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521 lines
13 KiB
C++
521 lines
13 KiB
C++
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/*---------------------------------------------------------------------------*\
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FILE........: nlp.c
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AUTHOR......: David Rowe
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DATE CREATED: 23/3/93
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Non Linear Pitch (NLP) estimation functions.
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\*---------------------------------------------------------------------------*/
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/*
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Copyright (C) 2009 David Rowe
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All rights reserved.
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This program is free software; you can redistribute it and/or modify
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it under the terms of the GNU Lesser General Public License version 2.1, as
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published by the Free Software Foundation. This program is
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distributed in the hope that it will be useful, but WITHOUT ANY
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WARRANTY; without even the implied warranty of MERCHANTABILITY or
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FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public
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License for more details.
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You should have received a copy of the GNU Lesser General Public License
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along with this program; if not, see <http://www.gnu.org/licenses/>.
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*/
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#include <assert.h>
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#include <math.h>
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#include <stdlib.h>
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#include "defines.h"
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#include "nlp.h"
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#include "kiss_fft.h"
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extern CKissFFT kiss;
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/*---------------------------------------------------------------------------*\
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GLOBALS
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\*---------------------------------------------------------------------------*/
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/* 48 tap 600Hz low pass FIR filter coefficients */
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static const float nlp_fir[] =
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{
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-1.0818124e-03,
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-1.1008344e-03,
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-9.2768838e-04,
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-4.2289438e-04,
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5.5034190e-04,
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2.0029849e-03,
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3.7058509e-03,
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5.1449415e-03,
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5.5924666e-03,
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4.3036754e-03,
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8.0284511e-04,
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-4.8204610e-03,
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-1.1705810e-02,
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-1.8199275e-02,
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-2.2065282e-02,
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-2.0920610e-02,
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-1.2808831e-02,
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3.2204775e-03,
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2.6683811e-02,
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5.5520624e-02,
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8.6305944e-02,
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1.1480192e-01,
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1.3674206e-01,
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1.4867556e-01,
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1.4867556e-01,
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1.3674206e-01,
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1.1480192e-01,
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8.6305944e-02,
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5.5520624e-02,
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2.6683811e-02,
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3.2204775e-03,
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-1.2808831e-02,
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-2.0920610e-02,
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-2.2065282e-02,
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-1.8199275e-02,
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-1.1705810e-02,
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-4.8204610e-03,
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8.0284511e-04,
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4.3036754e-03,
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5.5924666e-03,
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5.1449415e-03,
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3.7058509e-03,
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2.0029849e-03,
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5.5034190e-04,
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-4.2289438e-04,
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-9.2768838e-04,
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-1.1008344e-03,
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-1.0818124e-03
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};
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static const float fdmdv_os_filter[]= {
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-0.0008215855034550382,
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-0.0007833023901802921,
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0.001075563790768233,
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0.001199092367787555,
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-0.001765309502928316,
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-0.002055372115328064,
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0.002986877604154257,
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0.003462567920638414,
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-0.004856570111126334,
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-0.005563143845031497,
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0.007533613299748122,
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0.008563932468880897,
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-0.01126857129039911,
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-0.01280782411693687,
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0.01651443896361847,
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0.01894875110322284,
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-0.02421604439474981,
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-0.02845107338464062,
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0.03672973563400258,
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0.04542046150312214,
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-0.06189165826716491,
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-0.08721876380763803,
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0.1496157094199961,
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0.4497962274137046,
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0.4497962274137046,
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0.1496157094199961,
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-0.08721876380763803,
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-0.0618916582671649,
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0.04542046150312216,
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0.03672973563400257,
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-0.02845107338464062,
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-0.02421604439474984,
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0.01894875110322284,
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0.01651443896361848,
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-0.01280782411693687,
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-0.0112685712903991,
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0.008563932468880899,
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0.007533613299748123,
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-0.005563143845031501,
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-0.004856570111126346,
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0.003462567920638419,
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0.002986877604154259,
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-0.002055372115328063,
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-0.001765309502928318,
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0.001199092367787557,
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0.001075563790768233,
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-0.0007833023901802925,
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-0.0008215855034550383
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};
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/*---------------------------------------------------------------------------*\
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nlp_create()
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Initialisation function for NLP pitch estimator.
