (half-wave rectification)
adamstark@38 515 if (mag_diff > 0)
adamstark@38 516 {
adamstark@38 517 // calculate phase difference (imaginary part of Euclidean distance between complex frames)
adamstark@38 518 phase_diff = -mag[i]*sin(pdev);
adamstark@38 519
adamstark@38 520 // square real and imaginary parts, sum and take square root
adamstark@38 521 value = sqrt(pow(mag_diff,2) + pow(phase_diff,2));
adamstark@38 522
adamstark@38 523 // add to sum
adamstark@38 524 sum = sum + value;
adamstark@38 525 }
adamstark@38 526
adamstark@38 527 // store values for next calculation
adamstark@38 528 phase_old_2[i] = phase_old[i];
adamstark@38 529 phase_old[i] = phase[i];
adamstark@38 530 mag_old[i] = mag[i];
adamstark@38 531 }
adamstark@38 532
adamstark@38 533 return sum;
adamstark@38 534 }
adamstark@38 535
adamstark@38 536
adamstark@52 537 //=======================================================================
adamstark@38 538 double OnsetDetectionFunction :: high_frequency_content()
adamstark@38 539 {
adamstark@38 540 double sum;
adamstark@38 541
adamstark@38 542 // perform the FFT
adamstark@38 543 perform_FFT();
adamstark@38 544
adamstark@38 545 sum = 0; // initialise sum to zero
adamstark@38 546
adamstark@38 547 // compute phase values from fft output and sum deviations
adamstark@38 548 for (int i = 0;i < framesize;i++)
adamstark@38 549 {
adamstark@38 550 // calculate magnitude value
adamstark@38 551 mag[i] = sqrt(pow(out[i][0],2) + pow(out[i][1],2));
adamstark@38 552
adamstark@38 553
adamstark@38 554 sum = sum + (mag[i]*((double) (i+1)));
adamstark@38 555
adamstark@38 556 // store values for next calculation
adamstark@38 557 mag_old[i] = mag[i];
adamstark@38 558 }
adamstark@38 559
adamstark@38 560 return sum;
adamstark@38 561 }
adamstark@38 562
adamstark@52 563 //=======================================================================
adamstark@38 564 double OnsetDetectionFunction :: high_frequency_spectral_difference()
adamstark@38 565 {
adamstark@38 566 double sum;
adamstark@38 567 double mag_diff;
adamstark@38 568
adamstark@38 569 // perform the FFT
adamstark@38 570 perform_FFT();
adamstark@38 571
adamstark@38 572 sum = 0; // initialise sum to zero
adamstark@38 573
adamstark@38 574 // compute phase values from fft output and sum deviations
adamstark@38 575 for (int i = 0;i < framesize;i++)
adamstark@38 576 {
adamstark@38 577 // calculate magnitude value
adamstark@38 578 mag[i] = sqrt(pow(out[i][0],2) + pow(out[i][1],2));
adamstark@38 579
adamstark@38 580 // calculate difference
adamstark@38 581 mag_diff = mag[i] - mag_old[i];
adamstark@38 582
adamstark@38 583 if (mag_diff < 0)
adamstark@38 584 {
adamstark@38 585 mag_diff = -mag_diff;
adamstark@38 586 }
adamstark@38 587
adamstark@38 588 sum = sum + (mag_diff*((double) (i+1)));
adamstark@38 589
adamstark@38 590 // store values for next calculation
adamstark@38 591 mag_old[i] = mag[i];
adamstark@38 592 }
adamstark@38 593
adamstark@38 594 return sum;
adamstark@38 595 }
adamstark@38 596
adamstark@52 597 //=======================================================================
adamstark@38 598 double OnsetDetectionFunction :: high_frequency_spectral_difference_hwr()
adamstark@38 599 {
adamstark@38 600 double sum;
adamstark@38 601 double mag_diff;
adamstark@38 602
adamstark@38 603 // perform the FFT
adamstark@38 604 perform_FFT();
adamstark@38 605
adamstark@38 606 sum = 0; // initialise sum to zero
adamstark@38 607
adamstark@38 608 // compute phase values from fft output and sum deviations
adamstark@38 609 for (int i = 0;i < framesize;i++)
adamstark@38 610 {
adamstark@38 611 // calculate magnitude value
adamstark@38 612 mag[i] = sqrt(pow(out[i][0],2) + pow(out[i][1],2));
adamstark@38 613
adamstark@38 614 // calculate difference
adamstark@38 615 mag_diff = mag[i] - mag_old[i];
adamstark@38 616
adamstark@38 617 if (mag_diff > 0)
adamstark@38 618 {
adamstark@38 619 sum = sum + (mag_diff*((double) (i+1)));
adamstark@38 620 }
adamstark@38 621
adamstark@38 622 // store values for next calculation
adamstark@38 623 mag_old[i] = mag[i];
adamstark@38 624 }
adamstark@38 625
adamstark@38 626 return sum;
adamstark@38 627 }
adamstark@38 628
adamstark@38 629
adamstark@38 630 ////////////////////////////////////////////////////////////////////////////////////////////////
adamstark@38 631 ////////////////////////////////////////////////////////////////////////////////////////////////
adamstark@38 632 ////////////////////////////// Methods to Calculate Windows ////////////////////////////////////
adamstark@38 633
adamstark@52 634 //=======================================================================
adamstark@38 635 void OnsetDetectionFunction :: set_win_hanning()
adamstark@38 636 {
adamstark@38 637 double N; // variable to store framesize minus 1
