#include "sysdef.h"
#include "wbhal_f.h"

///////////////////////////////////////////////////////////////////////////////////////////////////
// Original Phy.h
//*****************************************************************************

/*****************************************************************************
; For MAXIM2825/6/7 Ver. 331 or more
; Edited by Tiger, Sep-17-2003
; revised by Ben, Sep-18-2003

0x00 0x000a2
0x01 0x21cc0
;0x02 0x13802
0x02 0x1383a

;channe1 01 ; 0x03 0x30142 ; 0x04 0x0b333;
;channe1 02 ;0x03 0x32141 ;0x04 0x08444;
;channe1 03 ;0x03 0x32143 ;0x04 0x0aeee;
;channe1 04 ;0x03 0x32142 ;0x04 0x0b333;
;channe1 05 ;0x03 0x31141 ;0x04 0x08444;
;channe1 06 ;
0x03 0x31143;
0x04 0x0aeee;
;channe1 07 ;0x03 0x31142 ;0x04 0x0b333;
;channe1 08 ;0x03 0x33141 ;0x04 0x08444;
;channe1 09 ;0x03 0x33143 ;0x04 0x0aeee;
;channe1 10 ;0x03 0x33142 ;0x04 0x0b333;
;channe1 11 ;0x03 0x30941 ;0x04 0x08444;
;channe1 12 ;0x03 0x30943 ;0x04 0x0aeee;
;channe1 13 ;0x03 0x30942 ;0x04 0x0b333;

0x05 0x28986
0x06 0x18008
0x07 0x38400
0x08 0x05100; 100 Hz DC
;0x08 0x05900; 30 KHz DC
0x09 0x24f08
0x0a 0x17e00, 0x17ea0
0x0b 0x37d80
0x0c 0x0c900 // 0x0ca00 (lager power 9db than 0x0c000), 0x0c000
*****************************************************************************/
// MAX2825 (pure b/g)
u32 max2825_rf_data[] =
{
    (0x00<<18)|0x000a2,
    (0x01<<18)|0x21cc0,
    (0x02<<18)|0x13806,
    (0x03<<18)|0x30142,
    (0x04<<18)|0x0b333,
    (0x05<<18)|0x289A6,
    (0x06<<18)|0x18008,
    (0x07<<18)|0x38000,
    (0x08<<18)|0x05100,
    (0x09<<18)|0x24f08,
    (0x0A<<18)|0x14000,
    (0x0B<<18)|0x37d80,
    (0x0C<<18)|0x0c100   // 11a: 0x0c300, 11g: 0x0c100
};

u32 max2825_channel_data_24[][3] =
{
    {(0x03<<18)|0x30142, (0x04<<18)|0x0b333, (0x05<<18)|0x289A6}, // channe1 01
    {(0x03<<18)|0x32141, (0x04<<18)|0x08444, (0x05<<18)|0x289A6}, // channe1 02
    {(0x03<<18)|0x32143, (0x04<<18)|0x0aeee, (0x05<<18)|0x289A6}, // channe1 03
    {(0x03<<18)|0x32142, (0x04<<18)|0x0b333, (0x05<<18)|0x289A6}, // channe1 04
    {(0x03<<18)|0x31141, (0x04<<18)|0x08444, (0x05<<18)|0x289A6}, // channe1 05
    {(0x03<<18)|0x31143, (0x04<<18)|0x0aeee, (0x05<<18)|0x289A6}, // channe1 06
    {(0x03<<18)|0x31142, (0x04<<18)|0x0b333, (0x05<<18)|0x289A6}, // channe1 07
    {(0x03<<18)|0x33141, (0x04<<18)|0x08444, (0x05<<18)|0x289A6}, // channe1 08
    {(0x03<<18)|0x33143, (0x04<<18)|0x0aeee, (0x05<<18)|0x289A6}, // channe1 09
    {(0x03<<18)|0x33142, (0x04<<18)|0x0b333, (0x05<<18)|0x289A6}, // channe1 10
    {(0x03<<18)|0x30941, (0x04<<18)|0x08444, (0x05<<18)|0x289A6}, // channe1 11
    {(0x03<<18)|0x30943, (0x04<<18)|0x0aeee, (0x05<<18)|0x289A6}, // channe1 12
    {(0x03<<18)|0x30942, (0x04<<18)|0x0b333, (0x05<<18)|0x289A6}, // channe1 13
    {(0x03<<18)|0x32941, (0x04<<18)|0x09999, (0x05<<18)|0x289A6} // 14 (2484MHz) hhmodify
};

u32 max2825_power_data_24[] = {(0x0C<<18)|0x0c000, (0x0C<<18)|0x0c100};

/****************************************************************************/
// MAX2827 (a/b/g)
u32 max2827_rf_data[] =
{
    (0x00<<18)|0x000a2,
    (0x01<<18)|0x21cc0,
    (0x02<<18)|0x13806,
    (0x03<<18)|0x30142,
    (0x04<<18)|0x0b333,
    (0x05<<18)|0x289A6,
    (0x06<<18)|0x18008,
    (0x07<<18)|0x38000,
    (0x08<<18)|0x05100,
    (0x09<<18)|0x24f08,
    (0x0A<<18)|0x14000,
    (0x0B<<18)|0x37d80,
    (0x0C<<18)|0x0c100   // 11a: 0x0c300, 11g: 0x0c100
};

u32 max2827_channel_data_24[][3] =
{
    {(0x03<<18)|0x30142, (0x04<<18)|0x0b333, (0x05<<18)|0x289A6}, // channe1 01
    {(0x03<<18)|0x32141, (0x04<<18)|0x08444, (0x05<<18)|0x289A6}, // channe1 02
    {(0x03<<18)|0x32143, (0x04<<18)|0x0aeee, (0x05<<18)|0x289A6}, // channe1 03
    {(0x03<<18)|0x32142, (0x04<<18)|0x0b333, (0x05<<18)|0x289A6}, // channe1 04
    {(0x03<<18)|0x31141, (0x04<<18)|0x08444, (0x05<<18)|0x289A6}, // channe1 05
    {(0x03<<18)|0x31143, (0x04<<18)|0x0aeee, (0x05<<18)|0x289A6}, // channe1 06
    {(0x03<<18)|0x31142, (0x04<<18)|0x0b333, (0x05<<18)|0x289A6}, // channe1 07
    {(0x03<<18)|0x33141, (0x04<<18)|0x08444, (0x05<<18)|0x289A6}, // channe1 08
    {(0x03<<18)|0x33143, (0x04<<18)|0x0aeee, (0x05<<18)|0x289A6}, // channe1 09
    {(0x03<<18)|0x33142, (0x04<<18)|0x0b333, (0x05<<18)|0x289A6}, // channe1 10
    {(0x03<<18)|0x30941, (0x04<<18)|0x08444, (0x05<<18)|0x289A6}, // channe1 11
    {(0x03<<18)|0x30943, (0x04<<18)|0x0aeee, (0x05<<18)|0x289A6}, // channe1 12
    {(0x03<<18)|0x30942, (0x04<<18)|0x0b333, (0x05<<18)|0x289A6}, // channe1 13
    {(0x03<<18)|0x32941, (0x04<<18)|0x09999, (0x05<<18)|0x289A6}  // 14 (2484MHz) hhmodify
};

u32 max2827_channel_data_50[][3] =
{
    {(0x03<<18)|0x33cc3, (0x04<<18)|0x08ccc, (0x05<<18)|0x2A9A6}, // channel 36
    {(0x03<<18)|0x302c0, (0x04<<18)|0x08000, (0x05<<18)|0x2A9A6}, // channel 40
    {(0x03<<18)|0x302c2, (0x04<<18)|0x0b333, (0x05<<18)|0x2A9A6}, // channel 44
    {(0x03<<18)|0x322c1, (0x04<<18)|0x09999, (0x05<<18)|0x2A9A6}, // channel 48
    {(0x03<<18)|0x312c1, (0x04<<18)|0x0a666, (0x05<<18)|0x2A9A6}, // channel 52
    {(0x03<<18)|0x332c3, (0x04<<18)|0x08ccc, (0x05<<18)|0x2A9A6}, // channel 56
    {(0x03<<18)|0x30ac0, (0x04<<18)|0x08000, (0x05<<18)|0x2A9A6}, // channel 60
    {(0x03<<18)|0x30ac2, (0x04<<18)|0x0b333, (0x05<<18)|0x2A9A6} // channel 64
};

u32 max2827_power_data_24[] = {(0x0C<<18)|0x0C000, (0x0C<<18)|0x0D600, (0x0C<<18)|0x0C100};
u32 max2827_power_data_50[] = {(0x0C<<18)|0x0C400, (0x0C<<18)|0x0D500, (0x0C<<18)|0x0C300};

/****************************************************************************/
// MAX2828 (a/b/g)
u32 max2828_rf_data[] =
{
    (0x00<<18)|0x000a2,
    (0x01<<18)|0x21cc0,
    (0x02<<18)|0x13806,
    (0x03<<18)|0x30142,
    (0x04<<18)|0x0b333,
    (0x05<<18)|0x289A6,
    (0x06<<18)|0x18008,
    (0x07<<18)|0x38000,
    (0x08<<18)|0x05100,
    (0x09<<18)|0x24f08,
    (0x0A<<18)|0x14000,
    (0x0B<<18)|0x37d80,
    (0x0C<<18)|0x0c100   // 11a: 0x0c300, 11g: 0x0c100
};

u32 max2828_channel_data_24[][3] =
{
    {(0x03<<18)|0x30142, (0x04<<18)|0x0b333, (0x05<<18)|0x289A6}, // channe1 01
    {(0x03<<18)|0x32141, (0x04<<18)|0x08444, (0x05<<18)|0x289A6}, // channe1 02
    {(0x03<<18)|0x32143, (0x04<<18)|0x0aeee, (0x05<<18)|0x289A6}, // channe1 03
    {(0x03<<18)|0x32142, (0x04<<18)|0x0b333, (0x05<<18)|0x289A6}, // channe1 04
    {(0x03<<18)|0x31141, (0x04<<18)|0x08444, (0x05<<18)|0x289A6}, // channe1 05
    {(0x03<<18)|0x31143, (0x04<<18)|0x0aeee, (0x05<<18)|0x289A6}, // channe1 06
    {(0x03<<18)|0x31142, (0x04<<18)|0x0b333, (0x05<<18)|0x289A6}, // channe1 07
    {(0x03<<18)|0x33141, (0x04<<18)|0x08444, (0x05<<18)|0x289A6}, // channe1 08
    {(0x03<<18)|0x33143, (0x04<<18)|0x0aeee, (0x05<<18)|0x289A6}, // channe1 09
    {(0x03<<18)|0x33142, (0x04<<18)|0x0b333, (0x05<<18)|0x289A6}, // channe1 10
    {(0x03<<18)|0x30941, (0x04<<18)|0x08444, (0x05<<18)|0x289A6}, // channe1 11
    {(0x03<<18)|0x30943, (0x04<<18)|0x0aeee, (0x05<<18)|0x289A6}, // channe1 12
    {(0x03<<18)|0x30942, (0x04<<18)|0x0b333, (0x05<<18)|0x289A6}, // channe1 13
    {(0x03<<18)|0x32941, (0x04<<18)|0x09999, (0x05<<18)|0x289A6}  // 14 (2484MHz) hhmodify
};

u32 max2828_channel_data_50[][3] =
{
    {(0x03<<18)|0x33cc3, (0x04<<18)|0x08ccc, (0x05<<18)|0x289A6}, // channel 36
    {(0x03<<18)|0x302c0, (0x04<<18)|0x08000, (0x05<<18)|0x289A6}, // channel 40
    {(0x03<<18)|0x302c2, (0x04<<18)|0x0b333, (0x05<<18)|0x289A6}, // channel 44
    {(0x03<<18)|0x322c1, (0x04<<18)|0x09999, (0x05<<18)|0x289A6}, // channel 48
    {(0x03<<18)|0x312c1, (0x04<<18)|0x0a666, (0x05<<18)|0x289A6}, // channel 52
    {(0x03<<18)|0x332c3, (0x04<<18)|0x08ccc, (0x05<<18)|0x289A6}, // channel 56
    {(0x03<<18)|0x30ac0, (0x04<<18)|0x08000, (0x05<<18)|0x289A6}, // channel 60
    {(0x03<<18)|0x30ac2, (0x04<<18)|0x0b333, (0x05<<18)|0x289A6} // channel 64
};

u32 max2828_power_data_24[] = {(0x0C<<18)|0x0c000, (0x0C<<18)|0x0c100};
u32 max2828_power_data_50[] = {(0x0C<<18)|0x0c000, (0x0C<<18)|0x0c100};

