1e2e838afcf03e603a41a0455846eaf9614537c16Mans Rullgard/*
2e2e838afcf03e603a41a0455846eaf9614537c16Mans Rullgard ** Copyright 2003-2010, VisualOn, Inc.
3e2e838afcf03e603a41a0455846eaf9614537c16Mans Rullgard **
4e2e838afcf03e603a41a0455846eaf9614537c16Mans Rullgard ** Licensed under the Apache License, Version 2.0 (the "License");
5e2e838afcf03e603a41a0455846eaf9614537c16Mans Rullgard ** you may not use this file except in compliance with the License.
6e2e838afcf03e603a41a0455846eaf9614537c16Mans Rullgard ** You may obtain a copy of the License at
7e2e838afcf03e603a41a0455846eaf9614537c16Mans Rullgard **
8e2e838afcf03e603a41a0455846eaf9614537c16Mans Rullgard **     http://www.apache.org/licenses/LICENSE-2.0
9e2e838afcf03e603a41a0455846eaf9614537c16Mans Rullgard **
10e2e838afcf03e603a41a0455846eaf9614537c16Mans Rullgard ** Unless required by applicable law or agreed to in writing, software
11e2e838afcf03e603a41a0455846eaf9614537c16Mans Rullgard ** distributed under the License is distributed on an "AS IS" BASIS,
12e2e838afcf03e603a41a0455846eaf9614537c16Mans Rullgard ** WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
13e2e838afcf03e603a41a0455846eaf9614537c16Mans Rullgard ** See the License for the specific language governing permissions and
14e2e838afcf03e603a41a0455846eaf9614537c16Mans Rullgard ** limitations under the License.
15e2e838afcf03e603a41a0455846eaf9614537c16Mans Rullgard */
16e2e838afcf03e603a41a0455846eaf9614537c16Mans Rullgard
17e2e838afcf03e603a41a0455846eaf9614537c16Mans Rullgard/***********************************************************************
18e2e838afcf03e603a41a0455846eaf9614537c16Mans Rullgard*      File: hp400.c                                                    *
19e2e838afcf03e603a41a0455846eaf9614537c16Mans Rullgard*                                                                       *
20e2e838afcf03e603a41a0455846eaf9614537c16Mans Rullgard*      Description:                                                     *
21e2e838afcf03e603a41a0455846eaf9614537c16Mans Rullgard* 2nd order high pass filter with cut off frequency at 400 Hz.          *
22e2e838afcf03e603a41a0455846eaf9614537c16Mans Rullgard* Designed with cheby2 function in MATLAB.                              *
23e2e838afcf03e603a41a0455846eaf9614537c16Mans Rullgard* Optimized for fixed-point to get the following frequency response:    *
24e2e838afcf03e603a41a0455846eaf9614537c16Mans Rullgard*                                                                       *
25e2e838afcf03e603a41a0455846eaf9614537c16Mans Rullgard*  frequency:     0Hz   100Hz  200Hz  300Hz  400Hz  630Hz  1.5kHz  3kHz *
26e2e838afcf03e603a41a0455846eaf9614537c16Mans Rullgard*  dB loss:     -infdB  -30dB  -20dB  -10dB  -3dB   +6dB    +1dB    0dB *
27e2e838afcf03e603a41a0455846eaf9614537c16Mans Rullgard*                                                                       *
28e2e838afcf03e603a41a0455846eaf9614537c16Mans Rullgard* Algorithm:                                                            *
29e2e838afcf03e603a41a0455846eaf9614537c16Mans Rullgard*                                                                       *
30e2e838afcf03e603a41a0455846eaf9614537c16Mans Rullgard*  y[i] = b[0]*x[i] + b[1]*x[i-1] + b[2]*x[i-2]                         *