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\*---------------------------------------------------------------------------*/
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void Cnlp::nlp_create(C2CONST *c2const)
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{
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int i;
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int m = c2const->m_pitch;
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int Fs = c2const->Fs;
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assert((Fs == 8000) || (Fs == 16000));
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snlp.Fs = Fs;
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snlp.m = m;
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/* if running at 16kHz allocate storage for decimating filter memory */
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if (Fs == 16000)
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{
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snlp.Sn16k.resize(FDMDV_OS_TAPS_16K + c2const->n_samp);
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for(i=0; i<FDMDV_OS_TAPS_16K; i++)
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{
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snlp.Sn16k[i] = 0.0;
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}
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/* most processing occurs at 8 kHz sample rate so halve m */
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m /= 2;
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}
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assert(m <= PMAX_M);
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for(i=0; i<m/DEC; i++)
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{
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snlp.w[i] = 0.5 - 0.5*cosf(2*PI*i/(m/DEC-1));
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}
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for(i=0; i<PMAX_M; i++)
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snlp.sq[i] = 0.0;
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snlp.mem_x = 0.0;
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snlp.mem_y = 0.0;
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for(i=0; i<NLP_NTAP; i++)
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snlp.mem_fir[i] = 0.0;
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kiss.fft_alloc(snlp.fft_cfg, PE_FFT_SIZE, false);
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}
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/*---------------------------------------------------------------------------*\
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nlp_destroy()
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Shut down function for NLP pitch estimator.
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\*---------------------------------------------------------------------------*/
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void Cnlp::nlp_destroy()
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{
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snlp.fft_cfg.twiddles.clear();
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}
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/*---------------------------------------------------------------------------*\
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nlp()
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Determines the pitch in samples using the Non Linear Pitch (NLP)
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algorithm [1]. Returns the fundamental in Hz. Note that the actual
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pitch estimate is for the centre of the M sample Sn[] vector, not
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the current N sample input vector. This is (I think) a delay of 2.5
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frames with N=80 samples. You should align further analysis using
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this pitch estimate to be centred on the middle of Sn[].
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Two post processors have been tried, the MBE version (as discussed
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in [1]), and a post processor that checks sub-multiples. Both
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suffer occasional gross pitch errors (i.e. neither are perfect). In
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the presence of background noise the sub-multiple algorithm tends
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towards low F0 which leads to better sounding background noise than
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the MBE post processor.
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A good way to test and develop the NLP pitch estimator is using the
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tnlp (codec2/unittest) and the codec2/octave/plnlp.m Octave script.
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A pitch tracker searching a few frames forward and backward in time
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would be a useful addition.
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References:
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[1] http://rowetel.com/downloads/1997_rowe_phd_thesis.pdf Chapter 4
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\*---------------------------------------------------------------------------*/
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float Cnlp::nlp(
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float Sn[], /* input speech vector */
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int n, /* frames shift (no. new samples in Sn[]) */
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float *pitch, /* estimated pitch period in samples at current Fs */
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// std::complex<float> Sw[], /* Freq domain version of Sn[] */
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// float W[], /* Freq domain window */
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float *prev_f0 /* previous pitch f0 in Hz, memory for pitch tracking */
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)
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{
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float notch; /* current notch filter output */
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std::complex<float> Fw[PE_FFT_SIZE]; /* DFT of squared signal (input/output) */
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float gmax;
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int gmax_bin;
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int m, i, j;
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float best_f0;
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m = snlp.m;
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/* Square, notch filter at DC, and LP filter vector */
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/* If running at 16 kHz decimate to 8 kHz, as NLP ws designed for
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Fs = 8kHz. The decimating filter introduces about 3ms of delay,
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that shouldn't be a problem as pitch changes slowly. */
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if (snlp.Fs == 8000)
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{
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/* Square latest input samples */
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for(i=m-n; i<m; i++)
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{
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snlp.sq[i] = Sn[i]*Sn[i];
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}
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}