/****************************************************************************/
// LA20040728 kevin
// MAX2829 (a/b/g)
u32 max2829_rf_data[] =
{
    (0x00<<18)|0x000a2,
    (0x01<<18)|0x23520,
    (0x02<<18)|0x13802,
    (0x03<<18)|0x30142,
    (0x04<<18)|0x0b333,
    (0x05<<18)|0x28906,
    (0x06<<18)|0x18008,
    (0x07<<18)|0x3B500,
    (0x08<<18)|0x05100,
    (0x09<<18)|0x24f08,
    (0x0A<<18)|0x14000,
    (0x0B<<18)|0x37d80,
    (0x0C<<18)|0x0F300 //TXVGA=51, (MAX-6 dB)
};

u32 max2829_channel_data_24[][3] =
{
    {(3<<18)|0x30142, (4<<18)|0x0b333, (5<<18)|0x289C6},  // 01 (2412MHz)
    {(3<<18)|0x32141, (4<<18)|0x08444, (5<<18)|0x289C6},  // 02 (2417MHz)
    {(3<<18)|0x32143, (4<<18)|0x0aeee, (5<<18)|0x289C6},  // 03 (2422MHz)
    {(3<<18)|0x32142, (4<<18)|0x0b333, (5<<18)|0x289C6},  // 04 (2427MHz)
    {(3<<18)|0x31141, (4<<18)|0x08444, (5<<18)|0x289C6},  // 05 (2432MHz)
    {(3<<18)|0x31143, (4<<18)|0x0aeee, (5<<18)|0x289C6},  // 06 (2437MHz)
    {(3<<18)|0x31142, (4<<18)|0x0b333, (5<<18)|0x289C6},  // 07 (2442MHz)
    {(3<<18)|0x33141, (4<<18)|0x08444, (5<<18)|0x289C6},  // 08 (2447MHz)
    {(3<<18)|0x33143, (4<<18)|0x0aeee, (5<<18)|0x289C6},  // 09 (2452MHz)
    {(3<<18)|0x33142, (4<<18)|0x0b333, (5<<18)|0x289C6},  // 10 (2457MHz)
    {(3<<18)|0x30941, (4<<18)|0x08444, (5<<18)|0x289C6},  // 11 (2462MHz)
    {(3<<18)|0x30943, (4<<18)|0x0aeee, (5<<18)|0x289C6},  // 12 (2467MHz)
    {(3<<18)|0x30942, (4<<18)|0x0b333, (5<<18)|0x289C6},  // 13 (2472MHz)
    {(3<<18)|0x32941, (4<<18)|0x09999, (5<<18)|0x289C6},  // 14 (2484MHz) hh-modify
};

u32 max2829_channel_data_50[][4] =
{
     {36, (3<<18)|0x33cc3, (4<<18)|0x08ccc, (5<<18)|0x2A946}, // 36 (5.180GHz)
     {40, (3<<18)|0x302c0, (4<<18)|0x08000, (5<<18)|0x2A946}, // 40 (5.200GHz)
     {44, (3<<18)|0x302c2, (4<<18)|0x0b333, (5<<18)|0x2A946}, // 44 (5.220GHz)
     {48, (3<<18)|0x322c1, (4<<18)|0x09999, (5<<18)|0x2A946}, // 48 (5.240GHz)
     {52, (3<<18)|0x312c1, (4<<18)|0x0a666, (5<<18)|0x2A946}, // 52 (5.260GHz)
     {56, (3<<18)|0x332c3, (4<<18)|0x08ccc, (5<<18)|0x2A946}, // 56 (5.280GHz)
     {60, (3<<18)|0x30ac0, (4<<18)|0x08000, (5<<18)|0x2A946}, // 60 (5.300GHz)
     {64, (3<<18)|0x30ac2, (4<<18)|0x0b333, (5<<18)|0x2A946}, // 64 (5.320GHz)

    {100, (3<<18)|0x30ec0, (4<<18)|0x08000, (5<<18)|0x2A9C6}, // 100 (5.500GHz)
    {104, (3<<18)|0x30ec2, (4<<18)|0x0b333, (5<<18)|0x2A9C6}, // 104 (5.520GHz)
    {108, (3<<18)|0x32ec1, (4<<18)|0x09999, (5<<18)|0x2A9C6}, // 108 (5.540GHz)
    {112, (3<<18)|0x31ec1, (4<<18)|0x0a666, (5<<18)|0x2A9C6}, // 112 (5.560GHz)
    {116, (3<<18)|0x33ec3, (4<<18)|0x08ccc, (5<<18)|0x2A9C6}, // 116 (5.580GHz)
    {120, (3<<18)|0x301c0, (4<<18)|0x08000, (5<<18)|0x2A9C6}, // 120 (5.600GHz)
    {124, (3<<18)|0x301c2, (4<<18)|0x0b333, (5<<18)|0x2A9C6}, // 124 (5.620GHz)
    {128, (3<<18)|0x321c1, (4<<18)|0x09999, (5<<18)|0x2A9C6}, // 128 (5.640GHz)
    {132, (3<<18)|0x311c1, (4<<18)|0x0a666, (5<<18)|0x2A9C6}, // 132 (5.660GHz)
    {136, (3<<18)|0x331c3, (4<<18)|0x08ccc, (5<<18)|0x2A9C6}, // 136 (5.680GHz)
    {140, (3<<18)|0x309c0, (4<<18)|0x08000, (5<<18)|0x2A9C6}, // 140 (5.700GHz)

    {149, (3<<18)|0x329c2, (4<<18)|0x0b333, (5<<18)|0x2A9C6}, // 149 (5.745GHz)
    {153, (3<<18)|0x319c1, (4<<18)|0x09999, (5<<18)|0x2A9C6}, // 153 (5.765GHz)
    {157, (3<<18)|0x339c1, (4<<18)|0x0a666, (5<<18)|0x2A9C6}, // 157 (5.785GHz)
    {161, (3<<18)|0x305c3, (4<<18)|0x08ccc, (5<<18)|0x2A9C6}, // 161 (5.805GHz)

    // Japan
    { 184, (3<<18)|0x308c2, (4<<18)|0x0b333, (5<<18)|0x2A946}, // 184 (4.920GHz)
    { 188, (3<<18)|0x328c1, (4<<18)|0x09999, (5<<18)|0x2A946}, // 188 (4.940GHz)
    { 192, (3<<18)|0x318c1, (4<<18)|0x0a666, (5<<18)|0x2A946}, // 192 (4.960GHz)
    { 196, (3<<18)|0x338c3, (4<<18)|0x08ccc, (5<<18)|0x2A946}, // 196 (4.980GHz)
    {   8, (3<<18)|0x324c1, (4<<18)|0x09999, (5<<18)|0x2A946}, //   8 (5.040GHz)
    {  12, (3<<18)|0x314c1, (4<<18)|0x0a666, (5<<18)|0x2A946}, //  12 (5.060GHz)
    {  16, (3<<18)|0x334c3, (4<<18)|0x08ccc, (5<<18)|0x2A946}, //  16 (5.080GHz)
    {  34, (3<<18)|0x31cc2, (4<<18)|0x0b333, (5<<18)|0x2A946}, //  34 (5.170GHz)
    {  38, (3<<18)|0x33cc1, (4<<18)|0x09999, (5<<18)|0x2A946}, //  38 (5.190GHz)
    {  42, (3<<18)|0x302c1, (4<<18)|0x0a666, (5<<18)|0x2A946}, //  42 (5.210GHz)
    {  46, (3<<18)|0x322c3, (4<<18)|0x08ccc, (5<<18)|0x2A946}, //  46 (5.230GHz)
};

/*****************************************************************************
; For MAXIM2825/6/7 Ver. 317 or less
; Edited by Tiger, Sep-17-2003  for 2.4Ghz channels
; Updated by Tiger, Sep-22-2003 for 5.0Ghz channels
; Corrected by Tiger, Sep-23-2003, for 0x03 and 0x04 of 5.0Ghz channels

0x00 0x00080
0x01 0x214c0
0x02 0x13802

;2.4GHz Channels
;channe1 01 (2.412GHz); 0x03 0x30143 ;0x04 0x0accc
;channe1 02 (2.417GHz); 0x03 0x32140 ;0x04 0x09111
;channe1 03 (2.422GHz); 0x03 0x32142 ;0x04 0x0bbbb
;channe1 04 (2.427GHz); 0x03 0x32143 ;0x04 0x0accc
;channe1 05 (2.432GHz); 0x03 0x31140 ;0x04 0x09111
;channe1 06 (2.437GHz); 0x03 0x31142 ;0x04 0x0bbbb
;channe1 07 (2.442GHz); 0x03 0x31143 ;0x04 0x0accc
;channe1 08 (2.447GHz); 0x03 0x33140 ;0x04 0x09111
;channe1 09 (2.452GHz); 0x03 0x33142 ;0x04 0x0bbbb
;channe1 10 (2.457GHz); 0x03 0x33143 ;0x04 0x0accc
;channe1 11 (2.462GHz); 0x03 0x30940 ;0x04 0x09111
;channe1 12 (2.467GHz); 0x03 0x30942 ;0x04 0x0bbbb
;channe1 13 (2.472GHz); 0x03 0x30943 ;0x04 0x0accc

;5.0Ghz Channels
;channel 36 (5.180GHz); 0x03 0x33cc0 ;0x04 0x0b333
;channel 40 (5.200GHz); 0x03 0x302c0 ;0x04 0x08000
;channel 44 (5.220GHz); 0x03 0x302c2 ;0x04 0x0b333
;channel 48 (5.240GHz); 0x03 0x322c1 ;0x04 0x09999
;channel 52 (5.260GHz); 0x03 0x312c1 ;0x04 0x0a666
;channel 56 (5.280GHz); 0x03 0x332c3 ;0x04 0x08ccc
;channel 60 (5.300GHz); 0x03 0x30ac0 ;0x04 0x08000
;channel 64 (5.320GHz); 0x03 0x30ac2 ;0x04 0x08333

;2.4GHz band ;0x05 0x28986;
;5.0GHz band
0x05 0x2a986

0x06 0x18008
0x07 0x38400
0x08 0x05108
0x09 0x27ff8
0x0a 0x14000
0x0b 0x37f99
0x0c 0x0c000
*****************************************************************************/
u32 maxim_317_rf_data[]     =
{
    (0x00<<18)|0x000a2,
    (0x01<<18)|0x214c0,
    (0x02<<18)|0x13802,
    (0x03<<18)|0x30143,
    (0x04<<18)|0x0accc,
    (0x05<<18)|0x28986,
    (0x06<<18)|0x18008,
    (0x07<<18)|0x38400,
    (0x08<<18)|0x05108,
    (0x09<<18)|0x27ff8,
    (0x0A<<18)|0x14000,
    (0x0B<<18)|0x37f99,
    (0x0C<<18)|0x0c000
};

u32 maxim_317_channel_data_24[][3]    =
{
    {(0x03<<18)|0x30143, (0x04<<18)|0x0accc, (0x05<<18)|0x28986}, // channe1 01
    {(0x03<<18)|0x32140, (0x04<<18)|0x09111, (0x05<<18)|0x28986}, // channe1 02
    {(0x03<<18)|0x32142, (0x04<<18)|0x0bbbb, (0x05<<18)|0x28986}, // channe1 03
    {(0x03<<18)|0x32143, (0x04<<18)|0x0accc, (0x05<<18)|0x28986}, // channe1 04
    {(0x03<<18)|0x31140, (0x04<<18)|0x09111, (0x05<<18)|0x28986}, // channe1 05
    {(0x03<<18)|0x31142, (0x04<<18)|0x0bbbb, (0x05<<18)|0x28986}, // channe1 06
    {(0x03<<18)|0x31143, (0x04<<18)|0x0accc, (0x05<<18)|0x28986}, // channe1 07
    {(0x03<<18)|0x33140, (0x04<<18)|0x09111, (0x05<<18)|0x28986}, // channe1 08
    {(0x03<<18)|0x33142, (0x04<<18)|0x0bbbb, (0x05<<18)|0x28986}, // channe1 09
    {(0x03<<18)|0x33143, (0x04<<18)|0x0accc, (0x05<<18)|0x28986}, // channe1 10
    {(0x03<<18)|0x30940, (0x04<<18)|0x09111, (0x05<<18)|0x28986}, // channe1 11
    {(0x03<<18)|0x30942, (0x04<<18)|0x0bbbb, (0x05<<18)|0x28986}, // channe1 12
    {(0x03<<18)|0x30943, (0x04<<18)|0x0accc, (0x05<<18)|0x28986} // channe1 13
};

u32 maxim_317_channel_data_50[][3]    =
{
    {(0x03<<18)|0x33cc0, (0x04<<18)|0x0b333, (0x05<<18)|0x2a986}, // channel 36
    {(0x03<<18)|0x302c0, (0x04<<18)|0x08000, (0x05<<18)|0x2a986}, // channel 40
    {(0x03<<18)|0x302c3, (0x04<<18)|0x0accc, (0x05<<18)|0x2a986}, // channel 44
    {(0x03<<18)|0x322c1, (0x04<<18)|0x09666, (0x05<<18)|0x2a986}, // channel 48
    {(0x03<<18)|0x312c2, (0x04<<18)|0x09999, (0x05<<18)|0x2a986}, // channel 52
    {(0x03<<18)|0x332c0, (0x04<<18)|0x0b333, (0x05<<18)|0x2a99e}, // channel 56
    {(0x03<<18)|0x30ac0, (0x04<<18)|0x08000, (0x05<<18)|0x2a99e}, // channel 60
    {(0x03<<18)|0x30ac3, (0x04<<18)|0x0accc, (0x05<<18)|0x2a99e} // channel 64
};

u32 maxim_317_power_data_24[] = {(0x0C<<18)|0x0c000, (0x0C<<18)|0x0c100};
u32 maxim_317_power_data_50[] = {(0x0C<<18)|0x0c000, (0x0C<<18)|0x0c100};

/*****************************************************************************
;;AL2230 MP (Mass Production Version)
;;RF Registers Setting for Airoha AL2230 silicon after June 1st, 2004
;;Updated by Tiger Huang (June 1st, 2004)
;;20-bit length and LSB first

