From d145fa6f792d6c44da2feec90507adb94e40323e Mon Sep 17 00:00:00 2001
From: Hans-Christoph Steiner <eighthave@users.sourceforge.net>
Date: Sun, 31 Jul 2011 03:59:16 +0000
Subject: got everything building using the template Makefile

svn path=/trunk/externals/unauthorized/; revision=15173
---
 lpc.c | 252 ++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++
 1 file changed, 252 insertions(+)
 create mode 100644 lpc.c

(limited to 'lpc.c')

diff --git a/lpc.c b/lpc.c
new file mode 100644
index 0000000..33159d4
--- /dev/null
+++ b/lpc.c
@@ -0,0 +1,252 @@
+/*
+vox - a musical real-time vocoder. version 1.0
+Copyright (C) 2000  Simon MORLAT (simon.morlat@free.fr)
+
+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., 59 Temple Place - Suite 330, Boston, MA  02111-1307, USA.
+*/
+
+#include "tables.h"
+#include "lpc.h"
+#define THRES 0.06
+#define Dmin 10.81e-3
+
+/* Levinson Durbin algorithm for computing LPC coefficients using 
+autocorrelation fonction */
+void lev_durb(double *corr,double *lpc_coef)
+{
+  double k[11],tab[11];
+  double err,acc;
+  int i,j;  
+  double *a=tab;
+  double *prev_a=lpc_coef;
+  double *exch;
+  
+  
+  /*init vectors*/
+  for (i=0;i<11;i++)
+  {
+      prev_a[i]=0;
+      a[i]=0;
+  };
+  err=corr[0];
+  for(i=1;i<11;i++)
+  {
+      prev_a[0]=1;
+      acc=0;
+      for(j=0;j<i;j++) 
+      {
+	  acc=acc+prev_a[j]*corr[i-j];
+      };
+      a[i]=k[i]=-acc/err;
+      for(j=1;j<i;j++)
+      {
+	  a[j]=prev_a[j]+k[i]*prev_a[i-j];
+      };
+      err=(1-k[i]*k[i])*err;
+      exch=prev_a;
+      prev_a=a;
+      a=exch;
+  };
+}
+
+void comp_lpc(double *buf_x,double *corr,double *lpc_coef,int n)
+{
+  double buffer[n*3];
+  double acc,max=0;
+  int i,j;
+  /* computes LPC analysis for one subframe */
+  /* hamming windowing*/
+  acc=0;
+  for(i=0;i<2*n;i++)
+  {
+      acc+=buf_x[i]*buf_x[i];
+  };
+  if (acc>THRES) 
+  {
+      for(i=0;i<3*n;i++)
+      {
+	  buffer[i]=buf_x[i-n]*HammingWindowTable[i];
+      };
+      /* autocorrelation computation*/
+      for(i=0;i<11;i++)
+      {
+	  acc=0;
+	  for(j=i;j<n*3;j++)	    
+          {
+	      acc=acc+buffer[j]*buffer[j-i];
+	  };
+	  /* correction with binomial coeffs */
+	  corr[i]=acc;//*BinomialWindowTable[i];
+      };
+      corr[0]=corr[0]*(1.0+1.0/1024.0);
+      lev_durb(corr,lpc_coef);
+  } 
+  else
+  {
+      for(i=0;i<11;i++)
+      {
+	  lpc_coef[i]=0;
+      };
+  }
+}
+  
+
+
+/* LPC to LSP coefficients conversion */
+
+/* evaluate  function C(x) (whose roots are  LSP coeffs)*/
+
+double evalc(double cw,double *fonc)
+{
+  double b[7];
+  double x,res;
+  int k;
+
+  x=cw;
+  b[5]=1;
+  b[6]=0;
+  for(k=4;k>0;k--)
+  {
+      b[k]=2*x*b[k+1]-b[k+2]+fonc[5-k];
+  };
+  res=x*b[1]-b[2]+fonc[5]/2;
+  return(res);
+}
+
+
+
+/* converts LPC vector into LSP frequency vector */
