www.pudn.com > source.rar > LPCFUNC.C
/* ITU-T G.729 Software Package Release 2 (November 2006) */
/*
ITU-T G.729 Annex C - Reference C code for floating point
implementation of G.729
Version 1.01 of 15.September.98
*/
/*
----------------------------------------------------------------------
COPYRIGHT NOTICE
----------------------------------------------------------------------
ITU-T G.729 Annex C ANSI C source code
Copyright (C) 1998, AT&T, France Telecom, NTT, University of
Sherbrooke. All rights reserved.
----------------------------------------------------------------------
*/
/*
File : LPCFUNC.C
Used for the floating point version of G.729 main body
(not for G.729A)
*/
#include
#include "typedef.h"
#include "ld8k.h"
#include "tab_ld8k.h"
/* local function */
static void get_lsp_pol(FLOAT lsf[],FLOAT f[]);
static void lsp_az(FLOAT *lsp, FLOAT *a);
/*-----------------------------------------------------------------------------
* lsp_az - convert LSPs to predictor coefficients a[]
*-----------------------------------------------------------------------------
*/
static void lsp_az(
FLOAT *lsp, /* input : lsp[0:M-1] */
FLOAT *a /* output: predictor coeffs a[0:M], a[0] = 1. */
)
{
FLOAT f1[NC+1], f2[NC+1];
int i,j;
get_lsp_pol(&lsp[0],f1);
get_lsp_pol(&lsp[1],f2);
for (i = NC; i > 0; i--)
{
f1[i] += f1[i-1];
f2[i] -= f2[i-1];
}
a[0] = (F)1.0;
for (i = 1, j = M; i <= NC; i++, j--)
{
a[i] = (F)0.5*(f1[i] + f2[i]);
a[j] = (F)0.5*(f1[i] - f2[i]);
}
return;
}
/*----------------------------------------------------------------------------
* get_lsp_pol - find the polynomial F1(z) or F2(z) from the LSFs
*----------------------------------------------------------------------------
*/
static void get_lsp_pol(
FLOAT lsp[], /* input : line spectral freq. (cosine domain) */
FLOAT f[] /* output: the coefficients of F1 or F2 */
)
{
FLOAT b;
int i,j;
f[0] = (F)1.0;
b = (F)-2.0*lsp[0];
f[1] = b;
for (i = 2; i <= NC; i++)
{
b = (F)-2.0*lsp[2*i-2];
f[i] = b*f[i-1] + (F)2.0*f[i-2];
for (j = i-1; j > 1; j--)
f[j] += b*f[j-1] + f[j-2];
f[1] += b;
}
return;
}
/*----------------------------------------------------------------------------
* lsf_lsp - convert from lsf[0..M-1 to lsp[0..M-1]
*----------------------------------------------------------------------------
*/
void lsf_lsp(
FLOAT lsf[], /* input : lsf */
FLOAT lsp[M], /* output: lsp */
int m
)
{
int i;
for ( i = 0; i < m; i++ )
lsp[i] = (FLOAT)cos((double)lsf[i]);
return;
}
/*----------------------------------------------------------------------------
* lsp_lsf - convert from lsp[0..M-1 to lsf[0..M-1]
*----------------------------------------------------------------------------
*/
void lsp_lsf(
FLOAT lsp[], /* input : lsp coefficients */
FLOAT lsf[], /* output: lsf (normalized frequencies */
int m
)
{
int i;
for ( i = 0; i < m; i++ )
lsf[i] = (FLOAT)acos((double)lsp[i]);
return;
}
/*---------------------------------------------------------------------------
* weigh_az: Weighting of LPC coefficients ap[i] = a[i] * (gamma ** i)
*---------------------------------------------------------------------------
*/
void weight_az(
FLOAT *a, /* input : lpc coefficients a[0:m] */
FLOAT gamma, /* input : weighting factor */
int m, /* input : filter order */
FLOAT *ap /* output: weighted coefficients ap[0:m] */
)
{
FLOAT fac;
int i;
ap[0] = a[0];
fac = gamma;
for (i = 1; i