;;Ch01 (2412MHz) ;0x00 0x09EFC ;0x01 0x8CCCC;
;;Ch02 (2417MHz) ;0x00 0x09EFC ;0x01 0x8CCCD;
;;Ch03 (2422MHz) ;0x00 0x09E7C ;0x01 0x8CCCC;
;;Ch04 (2427MHz) ;0x00 0x09E7C ;0x01 0x8CCCD;
;;Ch05 (2432MHz) ;0x00 0x05EFC ;0x01 0x8CCCC;
;;Ch06 (2437MHz) ;0x00 0x05EFC ;0x01 0x8CCCD;
;;Ch07 (2442MHz) ;0x00 0x05E7C ;0x01 0x8CCCC;
;;Ch08 (2447MHz) ;0x00 0x05E7C ;0x01 0x8CCCD;
;;Ch09 (2452MHz) ;0x00 0x0DEFC ;0x01 0x8CCCC;
;;Ch10 (2457MHz) ;0x00 0x0DEFC ;0x01 0x8CCCD;
;;Ch11 (2462MHz) ;0x00 0x0DE7C ;0x01 0x8CCCC;
;;Ch12 (2467MHz) ;0x00 0x0DE7C ;0x01 0x8CCCD;
;;Ch13 (2472MHz) ;0x00 0x03EFC ;0x01 0x8CCCC;
;;Ch14 (2484Mhz) ;0x00 0x03E7C ;0x01 0x86666;

0x02 0x401D8; RXDCOC BW 100Hz for RXHP low
;;0x02 0x481DC; RXDCOC BW 30Khz for RXHP low

0x03 0xCFFF0
0x04 0x23800
0x05 0xA3B72
0x06 0x6DA01
0x07 0xE1688
0x08 0x11600
0x09 0x99E02
0x0A 0x5DDB0
0x0B 0xD9900
0x0C 0x3FFBD
0x0D 0xB0000
0x0F 0xF00A0

;RF Calibration for Airoha AL2230
;Edit by Ben Chang (01/30/04)
;Updated by Tiger Huang (03/03/04)
0x0f 0xf00a0 ; Initial Setting
0x0f 0xf00b0 ; Activate TX DCC
0x0f 0xf02a0 ; Activate Phase Calibration
0x0f 0xf00e0 ; Activate Filter RC Calibration
0x0f 0xf00a0 ; Restore Initial Setting
*****************************************************************************/

u32 al2230_rf_data[]     =
{
    (0x00<<20)|0x09EFC,
    (0x01<<20)|0x8CCCC,
    (0x02<<20)|0x40058,// 20060627 Anson 0x401D8,
    (0x03<<20)|0xCFFF0,
    (0x04<<20)|0x24100,// 20060627 Anson 0x23800,
    (0x05<<20)|0xA3B2F,// 20060627 Anson 0xA3B72
    (0x06<<20)|0x6DA01,
    (0x07<<20)|0xE3628,// 20060627 Anson 0xE1688,
    (0x08<<20)|0x11600,
    (0x09<<20)|0x9DC02,// 20060627 Anosn 0x97602,//0x99E02, //0x9AE02
    (0x0A<<20)|0x5ddb0, // 941206 For QCOM interference 0x588b0,//0x5DDB0, 940601 adj 0x5aa30 for bluetooth
    (0x0B<<20)|0xD9900,
    (0x0C<<20)|0x3FFBD,
    (0x0D<<20)|0xB0000,
    (0x0F<<20)|0xF01A0 // 20060627 Anson 0xF00A0
};

u32 al2230s_rf_data[]     =
{
    (0x00<<20)|0x09EFC,
    (0x01<<20)|0x8CCCC,
    (0x02<<20)|0x40058,// 20060419 0x401D8,
    (0x03<<20)|0xCFFF0,
    (0x04<<20)|0x24100,// 20060419 0x23800,
    (0x05<<20)|0xA3B2F,// 20060419 0xA3B72,
    (0x06<<20)|0x6DA01,
    (0x07<<20)|0xE3628,// 20060419 0xE1688,
    (0x08<<20)|0x11600,
    (0x09<<20)|0x9DC02,// 20060419 0x97602,//0x99E02, //0x9AE02
    (0x0A<<20)|0x5DDB0,// 941206 For QCOM interference 0x588b0,//0x5DDB0, 940601 adj 0x5aa30 for bluetooth
    (0x0B<<20)|0xD9900,
    (0x0C<<20)|0x3FFBD,
    (0x0D<<20)|0xB0000,
    (0x0F<<20)|0xF01A0 // 20060419 0xF00A0
};

u32 al2230_channel_data_24[][2] =
{
    {(0x00<<20)|0x09EFC, (0x01<<20)|0x8CCCC}, // channe1 01
    {(0x00<<20)|0x09EFC, (0x01<<20)|0x8CCCD}, // channe1 02
    {(0x00<<20)|0x09E7C, (0x01<<20)|0x8CCCC}, // channe1 03
    {(0x00<<20)|0x09E7C, (0x01<<20)|0x8CCCD}, // channe1 04
    {(0x00<<20)|0x05EFC, (0x01<<20)|0x8CCCC}, // channe1 05
    {(0x00<<20)|0x05EFC, (0x01<<20)|0x8CCCD}, // channe1 06
    {(0x00<<20)|0x05E7C, (0x01<<20)|0x8CCCC}, // channe1 07
    {(0x00<<20)|0x05E7C, (0x01<<20)|0x8CCCD}, // channe1 08
    {(0x00<<20)|0x0DEFC, (0x01<<20)|0x8CCCC}, // channe1 09
    {(0x00<<20)|0x0DEFC, (0x01<<20)|0x8CCCD}, // channe1 10
    {(0x00<<20)|0x0DE7C, (0x01<<20)|0x8CCCC}, // channe1 11
    {(0x00<<20)|0x0DE7C, (0x01<<20)|0x8CCCD}, // channe1 12
    {(0x00<<20)|0x03EFC, (0x01<<20)|0x8CCCC}, // channe1 13
    {(0x00<<20)|0x03E7C, (0x01<<20)|0x86666} // channe1 14
};

// Current setting. u32 airoha_power_data_24[] = {(0x09<<20)|0x90202, (0x09<<20)|0x96602, (0x09<<20)|0x97602};
#define AIROHA_TXVGA_LOW_INDEX		31		// Index for 0x90202
#define AIROHA_TXVGA_MIDDLE_INDEX	12		// Index for 0x96602
#define AIROHA_TXVGA_HIGH_INDEX		8		// Index for 0x97602 1.0.24.0 1.0.28.0
/*
u32 airoha_power_data_24[] =
{
    0x9FE02,          // Max - 0 dB
    0x9BE02,          // Max - 1 dB
    0x9DE02,          // Max - 2 dB
    0x99E02,          // Max - 3 dB
    0x9EE02,          // Max - 4 dB
    0x9AE02,          // Max - 5 dB
    0x9CE02,          // Max - 6 dB
    0x98E02,          // Max - 7 dB
    0x97602,          // Max - 8 dB
    0x93602,          // Max - 9 dB
    0x95602,          // Max - 10 dB
    0x91602,          // Max - 11 dB
    0x96602,          // Max - 12 dB
    0x92602,          // Max - 13 dB
    0x94602,          // Max - 14 dB
    0x90602,          // Max - 15 dB
    0x97A02,          // Max - 16 dB
    0x93A02,          // Max - 17 dB
    0x95A02,          // Max - 18 dB
    0x91A02,          // Max - 19 dB
    0x96A02,          // Max - 20 dB
    0x92A02,          // Max - 21 dB
    0x94A02,          // Max - 22 dB
    0x90A02,          // Max - 23 dB
    0x97202,          // Max - 24 dB
    0x93202,          // Max - 25 dB
    0x95202,          // Max - 26 dB
    0x91202,          // Max - 27 dB
    0x96202,          // Max - 28 dB
    0x92202,          // Max - 29 dB
    0x94202,          // Max - 30 dB
    0x90202           // Max - 31 dB
};
*/

// 20040927 1.1.69.1000 ybjiang
// from John
u32 al2230_txvga_data[][2] =
{
	//value	, index
	{0x090202, 0},
	{0x094202, 2},
	{0x092202, 4},
	{0x096202, 6},
	{0x091202, 8},
	{0x095202, 10},
	{0x093202, 12},
	{0x097202, 14},
	{0x090A02, 16},
	{0x094A02, 18},
	{0x092A02, 20},
	{0x096A02, 22},
	{0x091A02, 24},
	{0x095A02, 26},
	{0x093A02, 28},
	{0x097A02, 30},
	{0x090602, 32},
	{0x094602, 34},
	{0x092602, 36},
	{0x096602, 38},
	{0x091602, 40},
	{0x095602, 42},
	{0x093602, 44},
	{0x097602, 46},
	{0x090E02, 48},
	{0x098E02, 49},
	{0x094E02, 50},
	{0x09CE02, 51},
	{0x092E02, 52},
	{0x09AE02, 53},
	{0x096E02, 54},
	{0x09EE02, 55},
	{0x091E02, 56},
	{0x099E02, 57},
	{0x095E02, 58},
	{0x09DE02, 59},
	{0x093E02, 60},
	{0x09BE02, 61},
	{0x097E02, 62},
	{0x09FE02, 63}
};

//--------------------------------
// For Airoha AL7230, 2.4Ghz band
// Edit by Tiger, (March, 9, 2005)
// 24bit, MSB first

//channel independent registers:
u32 al7230_rf_data_24[]	=
{
	(0x00<<24)|0x003790,
	(0x01<<24)|0x133331,
	(0x02<<24)|0x841FF2,
	(0x03<<24)|0x3FDFA3,
	(0x04<<24)|0x7FD784,
	(0x05<<24)|0x802B55,
	(0x06<<24)|0x56AF36,
	(0x07<<24)|0xCE0207,
	(0x08<<24)|0x6EBC08,
	(0x09<<24)|0x221BB9,
	(0x0A<<24)|0xE0000A,
	(0x0B<<24)|0x08071B,
	(0x0C<<24)|0x000A3C,
	(0x0D<<24)|0xFFFFFD,
	(0x0E<<24)|0x00000E,
	(0x0F<<24)|0x1ABA8F
};

u32 al7230_channel_data_24[][2] =
{
    {(0x00<<24)|0x003790, (0x01<<24)|0x133331}, // channe1 01
    {(0x00<<24)|0x003790, (0x01<<24)|0x1B3331}, // channe1 02
    {(0x00<<24)|0x003790, (0x01<<24)|0x033331}, // channe1 03
    {(0x00<<24)|0x003790, (0x01<<24)|0x0B3331}, // channe1 04
    {(0x00<<24)|0x0037A0, (0x01<<24)|0x133331}, // channe1 05
    {(0x00<<24)|0x0037A0, (0x01<<24)|0x1B3331}, // channe1 06
    {(0x00<<24)|0x0037A0, (0x01<<24)|0x033331}, // channe1 07
    {(0x00<<24)|0x0037A0, (0x01<<24)|0x0B3331}, // channe1 08
    {(0x00<<24)|0x0037B0, (0x01<<24)|0x133331}, // channe1 09
    {(0x00<<24)|0x0037B0, (0x01<<24)|0x1B3331}, // channe1 10
    {(0x00<<24)|0x0037B0, (0x01<<24)|0x033331}, // channe1 11
    {(0x00<<24)|0x0037B0, (0x01<<24)|0x0B3331}, // channe1 12
    {(0x00<<24)|0x0037C0, (0x01<<24)|0x133331}, // channe1 13
	{(0x00<<24)|0x0037C0, (0x01<<24)|0x066661}  // channel 14
};

//channel independent registers:
u32 al7230_rf_data_50[]	=
{
	(0x00<<24)|0x0FF520,
	(0x01<<24)|0x000001,
	(0x02<<24)|0x451FE2,
	(0x03<<24)|0x5FDFA3,
	(0x04<<24)|0x6FD784,
	(0x05<<24)|0x853F55,
	(0x06<<24)|0x56AF36,
	(0x07<<24)|0xCE0207,
	(0x08<<24)|0x6EBC08,
	(0x09<<24)|0x221BB9,
	(0x0A<<24)|0xE0600A,
	(0x0B<<24)|0x08044B,
	(0x0C<<24)|0x00143C,
	(0x0D<<24)|0xFFFFFD,
	(0x0E<<24)|0x00000E,
	(0x0F<<24)|0x12BACF //5Ghz default state
};