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else
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{
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assert(snlp.Fs == 16000);
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/* re-sample at 8 KHz */
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for(i=0; i<n; i++)
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{
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snlp.Sn16k[FDMDV_OS_TAPS_16K+i] = Sn[m-n+i];
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}
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m /= 2;
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n /= 2;
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float Sn8k[n];
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fdmdv_16_to_8(Sn8k, &snlp.Sn16k[FDMDV_OS_TAPS_16K], n);
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/* Square latest input samples */
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for(i=m-n, j=0; i<m; i++, j++)
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{
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snlp.sq[i] = Sn8k[j]*Sn8k[j];
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}
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assert(j <= n);
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}
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for(i=m-n; i<m; i++) /* notch filter at DC */
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{
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notch = snlp.sq[i] - snlp.mem_x;
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notch += COEFF*snlp.mem_y;
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snlp.mem_x = snlp.sq[i];
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snlp.mem_y = notch;
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snlp.sq[i] = notch + 1.0; /* With 0 input vectors to codec,
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kiss_fft() would take a long
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time to execute when running in
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real time. Problem was traced
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to kiss_fft function call in
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this function. Adding this small
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constant fixed problem. Not
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exactly sure why. */
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}
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for(i=m-n; i<m; i++) /* FIR filter vector */
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{
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for(j=0; j<NLP_NTAP-1; j++)
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snlp.mem_fir[j] = snlp.mem_fir[j+1];
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snlp.mem_fir[NLP_NTAP-1] = snlp.sq[i];
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snlp.sq[i] = 0.0;
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for(j=0; j<NLP_NTAP; j++)
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snlp.sq[i] += snlp.mem_fir[j]*nlp_fir[j];
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}
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/* Decimate and DFT */
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for(i=0; i<PE_FFT_SIZE; i++)
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{
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Fw[i].real(0);
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Fw[i].imag(0);
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}
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for(i=0; i<m/DEC; i++)
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{
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Fw[i].real(snlp.sq[i*DEC]*snlp.w[i]);
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}
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// FIXME: check if this can be converted to a real fft
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// since all imag inputs are 0
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codec2_fft_inplace(snlp.fft_cfg, Fw);
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for(i=0; i<PE_FFT_SIZE; i++)
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Fw[i].real(Fw[i].real() * Fw[i].real() + Fw[i].imag() * Fw[i].imag());
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/* todo: express everything in f0, as pitch in samples is dep on Fs */
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int pmin = floor(SAMPLE_RATE*P_MIN_S);
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int pmax = floor(SAMPLE_RATE*P_MAX_S);
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/* find global peak */
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gmax = 0.0;
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gmax_bin = PE_FFT_SIZE*DEC/pmax;
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for(i=PE_FFT_SIZE*DEC/pmax; i<=PE_FFT_SIZE*DEC/pmin; i++)
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{
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if (Fw[i].real() > gmax)
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{
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gmax = Fw[i].real();
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gmax_bin = i;
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}
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}
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best_f0 = post_process_sub_multiples(Fw, pmax, gmax, gmax_bin, prev_f0);
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/* Shift samples in buffer to make room for new samples */
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for(i=0; i<m-n; i++)
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snlp.sq[i] = snlp.sq[i+n];
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/* return pitch period in samples and F0 estimate */
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*pitch = (float)snlp.Fs/best_f0;
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*prev_f0 = best_f0;
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return(best_f0);
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}
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/*---------------------------------------------------------------------------*\
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post_process_sub_multiples()
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Given the global maximma of Fw[] we search integer submultiples for
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local maxima. If local maxima exist and they are above an
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experimentally derived threshold (OK a magic number I pulled out of
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the air) we choose the submultiple as the F0 estimate.
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The rational for this is that the lowest frequency peak of Fw[]
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should be F0, as Fw[] can be considered the autocorrelation function
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of Sw[] (the speech spectrum). However sometimes due to phase
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effects the lowest frequency maxima may not be the global maxima.
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This works OK in practice and favours low F0 values in the presence
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of background noise which means the sinusoidal codec does an OK job
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of synthesising the background noise. High F0 in background noise
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tends to sound more periodic introducing annoying artifacts.
