ref: a253fd4f37f9bd5c7b461a23ff2d27dc5452f6d5
dir: /src/spectral/tss.c/
/* Copyright (C) 2003 Paul Brossier This program is free software; you can redistribute it and/or modify it under the terms of the GNU General Public License as published by the Free Software Foundation; either version 2 of the License, or (at your option) any later version. This program is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for more details. You should have received a copy of the GNU General Public License along with this program; if not, write to the Free Software Foundation, Inc., 675 Mass Ave, Cambridge, MA 02139, USA. */ /* default values : alfa=4, beta=3, threshold=0.25 */ #include "aubio_priv.h" #include "fvec.h" #include "cvec.h" #include "mathutils.h" #include "spectral/tss.h" struct _aubio_tss_t { smpl_t thrs; smpl_t alfa; smpl_t beta; smpl_t parm; smpl_t thrsfact; fvec_t *theta1; fvec_t *theta2; fvec_t *oft1; fvec_t *oft2; fvec_t *dev; }; void aubio_tss_do(aubio_tss_t *o, cvec_t * input, cvec_t * trans, cvec_t * stead) { uint_t i,j; uint_t test; uint_t nbins = input->length; uint_t channels = input->channels; smpl_t alfa = o->alfa; smpl_t beta = o->beta; smpl_t parm = o->parm; smpl_t ** dev = (smpl_t **)o->dev->data; smpl_t ** oft1 = (smpl_t **)o->oft1->data; smpl_t ** oft2 = (smpl_t **)o->oft2->data; smpl_t ** theta1 = (smpl_t **)o->theta1->data; smpl_t ** theta2 = (smpl_t **)o->theta2->data; /* second phase derivative */ for (i=0;i<channels; i++){ for (j=0;j<nbins; j++){ dev[i][j] = aubio_unwrap2pi(input->phas[i][j] -2.0*theta1[i][j]+theta2[i][j]); theta2[i][j] = theta1[i][j]; theta1[i][j] = input->phas[i][j]; } for (j=0;j<nbins; j++){ /* transient analysis */ test = (ABS(dev[i][j]) > parm*oft1[i][j]); trans->norm[i][j] = input->norm[i][j] * test; trans->phas[i][j] = input->phas[i][j] * test; } for (j=0;j<nbins; j++){ /* steady state analysis */ test = (ABS(dev[i][j]) < parm*oft2[i][j]); stead->norm[i][j] = input->norm[i][j] * test; stead->phas[i][j] = input->phas[i][j] * test; /*increase sstate probability for sines */ test = (trans->norm[i][j]==0.); oft1[i][j] = test; test = (stead->norm[i][j]==0.); oft2[i][j] = test; test = (trans->norm[i][j]>0.); oft1[i][j] += alfa*test; test = (stead->norm[i][j]>0.); oft2[i][j] += alfa*test; test = (oft1[i][j]>1. && trans->norm[i][j]>0.); oft1[i][j] += beta*test; test = (oft2[i][j]>1. && stead->norm[i][j]>0.); oft2[i][j] += beta*test; } } } void aubio_tss_set_thres(aubio_tss_t *o, smpl_t thrs){ o->thrs = thrs; o->parm = thrs*o->thrsfact; } aubio_tss_t * new_aubio_tss(smpl_t thrs, smpl_t alfa, smpl_t beta, uint_t size, uint_t overlap,uint_t channels) { aubio_tss_t * o = AUBIO_NEW(aubio_tss_t); uint_t rsize = size/2+1; o->thrs = thrs; o->thrsfact = TWO_PI*overlap/rsize; o->alfa = alfa; o->beta = beta; o->parm = thrs*o->thrsfact; o->theta1 = new_fvec(rsize,channels); o->theta2 = new_fvec(rsize,channels); o->oft1 = new_fvec(rsize,channels); o->oft2 = new_fvec(rsize,channels); o->dev = new_fvec(rsize,channels); return o; } void del_aubio_tss(aubio_tss_t *s) { free(s->theta1); free(s->theta2); free(s->oft1); free(s->oft2); free(s->dev); free(s); }