u32 al7230_channel_data_5[][4] =
{
	//channel dependent registers: 0x00, 0x01 and 0x04
	//11J ===========
	{184, (0x00<<24)|0x0FF520, (0x01<<24)|0x000001, (0x04<<24)|0x67F784}, // channel 184
	{188, (0x00<<24)|0x0FF520, (0x01<<24)|0x0AAAA1, (0x04<<24)|0x77F784}, // channel 188
	{192, (0x00<<24)|0x0FF530, (0x01<<24)|0x155551, (0x04<<24)|0x77F784}, // channel 192
	{196, (0x00<<24)|0x0FF530, (0x01<<24)|0x000001, (0x04<<24)|0x67F784}, // channel 196
	{8,   (0x00<<24)|0x0FF540, (0x01<<24)|0x000001, (0x04<<24)|0x67F784}, // channel 008
	{12,  (0x00<<24)|0x0FF540, (0x01<<24)|0x0AAAA1, (0x04<<24)|0x77F784}, // channel 012
	{16,  (0x00<<24)|0x0FF550, (0x01<<24)|0x155551, (0x04<<24)|0x77F784}, // channel 016
	{34,  (0x00<<24)|0x0FF560, (0x01<<24)|0x055551, (0x04<<24)|0x77F784}, // channel 034
	{38,  (0x00<<24)|0x0FF570, (0x01<<24)|0x100001, (0x04<<24)|0x77F784}, // channel 038
	{42,  (0x00<<24)|0x0FF570, (0x01<<24)|0x1AAAA1, (0x04<<24)|0x77F784}, // channel 042
	{46,  (0x00<<24)|0x0FF570, (0x01<<24)|0x055551, (0x04<<24)|0x77F784}, // channel 046
	//11 A/H =========
	{36,  (0x00<<24)|0x0FF560, (0x01<<24)|0x0AAAA1, (0x04<<24)|0x77F784}, // channel 036
	{40,  (0x00<<24)|0x0FF570, (0x01<<24)|0x155551, (0x04<<24)|0x77F784}, // channel 040
	{44,  (0x00<<24)|0x0FF570, (0x01<<24)|0x000001, (0x04<<24)|0x67F784}, // channel 044
	{48,  (0x00<<24)|0x0FF570, (0x01<<24)|0x0AAAA1, (0x04<<24)|0x77F784}, // channel 048
	{52,  (0x00<<24)|0x0FF580, (0x01<<24)|0x155551, (0x04<<24)|0x77F784}, // channel 052
	{56,  (0x00<<24)|0x0FF580, (0x01<<24)|0x000001, (0x04<<24)|0x67F784}, // channel 056
	{60,  (0x00<<24)|0x0FF580, (0x01<<24)|0x0AAAA1, (0x04<<24)|0x77F784}, // channel 060
	{64,  (0x00<<24)|0x0FF590, (0x01<<24)|0x155551, (0x04<<24)|0x77F784}, // channel 064
	{100, (0x00<<24)|0x0FF5C0, (0x01<<24)|0x155551, (0x04<<24)|0x77F784}, // channel 100
	{104, (0x00<<24)|0x0FF5C0, (0x01<<24)|0x000001, (0x04<<24)|0x67F784}, // channel 104
	{108, (0x00<<24)|0x0FF5C0, (0x01<<24)|0x0AAAA1, (0x04<<24)|0x77F784}, // channel 108
	{112, (0x00<<24)|0x0FF5D0, (0x01<<24)|0x155551, (0x04<<24)|0x77F784}, // channel 112
	{116, (0x00<<24)|0x0FF5D0, (0x01<<24)|0x000001, (0x04<<24)|0x67F784}, // channel 116
	{120, (0x00<<24)|0x0FF5D0, (0x01<<24)|0x0AAAA1, (0x04<<24)|0x77F784}, // channel 120
	{124, (0x00<<24)|0x0FF5E0, (0x01<<24)|0x155551, (0x04<<24)|0x77F784}, // channel 124
	{128, (0x00<<24)|0x0FF5E0, (0x01<<24)|0x000001, (0x04<<24)|0x67F784}, // channel 128
	{132, (0x00<<24)|0x0FF5E0, (0x01<<24)|0x0AAAA1, (0x04<<24)|0x77F784}, // channel 132
	{136, (0x00<<24)|0x0FF5F0, (0x01<<24)|0x155551, (0x04<<24)|0x77F784}, // channel 136
	{140, (0x00<<24)|0x0FF5F0, (0x01<<24)|0x000001, (0x04<<24)|0x67F784}, // channel 140
	{149, (0x00<<24)|0x0FF600, (0x01<<24)|0x180001, (0x04<<24)|0x77F784}, // channel 149
	{153, (0x00<<24)|0x0FF600, (0x01<<24)|0x02AAA1, (0x04<<24)|0x77F784}, // channel 153
	{157, (0x00<<24)|0x0FF600, (0x01<<24)|0x0D5551, (0x04<<24)|0x77F784}, // channel 157
	{161, (0x00<<24)|0x0FF610, (0x01<<24)|0x180001, (0x04<<24)|0x77F784}, // channel 161
	{165, (0x00<<24)|0x0FF610, (0x01<<24)|0x02AAA1, (0x04<<24)|0x77F784}  // channel 165
};

//; RF Calibration <=== Register 0x0F
//0x0F 0x1ABA8F; start from 2.4Ghz default state
//0x0F 0x9ABA8F; TXDC compensation
//0x0F 0x3ABA8F; RXFIL adjustment
//0x0F 0x1ABA8F; restore 2.4Ghz default state

//;TXVGA Mapping Table <=== Register 0x0B
u32 al7230_txvga_data[][2] =
{
	{0x08040B, 0}, //TXVGA=0;
	{0x08041B, 1}, //TXVGA=1;
	{0x08042B, 2}, //TXVGA=2;
	{0x08043B, 3}, //TXVGA=3;
	{0x08044B, 4}, //TXVGA=4;
	{0x08045B, 5}, //TXVGA=5;
	{0x08046B, 6}, //TXVGA=6;
	{0x08047B, 7}, //TXVGA=7;
	{0x08048B, 8}, //TXVGA=8;
	{0x08049B, 9}, //TXVGA=9;
	{0x0804AB, 10}, //TXVGA=10;
	{0x0804BB, 11}, //TXVGA=11;
	{0x0804CB, 12}, //TXVGA=12;
	{0x0804DB, 13}, //TXVGA=13;
	{0x0804EB, 14}, //TXVGA=14;
	{0x0804FB, 15}, //TXVGA=15;
	{0x08050B, 16}, //TXVGA=16;
	{0x08051B, 17}, //TXVGA=17;
	{0x08052B, 18}, //TXVGA=18;
	{0x08053B, 19}, //TXVGA=19;
	{0x08054B, 20}, //TXVGA=20;
	{0x08055B, 21}, //TXVGA=21;
	{0x08056B, 22}, //TXVGA=22;
	{0x08057B, 23}, //TXVGA=23;
	{0x08058B, 24}, //TXVGA=24;
	{0x08059B, 25}, //TXVGA=25;
	{0x0805AB, 26}, //TXVGA=26;
	{0x0805BB, 27}, //TXVGA=27;
	{0x0805CB, 28}, //TXVGA=28;
	{0x0805DB, 29}, //TXVGA=29;
	{0x0805EB, 30}, //TXVGA=30;
	{0x0805FB, 31}, //TXVGA=31;
	{0x08060B, 32}, //TXVGA=32;
	{0x08061B, 33}, //TXVGA=33;
	{0x08062B, 34}, //TXVGA=34;
	{0x08063B, 35}, //TXVGA=35;
	{0x08064B, 36}, //TXVGA=36;
	{0x08065B, 37}, //TXVGA=37;
	{0x08066B, 38}, //TXVGA=38;
	{0x08067B, 39}, //TXVGA=39;
	{0x08068B, 40}, //TXVGA=40;
	{0x08069B, 41}, //TXVGA=41;
	{0x0806AB, 42}, //TXVGA=42;
	{0x0806BB, 43}, //TXVGA=43;
	{0x0806CB, 44}, //TXVGA=44;
	{0x0806DB, 45}, //TXVGA=45;
	{0x0806EB, 46}, //TXVGA=46;
	{0x0806FB, 47}, //TXVGA=47;
	{0x08070B, 48}, //TXVGA=48;
	{0x08071B, 49}, //TXVGA=49;
	{0x08072B, 50}, //TXVGA=50;
	{0x08073B, 51}, //TXVGA=51;
	{0x08074B, 52}, //TXVGA=52;
	{0x08075B, 53}, //TXVGA=53;
	{0x08076B, 54}, //TXVGA=54;
	{0x08077B, 55}, //TXVGA=55;
	{0x08078B, 56}, //TXVGA=56;
	{0x08079B, 57}, //TXVGA=57;
	{0x0807AB, 58}, //TXVGA=58;
	{0x0807BB, 59}, //TXVGA=59;
	{0x0807CB, 60}, //TXVGA=60;
	{0x0807DB, 61}, //TXVGA=61;
	{0x0807EB, 62}, //TXVGA=62;
	{0x0807FB, 63}, //TXVGA=63;
};
//--------------------------------


//; W89RF242 RFIC SPI programming initial data
//; Winbond WLAN 11g RFIC BB-SPI register -- version FA5976A rev 1.3b
//; Update Date: Ocotber 3, 2005 by PP10 Hsiang-Te Ho
//;
//; Version 1.3b revision items: (Oct. 1, 2005 by HTHo) for FA5976A
u32 w89rf242_rf_data[]     =
{
    (0x00<<24)|0xF86100, // 20060721 0xF86100, //; 3E184; MODA  (0x00) -- Normal mode ; calibration off
    (0x01<<24)|0xEFFFC2, //; 3BFFF; MODB  (0x01) -- turn off RSSI, and other circuits are turned on
    (0x02<<24)|0x102504, //; 04094; FSET  (0x02) -- default 20MHz crystal ; Icmp=1.5mA
    (0x03<<24)|0x026286, //; 0098A; FCHN  (0x03) -- default CH7, 2442MHz
    (0x04<<24)|0x000208, // 20060612.1.a 0x0002C8, // 20050818 // 20050816 0x000388
						 //; 02008; FCAL  (0x04) -- XTAL Freq Trim=001000 (socket board#1); FA5976AYG_v1.3C
    (0x05<<24)|0x24C60A, // 20060612.1.a 0x24C58A, // 941003 0x24C48A, // 20050818.2 0x24848A, // 20050818 // 20050816 0x24C48A
						 //; 09316; GANA  (0x05) -- TX VGA default (TXVGA=0x18(12)) & TXGPK=110 ; FA5976A_1.3D
    (0x06<<24)|0x3432CC, // 941003 0x26C34C, // 20050818 0x06B40C
						 //; 0D0CB; GANB  (0x06) -- RXDC(DC offset) on; LNA=11; RXVGA=001011(11) ; RXFLSW=11(010001); RXGPK=00; RXGCF=00; -50dBm input
    (0x07<<24)|0x0C68CE, // 20050818.2 0x0C66CE, // 20050818 // 20050816 0x0C68CE
						 //; 031A3; FILT  (0x07) -- TX/RX filter with auto-tuning; TFLBW=011; RFLBW=100
    (0x08<<24)|0x100010, //; 04000; TCAL  (0x08) -- //for LO
    (0x09<<24)|0x004012, // 20060612.1.a 0x6E4012, // 0x004012,
						 //; 1B900; RCALA (0x09) -- FASTS=11; HPDE=01 (100nsec); SEHP=1 (select B0 pin=RXHP); RXHP=1 (Turn on RXHP function)(FA5976A_1.3C)
    (0x0A<<24)|0x704014, //; 1C100; RCALB (0x0A)
    (0x0B<<24)|0x18BDD6, // 941003 0x1805D6, // 20050818.2 0x1801D6, // 20050818 // 20050816 0x1805D6
						 //; 062F7; IQCAL (0x0B) -- Turn on LO phase tuner=0111 & RX-LO phase = 0111; FA5976A_1.3B (2005/09/29)
    (0x0C<<24)|0x575558, // 20050818.2 0x555558, // 20050818 // 20050816 0x575558
						 //; 15D55 ; IBSA  (0x0C) -- IFPre =11 ; TC5376A_v1.3A for corner
    (0x0D<<24)|0x55545A, // 20060612.1.a 0x55555A,
						 //; 15555 ; IBSB  (0x0D)
    (0x0E<<24)|0x5557DC, // 20060612.1.a 0x55555C, // 941003 0x5557DC,
						 //; 1555F ; IBSC  (0x0E) -- IRLNA & IRLNB (PTAT & Const current)=01/01; FA5976B_1.3F (2005/11/25)
	(0x10<<24)|0x000C20, // 941003 0x000020, // 20050818
						 //; 00030 ; TMODA (0x10) -- LNA_gain_step=0011 ; LNA=15/16dB
	(0x11<<24)|0x0C0022, // 941003 0x030022  // 20050818.2 0x030022  // 20050818 // 20050816 0x0C0022
						 //; 03000 ; TMODB (0x11) -- Turn ON RX-Q path Test Switch; To improve IQ path group delay (FA5976A_1.3C)
	(0x12<<24)|0x000024  // 20060612.1.a 0x001824  // 941003 add
						 //; TMODC (0x12) -- Turn OFF Tempearure sensor
};

u32 w89rf242_channel_data_24[][2] =
{
    {(0x03<<24)|0x025B06, (0x04<<24)|0x080408}, // channe1 01
    {(0x03<<24)|0x025C46, (0x04<<24)|0x080408}, // channe1 02
    {(0x03<<24)|0x025D86, (0x04<<24)|0x080408}, // channe1 03
    {(0x03<<24)|0x025EC6, (0x04<<24)|0x080408}, // channe1 04
    {(0x03<<24)|0x026006, (0x04<<24)|0x080408}, // channe1 05
    {(0x03<<24)|0x026146, (0x04<<24)|0x080408}, // channe1 06
    {(0x03<<24)|0x026286, (0x04<<24)|0x080408}, // channe1 07
    {(0x03<<24)|0x0263C6, (0x04<<24)|0x080408}, // channe1 08
    {(0x03<<24)|0x026506, (0x04<<24)|0x080408}, // channe1 09
    {(0x03<<24)|0x026646, (0x04<<24)|0x080408}, // channe1 10
    {(0x03<<24)|0x026786, (0x04<<24)|0x080408}, // channe1 11
    {(0x03<<24)|0x0268C6, (0x04<<24)|0x080408}, // channe1 12
    {(0x03<<24)|0x026A06, (0x04<<24)|0x080408}, // channe1 13
    {(0x03<<24)|0x026D06, (0x04<<24)|0x080408}  // channe1 14
};

u32 w89rf242_power_data_24[] = {(0x05<<24)|0x24C48A, (0x05<<24)|0x24C48A, (0x05<<24)|0x24C48A};

// 20060315.6 Enlarge for new scale
// 20060316.6 20060619.2.a add mapping array
u32 w89rf242_txvga_old_mapping[][2] =
{
	{0, 0} , // New <-> Old
	{1, 1} ,
	{2, 2} ,
	{3, 3} ,
	{4, 4} ,
	{6, 5} ,
	{8, 6 },
	{10, 7 },
	{12, 8 },
	{14, 9 },
	{16, 10},
	{18, 11},
	{20, 12},
	{22, 13},
	{24, 14},
	{26, 15},
	{28, 16},
	{30, 17},
	{32, 18},
	{34, 19},