31e2e838afcf03e603a41a0455846eaf9614537c16Mans Rullgard*                   + a[1]*y[i-1] + a[2]*y[i-2];                        *
32e2e838afcf03e603a41a0455846eaf9614537c16Mans Rullgard*                                                                       *
33e2e838afcf03e603a41a0455846eaf9614537c16Mans Rullgard*  Word16 b[3] = {3660, -7320,  3660};       in Q12                     *
34e2e838afcf03e603a41a0455846eaf9614537c16Mans Rullgard*  Word16 a[3] = {4096,  7320, -3540};       in Q12                     *
35e2e838afcf03e603a41a0455846eaf9614537c16Mans Rullgard*                                                                       *
36e2e838afcf03e603a41a0455846eaf9614537c16Mans Rullgard*  float -->   b[3] = {0.893554687, -1.787109375,  0.893554687};        *
37e2e838afcf03e603a41a0455846eaf9614537c16Mans Rullgard*              a[3] = {1.000000000,  1.787109375, -0.864257812};        *
38e2e838afcf03e603a41a0455846eaf9614537c16Mans Rullgard*                                                                       *
39e2e838afcf03e603a41a0455846eaf9614537c16Mans Rullgard************************************************************************/
40e2e838afcf03e603a41a0455846eaf9614537c16Mans Rullgard
41e2e838afcf03e603a41a0455846eaf9614537c16Mans Rullgard#include "typedef.h"
42e2e838afcf03e603a41a0455846eaf9614537c16Mans Rullgard#include "basic_op.h"
43e2e838afcf03e603a41a0455846eaf9614537c16Mans Rullgard#include "oper_32b.h"
44e2e838afcf03e603a41a0455846eaf9614537c16Mans Rullgard#include "acelp.h"
45e2e838afcf03e603a41a0455846eaf9614537c16Mans Rullgard
46e2e838afcf03e603a41a0455846eaf9614537c16Mans Rullgard/* filter coefficients  */
47e2e838afcf03e603a41a0455846eaf9614537c16Mans Rullgardstatic Word16 b[3] = {915, -1830, 915};         /* Q12 (/4) */
48e2e838afcf03e603a41a0455846eaf9614537c16Mans Rullgardstatic Word16 a[3] = {16384, 29280, -14160};    /* Q12 (x4) */
49e2e838afcf03e603a41a0455846eaf9614537c16Mans Rullgard/* Initialization of static values */
50e2e838afcf03e603a41a0455846eaf9614537c16Mans Rullgard
51e2e838afcf03e603a41a0455846eaf9614537c16Mans Rullgardvoid Init_HP400_12k8(Word16 mem[])
52e2e838afcf03e603a41a0455846eaf9614537c16Mans Rullgard{
53e2e838afcf03e603a41a0455846eaf9614537c16Mans Rullgard	Set_zero(mem, 6);
54e2e838afcf03e603a41a0455846eaf9614537c16Mans Rullgard}
55e2e838afcf03e603a41a0455846eaf9614537c16Mans Rullgard
56e2e838afcf03e603a41a0455846eaf9614537c16Mans Rullgard
57e2e838afcf03e603a41a0455846eaf9614537c16Mans Rullgardvoid HP400_12k8(
58e2e838afcf03e603a41a0455846eaf9614537c16Mans Rullgard		Word16 signal[],                      /* input signal / output is divided by 16 */
59e2e838afcf03e603a41a0455846eaf9614537c16Mans Rullgard		Word16 lg,                            /* lenght of signal    */
60e2e838afcf03e603a41a0455846eaf9614537c16Mans Rullgard		Word16 mem[]                          /* filter memory [6]   */
61e2e838afcf03e603a41a0455846eaf9614537c16Mans Rullgard	       )
62e2e838afcf03e603a41a0455846eaf9614537c16Mans Rullgard{
63e2e838afcf03e603a41a0455846eaf9614537c16Mans Rullgard	Word16  x2;
64e2e838afcf03e603a41a0455846eaf9614537c16Mans Rullgard	Word16 y2_hi, y2_lo, y1_hi, y1_lo, x0, x1;
