/* ** Copyright 2003-2010, VisualOn, Inc. ** ** Licensed under the Apache License, Version 2.0 (the "License"); ** you may not use this file except in compliance with the License. ** You may obtain a copy of the License at ** ** http://www.apache.org/licenses/LICENSE-2.0 ** ** Unless required by applicable law or agreed to in writing, software ** distributed under the License is distributed on an "AS IS" BASIS, ** WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. ** See the License for the specific language governing permissions and ** limitations under the License. */ /*********************************************************************** * File: az_isp.c * * Description: *-----------------------------------------------------------------------* * Compute the ISPs from the LPC coefficients (order=M) * *-----------------------------------------------------------------------* * * * The ISPs are the roots of the two polynomials F1(z) and F2(z) * * defined as * * F1(z) = A(z) + z^-m A(z^-1) * * and F2(z) = A(z) - z^-m A(z^-1) * * * * For a even order m=2n, F1(z) has M/2 conjugate roots on the unit * * circle and F2(z) has M/2-1 conjugate roots on the unit circle in * * addition to two roots at 0 and pi. * * * * For a 16th order LP analysis, F1(z) and F2(z) can be written as * * * * F1(z) = (1 + a[M]) PRODUCT (1 - 2 cos(w_i) z^-1 + z^-2 ) * * i=0,2,4,6,8,10,12,14 * * * * F2(z) = (1 - a[M]) (1 - z^-2) PRODUCT (1 - 2 cos(w_i) z^-1 + z^-2 ) * * i=1,3,5,7,9,11,13 * * * * The ISPs are the M-1 frequencies w_i, i=0...M-2 plus the last * * predictor coefficient a[M]. * *-----------------------------------------------------------------------* ************************************************************************/ #include "typedef.h" #include "basic_op.h" #include "oper_32b.h" #include "stdio.h" #include "grid100.tab" #define M 16 #define NC (M/2) /* local function */ static __inline Word16 Chebps2(Word16 x, Word16 f[], Word32 n); void Az_isp( Word16 a[], /* (i) Q12 : predictor coefficients */ Word16 isp[], /* (o) Q15 : Immittance spectral pairs */ Word16 old_isp[] /* (i) : old isp[] (in case not found M roots) */ ) { Word32 i, j, nf, ip, order; Word16 xlow, ylow, xhigh, yhigh, xmid, ymid, xint; Word16 x, y, sign, exp; Word16 *coef; Word16 f1[NC + 1], f2[NC]; Word32 t0; /*-------------------------------------------------------------* * find the sum and diff polynomials F1(z) and F2(z) * * F1(z) = [A(z) + z^M A(z^-1)] * * F2(z) = [A(z) - z^M A(z^-1)]/(1-z^-2) * * * * for (i=0; i> 1) + (xhigh >> 1); /* xmid = (xlow + xhigh)/2 */ ymid = Chebps2(xmid, coef, order); if ((ylow * ymid) <= (Word32) 0) { yhigh = ymid; xhigh = xmid; } else { ylow = ymid; xlow = xmid; } } /*-------------------------------------------------------------* * Linear interpolation * * xint = xlow - ylow*(xhigh-xlow)/(yhigh-ylow); * *-------------------------------------------------------------*/ x = xhigh - xlow; y = yhigh - ylow; if (y == 0) { xint = xlow; } else { sign = y; y = abs_s(y); exp = norm_s(y); y = y << exp; y = div_s((Word16) 16383, y); t0 = x * y; t0 = (t0 >> (19 - exp)); y = vo_extract_l(t0); /* y= (xhigh-xlow)/(yhigh-ylow) in Q11 */ if (sign < 0) y = -y; t0 = ylow * y; /* result in Q26 */ t0 = (t0 >> 10); /* result in Q15 */ xint = vo_sub(xlow, vo_extract_l(t0)); /* xint = xlow - ylow*y */ } isp[nf] = xint; xlow = xint; nf++; if (ip == 0) { ip = 1; coef = f2; order = NC - 1; } else { ip = 0; coef = f1; order = NC; } ylow = Chebps2(xlow, coef, order); } } /* Check if M-1 roots found */ if(nf < M - 1) { for (i = 0; i < M; i++) { isp[i] = old_isp[i]; } } else { isp[M - 1] = a[M] << 3; /* From Q12 to Q15 with saturation */ } return; } /*--------------------------------------------------------------* * function Chebps2: * * ~~~~~~~ * * Evaluates the Chebishev polynomial series * *--------------------------------------------------------------* * * * The polynomial order is * * n = M/2 (M is the prediction order) * * The polynomial is given by * * C(x) = f(0)T_n(x) + f(1)T_n-1(x) + ... +f(n-1)T_1(x) + f(n)/2 * * Arguments: * * x: input value of evaluation; x = cos(frequency) in Q15 * * f[]: coefficients of the pol. in Q11 * * n: order of the pol. * * * * The value of C(x) is returned. (Satured to +-1.99 in Q14) * * * *--------------------------------------------------------------*/ static __inline Word16 Chebps2(Word16 x, Word16 f[], Word32 n) { Word32 i, cheb; Word16 b0_h, b0_l, b1_h, b1_l, b2_h, b2_l; Word32 t0; /* Note: All computation are done in Q24. */ t0 = f[0] << 13; b2_h = t0 >> 16; b2_l = (t0 & 0xffff)>>1; t0 = ((b2_h * x)<<1) + (((b2_l * x)>>15)<<1); t0 <<= 1; t0 += (f[1] << 13); /* + f[1] in Q24 */ b1_h = t0 >> 16; b1_l = (t0 & 0xffff) >> 1; for (i = 2; i < n; i++) { t0 = ((b1_h * x)<<1) + (((b1_l * x)>>15)<<1); t0 += (b2_h * (-16384))<<1; t0 += (f[i] << 12); t0 <<= 1; t0 -= (b2_l << 1); /* t0 = 2.0*x*b1 - b2 + f[i]; */ b0_h = t0 >> 16; b0_l = (t0 & 0xffff) >> 1; b2_l = b1_l; /* b2 = b1; */ b2_h = b1_h; b1_l = b0_l; /* b1 = b0; */ b1_h = b0_h; } t0 = ((b1_h * x)<<1) + (((b1_l * x)>>15)<<1); t0 += (b2_h * (-32768))<<1; /* t0 = x*b1 - b2 */ t0 -= (b2_l << 1); t0 += (f[n] << 12); /* t0 = x*b1 - b2 + f[i]/2 */ t0 = L_shl2(t0, 6); /* Q24 to Q30 with saturation */ cheb = extract_h(t0); /* Result in Q14 */ if (cheb == -32768) { cheb = -32767; /* to avoid saturation in Az_isp */ } return (cheb); }