};

// 20060619.3 modify from Bruce's mail
u32 w89rf242_txvga_data[][5] =
{
	//low gain mode
	{ (0x05<<24)|0x24C00A, 0, 0x00292315, 0x0800FEFF, 0x52523131 },//  ; min gain
	{ (0x05<<24)|0x24C80A, 1, 0x00292315, 0x0800FEFF, 0x52523131 },
	{ (0x05<<24)|0x24C04A, 2, 0x00292315, 0x0800FEFF, 0x52523131 },//  (default) +14dBm (ANT)
	{ (0x05<<24)|0x24C84A, 3, 0x00292315, 0x0800FEFF, 0x52523131 },

	//TXVGA=0x10
	{ (0x05<<24)|0x24C40A, 4, 0x00292315, 0x0800FEFF, 0x60603838 },
	{ (0x05<<24)|0x24C40A, 5, 0x00262114, 0x0700FEFF, 0x65653B3B },

	//TXVGA=0x11
	{ (0x05<<24)|0x24C44A, 6, 0x00241F13, 0x0700FFFF, 0x58583333 },
	{ (0x05<<24)|0x24C44A, 7, 0x00292315, 0x0800FEFF, 0x5E5E3737 },

	//TXVGA=0x12
	{ (0x05<<24)|0x24C48A, 8, 0x00262114, 0x0700FEFF, 0x53533030 },
	{ (0x05<<24)|0x24C48A, 9, 0x00241F13, 0x0700FFFF, 0x59593434 },

	//TXVGA=0x13
	{ (0x05<<24)|0x24C4CA, 10, 0x00292315, 0x0800FEFF, 0x52523030 },
	{ (0x05<<24)|0x24C4CA, 11, 0x00262114, 0x0700FEFF, 0x56563232 },

	//TXVGA=0x14
	{ (0x05<<24)|0x24C50A, 12, 0x00292315, 0x0800FEFF, 0x54543131 },
	{ (0x05<<24)|0x24C50A, 13, 0x00262114, 0x0700FEFF, 0x58583434 },

	//TXVGA=0x15
	{ (0x05<<24)|0x24C54A, 14, 0x00292315, 0x0800FEFF, 0x54543131 },
	{ (0x05<<24)|0x24C54A, 15, 0x00262114, 0x0700FEFF, 0x59593434 },

	//TXVGA=0x16
	{ (0x05<<24)|0x24C58A, 16, 0x00292315, 0x0800FEFF, 0x55553131 },
	{ (0x05<<24)|0x24C58A, 17, 0x00292315, 0x0800FEFF, 0x5B5B3535 },

	//TXVGA=0x17
	{ (0x05<<24)|0x24C5CA, 18, 0x00262114, 0x0700FEFF, 0x51512F2F },
	{ (0x05<<24)|0x24C5CA, 19, 0x00241F13, 0x0700FFFF, 0x55553131 },

	//TXVGA=0x18
	{ (0x05<<24)|0x24C60A, 20, 0x00292315, 0x0800FEFF, 0x4F4F2E2E },
	{ (0x05<<24)|0x24C60A, 21, 0x00262114, 0x0700FEFF, 0x53533030 },

	//TXVGA=0x19
	{ (0x05<<24)|0x24C64A, 22, 0x00292315, 0x0800FEFF, 0x4E4E2D2D },
	{ (0x05<<24)|0x24C64A, 23, 0x00262114, 0x0700FEFF, 0x53533030 },

	//TXVGA=0x1A
	{ (0x05<<24)|0x24C68A, 24, 0x00292315, 0x0800FEFF, 0x50502E2E },
	{ (0x05<<24)|0x24C68A, 25, 0x00262114, 0x0700FEFF, 0x55553131 },

	//TXVGA=0x1B
	{ (0x05<<24)|0x24C6CA, 26, 0x00262114, 0x0700FEFF, 0x53533030 },
	{ (0x05<<24)|0x24C6CA, 27, 0x00292315, 0x0800FEFF, 0x5A5A3434 },

	//TXVGA=0x1C
	{ (0x05<<24)|0x24C70A, 28, 0x00292315, 0x0800FEFF, 0x55553131 },
	{ (0x05<<24)|0x24C70A, 29, 0x00292315, 0x0800FEFF, 0x5D5D3636 },

	//TXVGA=0x1D
	{ (0x05<<24)|0x24C74A, 30, 0x00292315, 0x0800FEFF, 0x5F5F3737 },
	{ (0x05<<24)|0x24C74A, 31, 0x00262114, 0x0700FEFF, 0x65653B3B },

	//TXVGA=0x1E
	{ (0x05<<24)|0x24C78A, 32, 0x00292315, 0x0800FEFF, 0x66663B3B },
	{ (0x05<<24)|0x24C78A, 33, 0x00262114, 0x0700FEFF, 0x70704141 },

	//TXVGA=0x1F
	{ (0x05<<24)|0x24C7CA, 34, 0x00292315, 0x0800FEFF, 0x72724242 }
};

///////////////////////////////////////////////////////////////////////////////////////////////////
///////////////////////////////////////////////////////////////////////////////////////////////////
///////////////////////////////////////////////////////////////////////////////////////////////////



//=============================================================================================================
//  Uxx_ReadEthernetAddress --
//
//  Routine Description:
//    Reads in the Ethernet address from the IC.
//
//  Arguments:
//    pHwData        - The pHwData structure
//
//  Return Value:
//
//    The address is stored in EthernetIDAddr.
//=============================================================================================================
void
Uxx_ReadEthernetAddress(  struct hw_data * pHwData )
{
	u32	ltmp;

	// Reading Ethernet address from EEPROM and set into hardware due to MAC address maybe change.
	// Only unplug and plug again can make hardware read EEPROM again. 20060727
	Wb35Reg_WriteSync( pHwData, 0x03b4, 0x08000000 ); // Start EEPROM access + Read + address(0x0d)
	Wb35Reg_ReadSync( pHwData, 0x03b4, &ltmp );
	*(u16 *)pHwData->PermanentMacAddress = cpu_to_le16((u16)ltmp); //20060926 anson's endian
	Wb35Reg_WriteSync( pHwData, 0x03b4, 0x08010000 ); // Start EEPROM access + Read + address(0x0d)
	Wb35Reg_ReadSync( pHwData, 0x03b4, &ltmp );
	*(u16 *)(pHwData->PermanentMacAddress + 2) = cpu_to_le16((u16)ltmp); //20060926 anson's endian
	Wb35Reg_WriteSync( pHwData, 0x03b4, 0x08020000 ); // Start EEPROM access + Read + address(0x0d)
	Wb35Reg_ReadSync( pHwData, 0x03b4, &ltmp );
	*(u16 *)(pHwData->PermanentMacAddress + 4) = cpu_to_le16((u16)ltmp); //20060926 anson's endian
	*(u16 *)(pHwData->PermanentMacAddress + 6) = 0;
	Wb35Reg_WriteSync( pHwData, 0x03e8, cpu_to_le32(*(u32 *)pHwData->PermanentMacAddress) ); //20060926 anson's endian
	Wb35Reg_WriteSync( pHwData, 0x03ec, cpu_to_le32(*(u32 *)(pHwData->PermanentMacAddress+4)) ); //20060926 anson's endian
}


//===============================================================================================================
//  CardGetMulticastBit --
//  Description:
//    For a given multicast address, returns the byte and bit in the card multicast registers that it hashes to.
//    Calls CardComputeCrc() to determine the CRC value.
//  Arguments:
//    Address - the address
//    Byte - the byte that it hashes to
//    Value - will have a 1 in the relevant bit
//  Return Value:
//    None.
//==============================================================================================================
void CardGetMulticastBit( u8 Address[ETH_ALEN], u8 *Byte, u8 *Value )
{
    u32 Crc;
    u32 BitNumber;

    // First compute the CRC.
    Crc = CardComputeCrc(Address, ETH_ALEN);

	// The computed CRC is bit0~31 from left to right
	//At first we should do right shift 25bits, and read 7bits by using '&', 2^7=128
	BitNumber = (u32) ((Crc >> 26) & 0x3f);

	*Byte  = (u8) (BitNumber >> 3);// 900514 original (BitNumber / 8)
	*Value = (u8) ((u8)1 << (BitNumber % 8));
}

void Uxx_power_on_procedure(  struct hw_data * pHwData )
{
	u32	ltmp, loop;

	if( pHwData->phy_type <= RF_MAXIM_V1 )
		Wb35Reg_WriteSync( pHwData, 0x03d4, 0xffffff38 );
	else
	{
		Wb35Reg_WriteSync( pHwData, 0x03f4, 0xFF5807FF );// 20060721 For NEW IC 0xFF5807FF

		// 20060511.1 Fix the following 4 steps for Rx of RF 2230 initial fail
		Wb35Reg_WriteSync( pHwData, 0x03d4, 0x80 );// regulator on only
		msleep(10); // Modify 20051221.1.b
		Wb35Reg_WriteSync( pHwData, 0x03d4, 0xb8 );// REG_ON RF_RSTN on, and
		msleep(10); // Modify 20051221.1.b

		ltmp = 0x4968;
		if( (pHwData->phy_type == RF_WB_242) ||
			(RF_WB_242_1 == pHwData->phy_type) ) // 20060619.5 Add
			ltmp = 0x4468;
		Wb35Reg_WriteSync( pHwData, 0x03d0, ltmp );

		Wb35Reg_WriteSync( pHwData, 0x03d4, 0xa0 );// PLL_PD REF_PD set to 0

		msleep(20); // Modify 20051221.1.b
		Wb35Reg_ReadSync( pHwData, 0x03d0, &ltmp );
		loop = 500; // Wait for 5 second 20061101
		while( !(ltmp & 0x20) && loop-- )
		{
			msleep(10); // Modify 20051221.1.b
			if( !Wb35Reg_ReadSync( pHwData, 0x03d0, &ltmp ) )
				break;
		}

		Wb35Reg_WriteSync( pHwData, 0x03d4, 0xe0 );// MLK_EN
	}

	Wb35Reg_WriteSync( pHwData, 0x03b0, 1 );// Reset hardware first
	msleep(10); // Add this 20051221.1.b

	// Set burst write delay
	Wb35Reg_WriteSync( pHwData, 0x03f8, 0x7ff );
}

void Set_ChanIndep_RfData_al7230_24(  struct hw_data * pHwData, u32 *pltmp ,char number)
{
	u8	i;

	for( i=0; i<number; i++ )
	{
		pHwData->phy_para[i] = al7230_rf_data_24[i];
		pltmp[i] = (1 << 31) | (0 << 30) | (24 << 24) | (al7230_rf_data_24[i]&0xffffff);
	}
}

void Set_ChanIndep_RfData_al7230_50(  struct hw_data * pHwData, u32 *pltmp, char number)
{
	u8	i;

	for( i=0; i<number; i++ )
	{
		pHwData->phy_para[i] = al7230_rf_data_50[i];
		pltmp[i] = (1 << 31) | (0 << 30) | (24 << 24) | (al7230_rf_data_50[i]&0xffffff);
	}
}


//=============================================================================================================
// RFSynthesizer_initial --
//=============================================================================================================
void
RFSynthesizer_initial(struct hw_data * pHwData)
{
	u32	altmp[32];
	u32 *	pltmp = altmp;
	u32	ltmp;
	u8	number=0x00; // The number of register vale
	u8	i;

	//
	// bit[31]      SPI Enable.
	//              1=perform synthesizer program operation. This bit will
	//              cleared automatically after the operation is completed.
	// bit[30]      SPI R/W Control
	//              0=write,    1=read
	// bit[29:24]   SPI Data Format Length
	// bit[17:4 ]   RF Data bits.
	// bit[3 :0 ]   RF address.
	switch( pHwData->phy_type )
	{
	case RF_MAXIM_2825:
	case RF_MAXIM_V1: // 11g Winbond 2nd BB(with Phy board (v1) + Maxim 331)
		number = sizeof(max2825_rf_data)/sizeof(max2825_rf_data[0]);
		for( i=0; i<number; i++ )
		{
			pHwData->phy_para[i] = max2825_rf_data[i];// Backup Rf parameter
			pltmp[i] = (1 << 31) | (0 << 30) | (18 << 24) | BitReverse( max2825_rf_data[i], 18);
		}
		break;

	case RF_MAXIM_2827:
		number = sizeof(max2827_rf_data)/sizeof(max2827_rf_data[0]);
		for( i=0; i<number; i++ )
		{
			pHwData->phy_para[i] = max2827_rf_data[i];
			pltmp[i] = (1 << 31) | (0 << 30) | (18 << 24) | BitReverse( max2827_rf_data[i], 18);
		}
		break;

	case RF_MAXIM_2828:
		number = sizeof(max2828_rf_data)/sizeof(max2828_rf_data[0]);
		for( i=0; i<number; i++ )
		{
			pHwData->phy_para[i] = max2828_rf_data[i];
			pltmp[i] = (1 << 31) | (0 << 30) | (18 << 24) | BitReverse( max2828_rf_data[i], 18);
		}
		break;

	case RF_MAXIM_2829:
		number = sizeof(max2829_rf_data)/sizeof(max2829_rf_data[0]);
		for( i=0; i<number; i++ )
		{
			pHwData->phy_para[i] = max2829_rf_data[i];
			pltmp[i] = (1 << 31) | (0 << 30) | (18 << 24) | BitReverse( max2829_rf_data[i], 18);
		}
		break;

	case RF_AIROHA_2230:
		number = sizeof(al2230_rf_data)/sizeof(al2230_rf_data[0]);
		for( i=0; i<number; i++ )
		{
			pHwData->phy_para[i] = al2230_rf_data[i];
			pltmp[i] = (1 << 31) | (0 << 30) | (20 << 24) | BitReverse( al2230_rf_data[i], 20);
		}
		break;

	case RF_AIROHA_2230S:
		number = sizeof(al2230s_rf_data)/sizeof(al2230s_rf_data[0]);
		for( i=0; i<number; i++ )
		{
			pHwData->phy_para[i] = al2230s_rf_data[i];
			pltmp[i] = (1 << 31) | (0 << 30) | (20 << 24) | BitReverse( al2230s_rf_data[i], 20);
		}
		break;

	case RF_AIROHA_7230:

		//Start to fill RF parameters, PLL_ON should be pulled low.
		Wb35Reg_WriteSync( pHwData, 0x03dc, 0x00000000 );
#ifdef _PE_STATE_DUMP_
		printk("* PLL_ON    low\n");
#endif

		number = sizeof(al7230_rf_data_24)/sizeof(al7230_rf_data_24[0]);
		Set_ChanIndep_RfData_al7230_24(pHwData, pltmp, number);
		break;

	case RF_WB_242:
	case RF_WB_242_1: // 20060619.5 Add
		number = sizeof(w89rf242_rf_data)/sizeof(w89rf242_rf_data[0]);
		for( i=0; i<number; i++ )
		{
			ltmp = w89rf242_rf_data[i];
			if( i == 4 ) // Update the VCO trim from EEPROM
			{
				ltmp &= ~0xff0; // Mask bit4 ~bit11
				ltmp |= pHwData->VCO_trim<<4;
			}

			pHwData->phy_para[i] = ltmp;
			pltmp[i] = (1 << 31) | (0 << 30) | (24 << 24) | BitReverse( ltmp, 24);
		}
		break;
	}

	pHwData->phy_number = number;

	 // The 16 is the maximum capability of hardware. Here use 12
	if( number > 12 ) {
		//Wb35Reg_BurstWrite( pHwData, 0x0864, pltmp, 12, NO_INCREMENT );
		for( i=0; i<12; i++ ) // For Al2230
			Wb35Reg_WriteSync( pHwData, 0x0864, pltmp[i] );

		pltmp += 12;
		number -= 12;
	}

	// Write to register. number must less and equal than 16
	for( i=0; i<number; i++ )
		Wb35Reg_WriteSync( pHwData, 0x864, pltmp[i] );

	// 20060630.1 Calibration only 1 time
	if( pHwData->CalOneTime )
		return;
	pHwData->CalOneTime = 1;

	switch( pHwData->phy_type )
	{
		case RF_AIROHA_2230:

			// 20060511.1 --- Modifying the follow step for Rx issue-----------------
			ltmp = (1 << 31) | (0 << 30) | (20 << 24) | BitReverse( (0x07<<20)|0xE168E, 20);
			Wb35Reg_WriteSync( pHwData, 0x0864, ltmp );
			msleep(10);
			ltmp = (1 << 31) | (0 << 30) | (20 << 24) | BitReverse( al2230_rf_data[7], 20);
			Wb35Reg_WriteSync( pHwData, 0x0864, ltmp );
			msleep(10);

		case RF_AIROHA_2230S: // 20060420 Add this

			// 20060511.1 --- Modifying the follow step for Rx issue-----------------
			Wb35Reg_WriteSync( pHwData, 0x03d4, 0x80 );// regulator on only
			msleep(10); // Modify 20051221.1.b

			Wb35Reg_WriteSync( pHwData, 0x03d4, 0xa0 );// PLL_PD REF_PD set to 0
			msleep(10); // Modify 20051221.1.b

			Wb35Reg_WriteSync( pHwData, 0x03d4, 0xe0 );// MLK_EN
			Wb35Reg_WriteSync( pHwData, 0x03b0, 1 );// Reset hardware first
			msleep(10); // Add this 20051221.1.b
			//------------------------------------------------------------------------

			// The follow code doesn't use the burst-write mode
			//phy_set_rf_data(phw_data, 0x0F, (0x0F<<20) | 0xF01A0); //Raise Initial Setting
			ltmp = (1 << 31) | (0 << 30) | (20 << 24) | BitReverse( (0x0F<<20) | 0xF01A0, 20);
			Wb35Reg_WriteSync( pHwData, 0x0864, ltmp );

			ltmp = pHwData->reg.BB5C & 0xfffff000;
			Wb35Reg_WriteSync( pHwData, 0x105c, ltmp );
			pHwData->reg.BB50 |= 0x13;//(MASK_IQCAL_MODE|MASK_CALIB_START);//20060315.1 modify
	        	Wb35Reg_WriteSync(pHwData, 0x1050, pHwData->reg.BB50);
			msleep(5);

			//phy_set_rf_data(phw_data, 0x0F, (0x0F<<20) | 0xF01B0); //Activate Filter Cal.
			ltmp = (1 << 31) | (0 << 30) | (20 << 24) | BitReverse( (0x0F<<20) | 0xF01B0, 20);
			Wb35Reg_WriteSync( pHwData, 0x0864, ltmp );
			msleep(5);

			//phy_set_rf_data(phw_data, 0x0F, (0x0F<<20) | 0xF01e0); //Activate TX DCC
			ltmp = (1 << 31) | (0 << 30) | (20 << 24) | BitReverse( (0x0F<<20) | 0xF01E0, 20);
			Wb35Reg_WriteSync( pHwData, 0x0864, ltmp );
			msleep(5);

			//phy_set_rf_data(phw_data, 0x0F, (0x0F<<20) | 0xF01A0); //Resotre Initial Setting
			ltmp = (1 << 31) | (0 << 30) | (20 << 24) | BitReverse( (0x0F<<20) | 0xF01A0, 20);
			Wb35Reg_WriteSync( pHwData, 0x0864, ltmp );

//			//Force TXI(Q)P(N) to normal control
			Wb35Reg_WriteSync( pHwData, 0x105c, pHwData->reg.BB5C );
			pHwData->reg.BB50 &= ~0x13;//(MASK_IQCAL_MODE|MASK_CALIB_START);
        	Wb35Reg_WriteSync( pHwData, 0x1050, pHwData->reg.BB50);
			break;

		case RF_AIROHA_7230:

			//RF parameters have filled completely, PLL_ON should be
			//pulled high
			Wb35Reg_WriteSync( pHwData, 0x03dc, 0x00000080 );
			#ifdef _PE_STATE_DUMP_
			printk("* PLL_ON    high\n");
			#endif

			//2.4GHz
			//ltmp = (1 << 31) | (0 << 30) | (24 << 24) | 0x1ABA8F;
			//Wb35Reg_WriteSync pHwData, 0x0864, ltmp );
			//msleep(1); // Sleep 1 ms
			ltmp = (1 << 31) | (0 << 30) | (24 << 24) | 0x9ABA8F;
			Wb35Reg_WriteSync( pHwData, 0x0864, ltmp );
			msleep(5);
			ltmp = (1 << 31) | (0 << 30) | (24 << 24) | 0x3ABA8F;
			Wb35Reg_WriteSync( pHwData, 0x0864, ltmp );
			msleep(5);
			ltmp = (1 << 31) | (0 << 30) | (24 << 24) | 0x1ABA8F;
			Wb35Reg_WriteSync( pHwData, 0x0864, ltmp );
			msleep(5);

			//5GHz
			Wb35Reg_WriteSync( pHwData, 0x03dc, 0x00000000 );
			#ifdef _PE_STATE_DUMP_
			printk("* PLL_ON    low\n");
			#endif

			number = sizeof(al7230_rf_data_50)/sizeof(al7230_rf_data_50[0]);
			Set_ChanIndep_RfData_al7230_50(pHwData, pltmp, number);
			// Write to register. number must less and equal than 16
			for( i=0; i<number; i++ )
				Wb35Reg_WriteSync( pHwData, 0x0864, pltmp[i] );
			msleep(5);

			Wb35Reg_WriteSync( pHwData, 0x03dc, 0x00000080 );
			#ifdef _PE_STATE_DUMP_
			printk("* PLL_ON    high\n");
			#endif

			//ltmp = (1 << 31) | (0 << 30) | (24 << 24) | 0x12BACF;
			//Wb35Reg_WriteSync( pHwData, 0x0864, ltmp );
			ltmp = (1 << 31) | (0 << 30) | (24 << 24) | 0x9ABA8F;
			Wb35Reg_WriteSync( pHwData, 0x0864, ltmp );
			msleep(5);
			ltmp = (1 << 31) | (0 << 30) | (24 << 24) | 0x3ABA8F;
			Wb35Reg_WriteSync( pHwData, 0x0864, ltmp );
			msleep(5);
			ltmp = (1 << 31) | (0 << 30) | (24 << 24) | 0x12BACF;
			Wb35Reg_WriteSync( pHwData, 0x0864, ltmp );
			msleep(5);

			//Wb35Reg_WriteSync( pHwData, 0x03dc, 0x00000080 );
			//printk("* PLL_ON    high\n");
			break;

		case RF_WB_242:
		case RF_WB_242_1: // 20060619.5 Add

			//
			// ; Version 1.3B revision items: for FA5976A , October 3, 2005 by HTHo
			//
			ltmp = pHwData->reg.BB5C & 0xfffff000;
			Wb35Reg_WriteSync( pHwData, 0x105c, ltmp );
			Wb35Reg_WriteSync( pHwData, 0x1058, 0 );
			pHwData->reg.BB50 |= 0x3;//(MASK_IQCAL_MODE|MASK_CALIB_START);//20060630
		      	Wb35Reg_WriteSync(pHwData, 0x1050, pHwData->reg.BB50);

			//----- Calibration (1). VCO frequency calibration
			//Calibration (1a.0). Synthesizer reset (HTHo corrected 2005/05/10)
			ltmp = (1 << 31) | (0 << 30) | (24 << 24) | BitReverse( (0x0F<<24) | 0x00101E, 24);
			Wb35Reg_WriteSync( pHwData, 0x0864, ltmp );
			msleep(5); // Sleep 5ms
			//Calibration (1a). VCO frequency calibration mode ; waiting 2msec VCO calibration time
			ltmp = (1 << 31) | (0 << 30) | (24 << 24) | BitReverse( (0x00<<24) | 0xFE69c0, 24);
			Wb35Reg_WriteSync( pHwData, 0x0864, ltmp );
			msleep(2); // Sleep 2ms

			//----- Calibration (2). TX baseband Gm-C filter auto-tuning
			//Calibration (2a). turn off ENCAL signal
			ltmp = (1 << 31) | (0 << 30) | (24 << 24) | BitReverse( (0x00<<24) | 0xF8EBC0, 24);
			Wb35Reg_WriteSync( pHwData, 0x0864, ltmp );
			//Calibration (2b.0). TX filter auto-tuning BW: TFLBW=101 (TC5376A default)
			ltmp = (1 << 31) | (0 << 30) | (24 << 24) | BitReverse( (0x07<<24) | 0x0C68CE, 24);
			Wb35Reg_WriteSync( pHwData, 0x0864, ltmp );
			//Calibration (2b). send TX reset signal (HTHo corrected May 10, 2005)
			ltmp = (1 << 31) | (0 << 30) | (24 << 24) | BitReverse( (0x0F<<24) | 0x00201E, 24);
			Wb35Reg_WriteSync( pHwData, 0x0864, ltmp );
			//Calibration (2c). turn-on TX Gm-C filter auto-tuning
			ltmp = (1 << 31) | (0 << 30) | (24 << 24) | BitReverse( (0x00<<24) | 0xFCEBC0, 24);
			Wb35Reg_WriteSync( pHwData, 0x0864, ltmp );
			udelay(150); // Sleep 150 us
			//turn off ENCAL signal
			ltmp = (1 << 31) | (0 << 30) | (24 << 24) | BitReverse( (0x00<<24) | 0xF8EBC0, 24);
			Wb35Reg_WriteSync( pHwData, 0x0864, ltmp );

			//----- Calibration (3). RX baseband Gm-C filter auto-tuning
			//Calibration (3a). turn off ENCAL signal
			ltmp = (1 << 31) | (0 << 30) | (24 << 24) | BitReverse( (0x00<<24) | 0xFAEDC0, 24);
			Wb35Reg_WriteSync( pHwData, 0x0864, ltmp );
			//Calibration (3b.0). RX filter auto-tuning BW: RFLBW=100 (TC5376A+corner default; July 26, 2005)
			ltmp = (1 << 31) | (0 << 30) | (24 << 24) | BitReverse( (0x07<<24) | 0x0C68CE, 24);
			Wb35Reg_WriteSync( pHwData, 0x0864, ltmp );
			//Calibration (3b). send RX reset signal (HTHo corrected May 10, 2005)
			ltmp = (1 << 31) | (0 << 30) | (24 << 24) | BitReverse( (0x0F<<24) | 0x00401E, 24);
			Wb35Reg_WriteSync( pHwData, 0x0864, ltmp );
			//Calibration (3c). turn-on RX Gm-C filter auto-tuning
			ltmp = (1 << 31) | (0 << 30) | (24 << 24) | BitReverse( (0x00<<24) | 0xFEEDC0, 24);
			Wb35Reg_WriteSync( pHwData, 0x0864, ltmp );
			udelay(150); // Sleep 150 us
			//Calibration (3e). turn off ENCAL signal
			ltmp = (1 << 31) | (0 << 30) | (24 << 24) | BitReverse( (0x00<<24) | 0xFAEDC0, 24);
			Wb35Reg_WriteSync( pHwData, 0x0864, ltmp );