+/* all LSP frenquencies are in [0;PI] but are normalized to be in [0;1] */
+void lpc2lsp(double lpc_coef[],double *f1,double *f2,double lsp_coef[])
+{
+  
+  int i,k=1;
+  double *fonc,*prev_f,*f_exch;
+  double prev_sign1,sign,prev_sign2;
+  double *s, *prev_s,*s_exch;
+  double lpc_exp[11];
+
+  /* first computes an additional bandwidth expansion on LPC coeffs*/
+  for(i=1;i<11;i++)
+  {
+      lpc_exp[i]=lpc_coef[i]*BandExpTable[i];
+  };
+  /* computes the F1 and F2 coeffs*/
+  f1[0]=f2[0]=1;
+  for(i=0;i<5;i++)
+  {
+      f1[i+1]=lpc_exp[i+1]+lpc_exp[10-i]-f1[i];
+      f2[i+1]=lpc_exp[i+1]-lpc_exp[10-i]+f2[i];
+  }; 
+
+   /*find the roots of C(x) alternatively for F1 and F2*/
+  fonc=f1;
+  prev_f=f2;
+  prev_sign1=evalc(1.0,f1);
+  prev_sign2=evalc(1.0,f2);
+  s=&prev_sign1;
+  prev_s=&prev_sign2;
+  for(i=1;i<256;i++)
+  {
+      sign=evalc(CosineTable[i],fonc);
+      if ((sign)*(*s)<0)
+      {
+	  /* interpolate to find root*/
+	  lsp_coef[k]=((double)i-(*s)/(sign-(*s)))/256.0;
+	  k++;
+	  /* chek if all roots are found */
+	  if (k==11) i=257;
+	  (*s)=sign;
+	  /* pointers exchange  */
+	  s_exch=s;
+	  s=prev_s;
+	  prev_s=s_exch;
+	  f_exch=fonc;
+	  fonc=prev_f;
+	  prev_f=f_exch;
+       }
+       else (*s)=sign;
+  }
+  /* if here all roots are not found , use  lspDC vector */
+  if (k!=11)
+  {
+      for(i=1;i<11;i++)
+      {
+	  lsp_coef[i]=LspDcTable[i];
+      };
+  };
+}
+
+
+/* converts lsp frequencies to lpc coeffs */
+
+void lsp2lpc(double *lsp_coef,double *lpc_coef)
+{
+   int i,j=0,index,ok=1;
+   double lspcos[11],delta,tmp,p_avg;
+   double F1[12],F2[12]; /* begin at indice two*/
+
+   F1[0]=0;F1[1]=1;
+   F2[0]=0;F2[1]=1;
+   /* stability check */
+   while(ok && (j<11))
+   {
+       ok=0;
+       for(i=1;i<10;i++)
+       {
+	   if( (lsp_coef[i+1]-lsp_coef[i]) < Dmin)
+	   {
+	       ok=1;
+	       p_avg=(lsp_coef[i]+lsp_coef[i+1])/2.0;
+	       lsp_coef[i]=p_avg-Dmin/2.0;
+	       lsp_coef[i+1]=p_avg+Dmin/2.0;
+	   };
+       };
+       j++;
+   }
+   
+   /* first converts lsp frequencies to lsp coefficients */
+   for (i=1;i<11;i++)
+   {
+       /* interpolation */
+       tmp=lsp_coef[i]*255.0;
+       index=(int)tmp;
+       delta=CosineTable[index+1]-CosineTable[index];
+       lspcos[i]=CosineTable[index]+delta*(tmp-index);
+   };
+
+   for(i=2;i<7;i++)
+   {
+       F1[i]=-2*lspcos[2*i-3]*F1[i-1]+2*F1[i-2];
+       F2[i]=-2*lspcos[2*i-2]*F2[i-1]+2*F2[i-2]; 
+       for(j=i-1;j>1;j--)
+       {
+	   F1[j]=F1[j]-2*lspcos[2*i-3]*F1[j-1]+F1[j-2];
+	   F2[j]=F2[j]-2*lspcos[2*i-2]*F2[j-1]+F2[j-2];
+       };
+   };
+   for(i=6;i>1;i--)
+   {
+       F1[i]=F1[i]+F1[i-1];
+       F2[i]=F2[i]-F2[i-1];
+   };
+   for(i=2;i<7;i++)
+   {
+       lpc_coef[i-1]=(F1[i]+F2[i])*0.5;
+       lpc_coef[i+4]=(F1[8-i]-F2[8-i])*0.5;
+   };
+   lpc_coef[0]=1;
+}
+
-- 
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