adamstark@38 638
adamstark@38 639 N = (double) (framesize-1); // framesize minus 1
adamstark@38 640
adamstark@38 641 // Hanning window calculation
adamstark@38 642 for (int n = 0;n < framesize;n++)
adamstark@38 643 {
adamstark@38 644 window[n] = 0.5*(1-cos(2*pi*(n/N)));
adamstark@38 645 }
adamstark@38 646 }
adamstark@38 647
adamstark@52 648 //=======================================================================
adamstark@38 649 void OnsetDetectionFunction :: set_win_hamming()
adamstark@38 650 {
adamstark@38 651 double N; // variable to store framesize minus 1
adamstark@38 652 double n_val; // double version of index 'n'
adamstark@38 653
adamstark@38 654 N = (double) (framesize-1); // framesize minus 1
adamstark@38 655 n_val = 0;
adamstark@38 656
adamstark@38 657 // Hamming window calculation
adamstark@38 658 for (int n = 0;n < framesize;n++)
adamstark@38 659 {
adamstark@38 660 window[n] = 0.54 - (0.46*cos(2*pi*(n_val/N)));
adamstark@38 661 n_val = n_val+1;
adamstark@38 662 }
adamstark@38 663 }
adamstark@38 664
adamstark@52 665 //=======================================================================
adamstark@38 666 void OnsetDetectionFunction :: set_win_blackman()
adamstark@38 667 {
adamstark@38 668 double N; // variable to store framesize minus 1
adamstark@38 669 double n_val; // double version of index 'n'
adamstark@38 670
adamstark@38 671 N = (double) (framesize-1); // framesize minus 1
adamstark@38 672 n_val = 0;
adamstark@38 673
adamstark@38 674 // Blackman window calculation
adamstark@38 675 for (int n = 0;n < framesize;n++)
adamstark@38 676 {
adamstark@38 677 window[n] = 0.42 - (0.5*cos(2*pi*(n_val/N))) + (0.08*cos(4*pi*(n_val/N)));
adamstark@38 678 n_val = n_val+1;
adamstark@38 679 }
adamstark@38 680 }
adamstark@38 681
adamstark@52 682 //=======================================================================
adamstark@38 683 void OnsetDetectionFunction :: set_win_tukey()
adamstark@38 684 {
adamstark@38 685 double N; // variable to store framesize minus 1
adamstark@38 686 double n_val; // double version of index 'n'
adamstark@38 687 double alpha; // alpha [default value = 0.5];
adamstark@38 688
adamstark@38 689 alpha = 0.5;
adamstark@38 690
adamstark@38 691 N = (double) (framesize-1); // framesize minus 1
adamstark@38 692
adamstark@38 693 // Tukey window calculation
adamstark@38 694
adamstark@38 695 n_val = (double) (-1*((framesize/2)))+1;
adamstark@38 696
adamstark@38 697 for (int n = 0;n < framesize;n++) // left taper
adamstark@38 698 {
adamstark@38 699 if ((n_val >= 0) && (n_val <= (alpha*(N/2))))
adamstark@38 700 {
adamstark@38 701 window[n] = 1.0;
adamstark@38 702 }
adamstark@38 703 else if ((n_val <= 0) && (n_val >= (-1*alpha*(N/2))))
adamstark@38 704 {
adamstark@38 705 window[n] = 1.0;
adamstark@38 706 }
adamstark@38 707 else
adamstark@38 708 {
adamstark@38 709 window[n] = 0.5*(1+cos(pi*(((2*n_val)/(alpha*N))-1)));
adamstark@38 710 }
adamstark@38 711
adamstark@38 712 n_val = n_val+1;
adamstark@38 713 }
adamstark@38 714
adamstark@38 715 }
adamstark@38 716
adamstark@52 717 //=======================================================================
adamstark@38 718 void OnsetDetectionFunction :: set_win_rectangular()
adamstark@38 719 {
adamstark@38 720 // Rectangular window calculation
adamstark@38 721 for (int n = 0;n < framesize;n++)
adamstark@38 722 {
adamstark@38 723 window[n] = 1.0;
adamstark@38 724 }
adamstark@38 725 }
adamstark@38 726
adamstark@38 727
adamstark@38 728
adamstark@38 729 ////////////////////////////////////////////////////////////////////////////////////////////////
adamstark@38 730 ////////////////////////////////////////////////////////////////////////////////////////////////
adamstark@38 731 ///////////////////////////////// Other Handy Methods //////////////////////////////////////////
adamstark@38 732
adamstark@52 733 //=======================================================================
adamstark@38 734 double OnsetDetectionFunction :: princarg(double phaseval)
adamstark@38 735 {
adamstark@38 736 // if phase value is less than or equal to -pi then add 2*pi
adamstark@38 737 while (phaseval <= (-pi))
adamstark@38 738 {
adamstark@38 739 phaseval = phaseval + (2*pi);
adamstark@38 740 }
adamstark@38 741
adamstark@38 742 // if phase value is larger than pi, then subtract 2*pi
adamstark@38 743 while (phaseval > pi)
adamstark@38 744 {
adamstark@38 745 phaseval = phaseval - (2*pi);
adamstark@38 746 }
adamstark@38 747
adamstark@38 748 return phaseval;
adamstark@38 749 }
adamstark@38 750
adamstark@38 751
adamstark@38 752
adamstark@38 753
adamstark@38 754
adamstark@38 755
adamstark@38 756
adamstark@38 757
adamstark@38 758
adamstark@38 759
adamstark@38 760
adamstark@38 761
adamstark@38 762