			//----- Calibration (4). TX LO leakage calibration
			//Calibration (4a). TX LO leakage calibration
			ltmp = (1 << 31) | (0 << 30) | (24 << 24) | BitReverse( (0x00<<24) | 0xFD6BC0, 24);
			Wb35Reg_WriteSync( pHwData, 0x0864, ltmp );
			udelay(150); // Sleep 150 us

			//----- Calibration (5). RX DC offset calibration
			//Calibration (5a). turn off ENCAL signal and set to RX SW DC caliration mode
			ltmp = (1 << 31) | (0 << 30) | (24 << 24) | BitReverse( (0x00<<24) | 0xFAEDC0, 24);
			Wb35Reg_WriteSync( pHwData, 0x0864, ltmp );
			//Calibration (5b). turn off AGC servo-loop & RSSI
			ltmp = (1 << 31) | (0 << 30) | (24 << 24) | BitReverse( (0x01<<24) | 0xEBFFC2, 24);
			Wb35Reg_WriteSync( pHwData, 0x0864, ltmp );

			//; for LNA=11 --------
			//Calibration (5c-h). RX DC offset current bias ON; & LNA=11; RXVGA=111111
			ltmp = (1 << 31) | (0 << 30) | (24 << 24) | BitReverse( (0x06<<24) | 0x343FCC, 24);
			Wb35Reg_WriteSync( pHwData, 0x0864, ltmp );
			//Calibration (5d). turn on RX DC offset cal function; and waiting 2 msec cal time
			ltmp = (1 << 31) | (0 << 30) | (24 << 24) | BitReverse( (0x00<<24) | 0xFF6DC0, 24);
			Wb35Reg_WriteSync( pHwData, 0x0864, ltmp );
			msleep(2); // Sleep 2ms
			//Calibration (5f). turn off ENCAL signal
			ltmp = (1 << 31) | (0 << 30) | (24 << 24) | BitReverse( (0x00<<24) | 0xFAEDC0, 24);
			Wb35Reg_WriteSync( pHwData, 0x0864, ltmp );

			//; for LNA=10 --------
			//Calibration (5c-m). RX DC offset current bias ON; & LNA=10; RXVGA=111111
			ltmp = (1 << 31) | (0 << 30) | (24 << 24) | BitReverse( (0x06<<24) | 0x342FCC, 24);
			Wb35Reg_WriteSync( pHwData, 0x0864, ltmp );
			//Calibration (5d). turn on RX DC offset cal function; and waiting 2 msec cal time
			ltmp = (1 << 31) | (0 << 30) | (24 << 24) | BitReverse( (0x00<<24) | 0xFF6DC0, 24);
			Wb35Reg_WriteSync( pHwData, 0x0864, ltmp );
			msleep(2); // Sleep 2ms
			//Calibration (5f). turn off ENCAL signal
			ltmp = (1 << 31) | (0 << 30) | (24 << 24) | BitReverse( (0x00<<24) | 0xFAEDC0, 24);
			Wb35Reg_WriteSync( pHwData, 0x0864, ltmp );

			//; for LNA=01 --------
			//Calibration (5c-m). RX DC offset current bias ON; & LNA=01; RXVGA=111111
			ltmp = (1 << 31) | (0 << 30) | (24 << 24) | BitReverse( (0x06<<24) | 0x341FCC, 24);
			Wb35Reg_WriteSync( pHwData, 0x0864, ltmp );
			//Calibration (5d). turn on RX DC offset cal function; and waiting 2 msec cal time
			ltmp = (1 << 31) | (0 << 30) | (24 << 24) | BitReverse( (0x00<<24) | 0xFF6DC0, 24);
			Wb35Reg_WriteSync( pHwData, 0x0864, ltmp );
			msleep(2); // Sleep 2ms
			//Calibration (5f). turn off ENCAL signal
			ltmp = (1 << 31) | (0 << 30) | (24 << 24) | BitReverse( (0x00<<24) | 0xFAEDC0, 24);
			Wb35Reg_WriteSync( pHwData, 0x0864, ltmp );

			//; for LNA=00 --------
			//Calibration (5c-l). RX DC offset current bias ON; & LNA=00; RXVGA=111111
			ltmp = (1 << 31) | (0 << 30) | (24 << 24) | BitReverse( (0x06<<24) | 0x340FCC, 24);
			Wb35Reg_WriteSync( pHwData, 0x0864, ltmp );
			//Calibration (5d). turn on RX DC offset cal function; and waiting 2 msec cal time
			ltmp = (1 << 31) | (0 << 30) | (24 << 24) | BitReverse( (0x00<<24) | 0xFF6DC0, 24);
			Wb35Reg_WriteSync( pHwData, 0x0864, ltmp );
			msleep(2); // Sleep 2ms
			//Calibration (5f). turn off ENCAL signal
			ltmp = (1 << 31) | (0 << 30) | (24 << 24) | BitReverse( (0x00<<24) | 0xFAEDC0, 24);
			Wb35Reg_WriteSync( pHwData, 0x0864, ltmp );
			//Calibration (5g). turn on AGC servo-loop
			ltmp = (1 << 31) | (0 << 30) | (24 << 24) | BitReverse( (0x01<<24) | 0xEFFFC2, 24);
			Wb35Reg_WriteSync( pHwData, 0x0864, ltmp );

			//; ----- Calibration (7). Switch RF chip to normal mode
			//0x00 0xF86100 ; 3E184   ; Switch RF chip to normal mode
//			msleep(10); // @@ 20060721
			ltmp = (1 << 31) | (0 << 30) | (24 << 24) | BitReverse( (0x00<<24) | 0xF86100, 24);
			Wb35Reg_WriteSync( pHwData, 0x0864, ltmp );
			msleep(5); // Sleep 5 ms

//			//write back
//			Wb35Reg_WriteSync(pHwData, 0x105c, pHwData->reg.BB5C);
//			pHwData->reg.BB50 &= ~0x13;//(MASK_IQCAL_MODE|MASK_CALIB_START); // 20060315.1 fix
//		      	Wb35Reg_WriteSync(pHwData, 0x1050, pHwData->reg.BB50);
//			msleep(1); // Sleep 1 ms
			break;
	}
}

void BBProcessor_AL7230_2400(  struct hw_data * pHwData)
{
	struct wb35_reg *reg = &pHwData->reg;
	u32	pltmp[12];

	pltmp[0] = 0x16A8337A; // 0x16a5215f; // 0x1000 AGC_Ctrl1
	pltmp[1] = 0x9AFF9AA6; // 0x9aff9ca6; // 0x1004 AGC_Ctrl2
	pltmp[2] = 0x55D00A04; // 0x55d00a04; // 0x1008 AGC_Ctrl3
	pltmp[3] = 0xFFF72031; // 0xFfFf2138; // 0x100c AGC_Ctrl4
	reg->BB0C = 0xFFF72031;
	pltmp[4] = 0x0FacDCC5; // 0x1010 AGC_Ctrl5 // 20050927 0x0FacDCB7
	pltmp[5] = 0x00CAA333; // 0x00eaa333; // 0x1014 AGC_Ctrl6
	pltmp[6] = 0xF2211111; // 0x11111111; // 0x1018 AGC_Ctrl7
	pltmp[7] = 0x0FA3F0ED; // 0x101c AGC_Ctrl8
	pltmp[8] = 0x06443440; // 0x1020 AGC_Ctrl9
	pltmp[9] = 0xA8002A79; // 0xa9002A79; // 0x1024 AGC_Ctrl10
	pltmp[10] = 0x40000528; // 20050927 0x40000228
	pltmp[11] = 0x232D7F30; // 0x23457f30;// 0x102c A_ACQ_Ctrl
	reg->BB2C = 0x232D7F30;
	Wb35Reg_BurstWrite( pHwData, 0x1000, pltmp, 12, AUTO_INCREMENT );

	pltmp[0] = 0x00002c54; // 0x1030 B_ACQ_Ctrl
	reg->BB30 = 0x00002c54;
	pltmp[1] = 0x00C0D6C5; // 0x1034 A_TXRX_Ctrl
	pltmp[2] = 0x5B2C8769; // 0x1038 B_TXRX_Ctrl
	pltmp[3] = 0x00000000; // 0x103c 11a TX LS filter
	reg->BB3C = 0x00000000;
	pltmp[4] = 0x00003F29; // 0x1040 11a TX LS filter
	pltmp[5] = 0x0EFEFBFE; // 0x1044 11a TX LS filter
	pltmp[6] = 0x00332C1B; // 0x00453B24; // 0x1048 11b TX RC filter
	pltmp[7] = 0x0A00FEFF; // 0x0E00FEFF; // 0x104c 11b TX RC filter
	pltmp[8] = 0x2B106208; // 0x1050 MODE_Ctrl
	reg->BB50 = 0x2B106208;
	pltmp[9] = 0; // 0x1054
	reg->BB54 = 0x00000000;
	pltmp[10] = 0x52524242; // 0x64645252; // 0x1058 IQ_Alpha
	reg->BB58 = 0x52524242;
	pltmp[11] = 0xAA0AC000; // 0x105c DC_Cancel
	Wb35Reg_BurstWrite( pHwData, 0x1030, pltmp, 12, AUTO_INCREMENT );

}

void BBProcessor_AL7230_5000(  struct hw_data * pHwData)
{
	struct wb35_reg *reg = &pHwData->reg;
	u32	pltmp[12];

	pltmp[0] = 0x16AA6678; // 0x1000 AGC_Ctrl1
	pltmp[1] = 0x9AFFA0B2; // 0x1004 AGC_Ctrl2
	pltmp[2] = 0x55D00A04; // 0x1008 AGC_Ctrl3
	pltmp[3] = 0xEFFF233E; // 0x100c AGC_Ctrl4
	reg->BB0C = 0xEFFF233E;
	pltmp[4] = 0x0FacDCC5; // 0x1010 AGC_Ctrl5 // 20050927 0x0FacDCB7
	pltmp[5] = 0x00CAA333; // 0x1014 AGC_Ctrl6
	pltmp[6] = 0xF2432111; // 0x1018 AGC_Ctrl7
	pltmp[7] = 0x0FA3F0ED; // 0x101c AGC_Ctrl8
	pltmp[8] = 0x05C43440; // 0x1020 AGC_Ctrl9
	pltmp[9] = 0x00002A79; // 0x1024 AGC_Ctrl10
	pltmp[10] = 0x40000528; // 20050927 0x40000228
	pltmp[11] = 0x232FDF30;// 0x102c A_ACQ_Ctrl
	reg->BB2C = 0x232FDF30;
	Wb35Reg_BurstWrite( pHwData, 0x1000, pltmp, 12, AUTO_INCREMENT );

	pltmp[0] = 0x80002C7C; // 0x1030 B_ACQ_Ctrl
	pltmp[1] = 0x00C0D6C5; // 0x1034 A_TXRX_Ctrl
	pltmp[2] = 0x5B2C8769; // 0x1038 B_TXRX_Ctrl
	pltmp[3] = 0x00000000; // 0x103c 11a TX LS filter
	reg->BB3C = 0x00000000;
	pltmp[4] = 0x00003F29; // 0x1040 11a TX LS filter
	pltmp[5] = 0x0EFEFBFE; // 0x1044 11a TX LS filter
	pltmp[6] = 0x00332C1B; // 0x1048 11b TX RC filter
	pltmp[7] = 0x0A00FEFF; // 0x104c 11b TX RC filter
	pltmp[8] = 0x2B107208; // 0x1050 MODE_Ctrl
	reg->BB50 = 0x2B107208;
	pltmp[9] = 0; // 0x1054
	reg->BB54 = 0x00000000;
	pltmp[10] = 0x52524242; // 0x1058 IQ_Alpha
	reg->BB58 = 0x52524242;
	pltmp[11] = 0xAA0AC000; // 0x105c DC_Cancel
	Wb35Reg_BurstWrite( pHwData, 0x1030, pltmp, 12, AUTO_INCREMENT );

}

//=============================================================================================================
//  BBProcessorPowerupInit --
//
//  Description:
//    Initialize the Baseband processor.
//
//  Arguments:
//    pHwData    - Handle of the USB Device.
//
//  Return values:
//    None.
//=============================================================================================================
void
BBProcessor_initial(  struct hw_data * pHwData )
{
	struct wb35_reg *reg = &pHwData->reg;
	u32	i, pltmp[12];

    switch( pHwData->phy_type )
    {
		case RF_MAXIM_V1: // Initializng the Winbond 2nd BB(with Phy board (v1) + Maxim 331)

			pltmp[0] = 0x16F47E77; // 0x1000 AGC_Ctrl1
			pltmp[1] = 0x9AFFAEA4; // 0x1004 AGC_Ctrl2
			pltmp[2] = 0x55D00A04; // 0x1008 AGC_Ctrl3
			pltmp[3] = 0xEFFF1A34; // 0x100c AGC_Ctrl4
			reg->BB0C = 0xEFFF1A34;
			pltmp[4] = 0x0FABE0B7; // 0x1010 AGC_Ctrl5
			pltmp[5] = 0x00CAA332; // 0x1014 AGC_Ctrl6
			pltmp[6] = 0xF6632111; // 0x1018 AGC_Ctrl7
			pltmp[7] = 0x0FA3F0ED; // 0x101c AGC_Ctrl8
			pltmp[8] = 0x04CC3640; // 0x1020 AGC_Ctrl9
			pltmp[9] = 0x00002A79; // 0x1024 AGC_Ctrl10
			pltmp[10] = (pHwData->phy_type==3) ? 0x40000a28 : 0x40000228; // 0x1028 MAXIM_331(b31=0) + WBRF_V1(b11=1) : MAXIM_331(b31=0) + WBRF_V2(b11=0)
			pltmp[11] = 0x232FDF30; // 0x102c A_ACQ_Ctrl
			reg->BB2C = 0x232FDF30; //Modify for 33's 1.0.95.xxx version, antenna 1
			Wb35Reg_BurstWrite( pHwData, 0x1000, pltmp, 12, AUTO_INCREMENT );

			pltmp[0] = 0x00002C54; // 0x1030 B_ACQ_Ctrl
			reg->BB30 = 0x00002C54;
			pltmp[1] = 0x00C0D6C5; // 0x1034 A_TXRX_Ctrl
			pltmp[2] = 0x5B6C8769; // 0x1038 B_TXRX_Ctrl
			pltmp[3] = 0x00000000; // 0x103c 11a TX LS filter
			reg->BB3C = 0x00000000;
			pltmp[4] = 0x00003F29; // 0x1040 11a TX LS filter
			pltmp[5] = 0x0EFEFBFE; // 0x1044 11a TX LS filter
			pltmp[6] = 0x00453B24; // 0x1048 11b TX RC filter
			pltmp[7] = 0x0E00FEFF; // 0x104c 11b TX RC filter
			pltmp[8] = 0x27106208; // 0x1050 MODE_Ctrl
			reg->BB50 = 0x27106208;
			pltmp[9] = 0; // 0x1054
			reg->BB54 = 0x00000000;
			pltmp[10] = 0x64646464; // 0x1058 IQ_Alpha
			reg->BB58 = 0x64646464;
			pltmp[11] = 0xAA0AC000; // 0x105c DC_Cancel
			Wb35Reg_BurstWrite( pHwData, 0x1030, pltmp, 12, AUTO_INCREMENT );