65e2e838afcf03e603a41a0455846eaf9614537c16Mans Rullgard	Word32 L_tmp;
66e2e838afcf03e603a41a0455846eaf9614537c16Mans Rullgard	Word32 num;
67e2e838afcf03e603a41a0455846eaf9614537c16Mans Rullgard	y2_hi = *mem++;
68e2e838afcf03e603a41a0455846eaf9614537c16Mans Rullgard	y2_lo = *mem++;
69e2e838afcf03e603a41a0455846eaf9614537c16Mans Rullgard	y1_hi = *mem++;
70e2e838afcf03e603a41a0455846eaf9614537c16Mans Rullgard	y1_lo = *mem++;
71b676a05348e4c516fa8b57e33b10548e6142c3f8Mans Rullgard	x0 = *mem++;
72b676a05348e4c516fa8b57e33b10548e6142c3f8Mans Rullgard	x1 = *mem;
73e2e838afcf03e603a41a0455846eaf9614537c16Mans Rullgard	num = (Word32)lg;
74e2e838afcf03e603a41a0455846eaf9614537c16Mans Rullgard	do
75e2e838afcf03e603a41a0455846eaf9614537c16Mans Rullgard	{
76e2e838afcf03e603a41a0455846eaf9614537c16Mans Rullgard		x2 = x1;
77e2e838afcf03e603a41a0455846eaf9614537c16Mans Rullgard		x1 = x0;
78e2e838afcf03e603a41a0455846eaf9614537c16Mans Rullgard		x0 = *signal;
79e2e838afcf03e603a41a0455846eaf9614537c16Mans Rullgard		/* y[i] = b[0]*x[i] + b[1]*x[i-1] + b140[2]*x[i-2]  */
80e2e838afcf03e603a41a0455846eaf9614537c16Mans Rullgard		/* + a[1]*y[i-1] + a[2] * y[i-2];  */
81e2e838afcf03e603a41a0455846eaf9614537c16Mans Rullgard		L_tmp = 8192L;                    /* rounding to maximise precision */
82e2e838afcf03e603a41a0455846eaf9614537c16Mans Rullgard		L_tmp += y1_lo * a[1];
83e2e838afcf03e603a41a0455846eaf9614537c16Mans Rullgard		L_tmp += y2_lo * a[2];
84e2e838afcf03e603a41a0455846eaf9614537c16Mans Rullgard		L_tmp = L_tmp >> 14;
85e2e838afcf03e603a41a0455846eaf9614537c16Mans Rullgard		L_tmp += (y1_hi * a[1] + y2_hi * a[2] + (x0 + x2)* b[0] + x1 * b[1]) << 1;
86e2e838afcf03e603a41a0455846eaf9614537c16Mans Rullgard		L_tmp <<= 1;           /* coeff Q12 --> Q13 */
87e2e838afcf03e603a41a0455846eaf9614537c16Mans Rullgard		y2_hi = y1_hi;
88e2e838afcf03e603a41a0455846eaf9614537c16Mans Rullgard		y2_lo = y1_lo;
89e2e838afcf03e603a41a0455846eaf9614537c16Mans Rullgard		y1_hi = (Word16)(L_tmp>>16);
90e2e838afcf03e603a41a0455846eaf9614537c16Mans Rullgard		y1_lo = (Word16)((L_tmp & 0xffff)>>1);
91e2e838afcf03e603a41a0455846eaf9614537c16Mans Rullgard
92e2e838afcf03e603a41a0455846eaf9614537c16Mans Rullgard		/* signal is divided by 16 to avoid overflow in energy computation */
93e2e838afcf03e603a41a0455846eaf9614537c16Mans Rullgard		*signal++ = (L_tmp + 0x8000) >> 16;
94e2e838afcf03e603a41a0455846eaf9614537c16Mans Rullgard	}while(--num !=0);
95e2e838afcf03e603a41a0455846eaf9614537c16Mans Rullgard
96e2e838afcf03e603a41a0455846eaf9614537c16Mans Rullgard	*mem-- = x1;
97e2e838afcf03e603a41a0455846eaf9614537c16Mans Rullgard	*mem-- = x0;
98e2e838afcf03e603a41a0455846eaf9614537c16Mans Rullgard	*mem-- = y1_lo;
99e2e838afcf03e603a41a0455846eaf9614537c16Mans Rullgard	*mem-- = y1_hi;
100e2e838afcf03e603a41a0455846eaf9614537c16Mans Rullgard	*mem-- = y2_lo;
101b676a05348e4c516fa8b57e33b10548e6142c3f8Mans Rullgard	*mem   = y2_hi;
102e2e838afcf03e603a41a0455846eaf9614537c16Mans Rullgard	return;
103e2e838afcf03e603a41a0455846eaf9614537c16Mans Rullgard}
104e2e838afcf03e603a41a0455846eaf9614537c16Mans Rullgard
105e2e838afcf03e603a41a0455846eaf9614537c16Mans Rullgard
106e2e838afcf03e603a41a0455846eaf9614537c16Mans Rullgard
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