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\*---------------------------------------------------------------------------*/
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float Cnlp::post_process_sub_multiples(std::complex<float> Fw[], int pmax, float gmax, int gmax_bin, float *prev_f0)
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{
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int min_bin, cmax_bin;
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int mult;
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float thresh, best_f0;
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int b, bmin, bmax, lmax_bin;
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float lmax;
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int prev_f0_bin;
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/* post process estimate by searching submultiples */
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mult = 2;
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min_bin = PE_FFT_SIZE*DEC/pmax;
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cmax_bin = gmax_bin;
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prev_f0_bin = *prev_f0*(PE_FFT_SIZE*DEC)/SAMPLE_RATE;
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while(gmax_bin/mult >= min_bin)
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{
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b = gmax_bin/mult; /* determine search interval */
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bmin = 0.8*b;
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bmax = 1.2*b;
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if (bmin < min_bin)
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bmin = min_bin;
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/* lower threshold to favour previous frames pitch estimate,
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this is a form of pitch tracking */
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if ((prev_f0_bin > bmin) && (prev_f0_bin < bmax))
|
||
|
thresh = CNLP*0.5*gmax;
|
||
|
else
|
||
|
thresh = CNLP*gmax;
|
||
|
|
||
|
lmax = 0;
|
||
|
lmax_bin = bmin;
|
||
|
for (b=bmin; b<=bmax; b++) /* look for maximum in interval */
|
||
|
if (Fw[b].real() > lmax)
|
||
|
{
|
||
|
lmax = Fw[b].real();
|
||
|
lmax_bin = b;
|
||
|
}
|
||
|
|
||
|
if (lmax > thresh)
|
||
|
if ((lmax > Fw[lmax_bin-1].real()) && (lmax > Fw[lmax_bin+1].real()))
|
||
|
{
|
||
|
cmax_bin = lmax_bin;
|
||
|
}
|
||
|
|
||
|
mult++;
|
||
|
}
|
||
|
|
||
|
best_f0 = (float)cmax_bin*SAMPLE_RATE/(PE_FFT_SIZE*DEC);
|
||
|
|
||
|
return best_f0;
|
||
|
}
|
||
|
|
||
|
/*---------------------------------------------------------------------------*\
|
||
|
|
||
|
FUNCTION....: fdmdv_16_to_8()
|
||
|
AUTHOR......: David Rowe
|
||
|
DATE CREATED: 9 May 2012
|
||
|
|
||
|
Changes the sample rate of a signal from 16 to 8 kHz.
|
||
|
|
||
|
n is the number of samples at the 8 kHz rate, there are FDMDV_OS*n
|
||
|
samples at the 48 kHz rate. As above however a memory of
|
||
|
FDMDV_OS_TAPS samples is reqd for in16k[] (see t16_8.c unit test as example).
|
||
|
|
||
|
Low pass filter the 16 kHz signal at 4 kHz using the same filter as
|
||
|
the upsampler, then just output every FDMDV_OS-th filtered sample.
|
||
|
|
||
|
Note: this function copied from fdmdv.c, included in nlp.c as a convenience
|
||
|
to avoid linking with another source file.
|
||
|
|
||
|
\*---------------------------------------------------------------------------*/
|
||
|
|
||
|
void Cnlp::fdmdv_16_to_8(float out8k[], float in16k[], int n)
|
||
|
{
|
||
|
float acc;
|
||
|
int i,j,k;
|
||
|
|
||
|
for(i=0, k=0; k<n; i+=FDMDV_OS, k++)
|
||
|
{
|
||
|
acc = 0.0;
|
||
|
for(j=0; j<FDMDV_OS_TAPS_16K; j++)
|
||
|
acc += fdmdv_os_filter[j]*in16k[i-j];
|
||
|
out8k[k] = acc;
|
||
|
}
|
||
|
|
||
|
/* update filter memory */
|
||
|
|
||
|
for(i=-FDMDV_OS_TAPS_16K; i<0; i++)
|
||
|
in16k[i] = in16k[i + n*FDMDV_OS];
|
||
|
}
|
||
|
|
||
|
// there is a little overhead for inplace kiss_fft but this is
|
||
|
// on the powerful platforms like the Raspberry or even x86 PC based ones
|
||
|
// not noticeable
|
||
|
// the reduced usage of RAM and increased performance on STM32 platforms
|
||
|
// should be worth it.
|
||
|
void Cnlp::codec2_fft_inplace(FFT_STATE &cfg, std::complex<float> *inout)
|
||
|
{
|
||
|
std::complex<float> in[512];
|
||
|
// decide whether to use the local stack based buffer for in
|
||
|
// or to allow kiss_fft to allocate RAM
|
||
|
// second part is just to play safe since first method
|
||
|
// is much faster and uses less RAM
|
||
|
if (cfg.nfft <= 512)
|
||
|
{
|
||
|
memcpy(in, inout, cfg.nfft*sizeof(std::complex<float>));
|
||
|
kiss.fft(cfg, in, inout);
|
||
|
}
|
||
|
else
|
||
|
{
|
||
|
kiss.fft(cfg, inout, inout);
|
||
|
}
|
||
|
}
|