			Wb35Reg_Write( pHwData, 0x1070, 0x00000045 );
			break;

		//------------------------------------------------------------------
		//[20040722 WK]
		//Only for baseband version 2
//		case RF_MAXIM_317:
		case RF_MAXIM_2825:
		case RF_MAXIM_2827:
		case RF_MAXIM_2828:

			pltmp[0] = 0x16b47e77; // 0x1000 AGC_Ctrl1
			pltmp[1] = 0x9affaea4; // 0x1004 AGC_Ctrl2
			pltmp[2] = 0x55d00a04; // 0x1008 AGC_Ctrl3
			pltmp[3] = 0xefff1a34; // 0x100c AGC_Ctrl4
			reg->BB0C = 0xefff1a34;
			pltmp[4] = 0x0fabe0b7; // 0x1010 AGC_Ctrl5
			pltmp[5] = 0x00caa332; // 0x1014 AGC_Ctrl6
			pltmp[6] = 0xf6632111; // 0x1018 AGC_Ctrl7
			pltmp[7] = 0x0FA3F0ED; // 0x101c AGC_Ctrl8
			pltmp[8] = 0x04CC3640; // 0x1020 AGC_Ctrl9
			pltmp[9] = 0x00002A79; // 0x1024 AGC_Ctrl10
			pltmp[10] = 0x40000528; // 0x40000128; Modify for 33's 1.0.95
			pltmp[11] = 0x232fdf30; // 0x102c A_ACQ_Ctrl
			reg->BB2C = 0x232fdf30; //Modify for 33's 1.0.95.xxx version, antenna 1
			Wb35Reg_BurstWrite( pHwData, 0x1000, pltmp, 12, AUTO_INCREMENT );

			pltmp[0] = 0x00002C54; // 0x1030 B_ACQ_Ctrl
			reg->BB30 = 0x00002C54;
			pltmp[1] = 0x00C0D6C5; // 0x1034 A_TXRX_Ctrl
			pltmp[2] = 0x5B6C8769; // 0x1038 B_TXRX_Ctrl
			pltmp[3] = 0x00000000; // 0x103c 11a TX LS filter
			reg->BB3C = 0x00000000;
			pltmp[4] = 0x00003F29; // 0x1040 11a TX LS filter
			pltmp[5] = 0x0EFEFBFE; // 0x1044 11a TX LS filter
			pltmp[6] = 0x00453B24; // 0x1048 11b TX RC filter
			pltmp[7] = 0x0D00FDFF; // 0x104c 11b TX RC filter
			pltmp[8] = 0x27106208; // 0x1050 MODE_Ctrl
			reg->BB50 = 0x27106208;
			pltmp[9] = 0; // 0x1054
			reg->BB54 = 0x00000000;
			pltmp[10] = 0x64646464; // 0x1058 IQ_Alpha
			reg->BB58 = 0x64646464;
			pltmp[11] = 0xAA28C000; // 0x105c DC_Cancel
			Wb35Reg_BurstWrite( pHwData, 0x1030, pltmp, 12, AUTO_INCREMENT );

			Wb35Reg_Write( pHwData, 0x1070, 0x00000045 );
			break;

		case RF_MAXIM_2829:

			pltmp[0] = 0x16b47e77; // 0x1000 AGC_Ctrl1
			pltmp[1] = 0x9affaea4; // 0x1004 AGC_Ctrl2
			pltmp[2] = 0x55d00a04; // 0x1008 AGC_Ctrl3
			pltmp[3] = 0xf4ff1632; // 0xefff1a34; // 0x100c AGC_Ctrl4 Modify for 33's 1.0.95
			reg->BB0C = 0xf4ff1632; // 0xefff1a34; Modify for 33's 1.0.95
			pltmp[4] = 0x0fabe0b7; // 0x1010 AGC_Ctrl5
			pltmp[5] = 0x00caa332; // 0x1014 AGC_Ctrl6
			pltmp[6] = 0xf8632112; // 0xf6632111; // 0x1018 AGC_Ctrl7 Modify for 33's 1.0.95
			pltmp[7] = 0x0FA3F0ED; // 0x101c AGC_Ctrl8
			pltmp[8] = 0x04CC3640; // 0x1020 AGC_Ctrl9
			pltmp[9] = 0x00002A79; // 0x1024 AGC_Ctrl10
			pltmp[10] = 0x40000528; // 0x40000128; modify for 33's 1.0.95
			pltmp[11] = 0x232fdf30; // 0x102c A_ACQ_Ctrl
			reg->BB2C = 0x232fdf30; //Modify for 33's 1.0.95.xxx version, antenna 1
			Wb35Reg_BurstWrite( pHwData, 0x1000, pltmp, 12, AUTO_INCREMENT );

			pltmp[0] = 0x00002C54; // 0x1030 B_ACQ_Ctrl
			reg->BB30 = 0x00002C54;
			pltmp[1] = 0x00C0D6C5; // 0x1034 A_TXRX_Ctrl
			pltmp[2] = 0x5b2c8769; // 0x5B6C8769; // 0x1038 B_TXRX_Ctrl Modify for 33's 1.0.95
			pltmp[3] = 0x00000000; // 0x103c 11a TX LS filter
			reg->BB3C = 0x00000000;
			pltmp[4] = 0x00003F29; // 0x1040 11a TX LS filter
			pltmp[5] = 0x0EFEFBFE; // 0x1044 11a TX LS filter
			pltmp[6] = 0x002c2617; // 0x00453B24; // 0x1048 11b TX RC filter Modify for 33's 1.0.95
			pltmp[7] = 0x0800feff; // 0x0D00FDFF; // 0x104c 11b TX RC filter Modify for 33's 1.0.95
			pltmp[8] = 0x27106208; // 0x1050 MODE_Ctrl
			reg->BB50 = 0x27106208;
			pltmp[9] = 0; // 0x1054
			reg->BB54 = 0x00000000;
			pltmp[10] = 0x64644a4a; // 0x64646464; // 0x1058 IQ_Alpha Modify for 33's 1.0.95
			reg->BB58 = 0x64646464;
			pltmp[11] = 0xAA28C000; // 0x105c DC_Cancel
			Wb35Reg_BurstWrite( pHwData, 0x1030, pltmp, 12, AUTO_INCREMENT );

			Wb35Reg_Write( pHwData, 0x1070, 0x00000045 );
			break;

		case RF_AIROHA_2230:

			pltmp[0] = 0X16764A77; // 0x1000 AGC_Ctrl1		//0x16765A77
			pltmp[1] = 0x9affafb2; // 0x1004 AGC_Ctrl2
			pltmp[2] = 0x55d00a04; // 0x1008 AGC_Ctrl3
			pltmp[3] = 0xFFFd203c; // 0xFFFb203a; // 0x100c AGC_Ctrl4 Modify for 33's 1.0.95.xxx version
			reg->BB0C = 0xFFFd203c;
			pltmp[4] = 0X0FBFDCc5; // 0X0FBFDCA0; // 0x1010 AGC_Ctrl5 //0x0FB2E0B7 Modify for 33's 1.0.95.xxx version
			pltmp[5] = 0x00caa332; // 0x00caa333; // 0x1014 AGC_Ctrl6 Modify for 33's 1.0.95.xxx version
			pltmp[6] = 0XF6632111; // 0XF1632112; // 0x1018 AGC_Ctrl7		//0xf6632112 Modify for 33's 1.0.95.xxx version
			pltmp[7] = 0x0FA3F0ED; // 0x101c AGC_Ctrl8
			pltmp[8] = 0x04C43640; // 0x1020 AGC_Ctrl9
			pltmp[9] = 0x00002A79; // 0x1024 AGC_Ctrl10
			pltmp[10] = 0X40000528;							//0x40000228
			pltmp[11] = 0x232dfF30; // 0x232A9F30; // 0x102c A_ACQ_Ctrl	//0x232a9730
			reg->BB2C = 0x232dfF30; //Modify for 33's 1.0.95.xxx version, antenna 1
			Wb35Reg_BurstWrite( pHwData, 0x1000, pltmp, 12, AUTO_INCREMENT );

			pltmp[0] = 0x00002C54; // 0x1030 B_ACQ_Ctrl
			reg->BB30 = 0x00002C54;
			pltmp[1] = 0x00C0D6C5; // 0x1034 A_TXRX_Ctrl
			pltmp[2] = 0x5B2C8769; // 0x1038 B_TXRX_Ctrl	//0x5B6C8769
			pltmp[3] = 0x00000000; // 0x103c 11a TX LS filter
			reg->BB3C = 0x00000000;
			pltmp[4] = 0x00003F29; // 0x1040 11a TX LS filter
			pltmp[5] = 0x0EFEFBFE; // 0x1044 11a TX LS filter
			pltmp[6] = BB48_DEFAULT_AL2230_11G; // 0x1048 11b TX RC filter 20060613.2
			reg->BB48 = BB48_DEFAULT_AL2230_11G; // 20051221 ch14 20060613.2
			pltmp[7] = BB4C_DEFAULT_AL2230_11G; // 0x104c 11b TX RC filter 20060613.2
			reg->BB4C = BB4C_DEFAULT_AL2230_11G; // 20060613.1 20060613.2
			pltmp[8] = 0x27106200; // 0x1050 MODE_Ctrl
			reg->BB50 = 0x27106200;
			pltmp[9] = 0; // 0x1054
			reg->BB54 = 0x00000000;
			pltmp[10] = 0x52524242; // 0x1058 IQ_Alpha
			reg->BB58 = 0x52524242;
			pltmp[11] = 0xAA0AC000; // 0x105c DC_Cancel
			Wb35Reg_BurstWrite( pHwData, 0x1030, pltmp, 12, AUTO_INCREMENT );

			Wb35Reg_Write( pHwData, 0x1070, 0x00000045 );
			break;

		case RF_AIROHA_2230S: // 20060420 Add this

			pltmp[0] = 0X16764A77; // 0x1000 AGC_Ctrl1		//0x16765A77
			pltmp[1] = 0x9affafb2; // 0x1004 AGC_Ctrl2
			pltmp[2] = 0x55d00a04; // 0x1008 AGC_Ctrl3
			pltmp[3] = 0xFFFd203c; // 0xFFFb203a; // 0x100c AGC_Ctrl4 Modify for 33's 1.0.95.xxx version
			reg->BB0C = 0xFFFd203c;
			pltmp[4] = 0X0FBFDCc5; // 0X0FBFDCA0; // 0x1010 AGC_Ctrl5 //0x0FB2E0B7 Modify for 33's 1.0.95.xxx version
			pltmp[5] = 0x00caa332; // 0x00caa333; // 0x1014 AGC_Ctrl6 Modify for 33's 1.0.95.xxx version
			pltmp[6] = 0XF6632111; // 0XF1632112; // 0x1018 AGC_Ctrl7		//0xf6632112 Modify for 33's 1.0.95.xxx version
			pltmp[7] = 0x0FA3F0ED; // 0x101c AGC_Ctrl8
			pltmp[8] = 0x04C43640; // 0x1020 AGC_Ctrl9
			pltmp[9] = 0x00002A79; // 0x1024 AGC_Ctrl10
			pltmp[10] = 0X40000528;							//0x40000228
			pltmp[11] = 0x232dfF30; // 0x232A9F30; // 0x102c A_ACQ_Ctrl	//0x232a9730
			reg->BB2C = 0x232dfF30; //Modify for 33's 1.0.95.xxx version, antenna 1
			Wb35Reg_BurstWrite( pHwData, 0x1000, pltmp, 12, AUTO_INCREMENT );

			pltmp[0] = 0x00002C54; // 0x1030 B_ACQ_Ctrl
			reg->BB30 = 0x00002C54;
			pltmp[1] = 0x00C0D6C5; // 0x1034 A_TXRX_Ctrl
			pltmp[2] = 0x5B2C8769; // 0x1038 B_TXRX_Ctrl	//0x5B6C8769
			pltmp[3] = 0x00000000; // 0x103c 11a TX LS filter
			reg->BB3C = 0x00000000;
			pltmp[4] = 0x00003F29; // 0x1040 11a TX LS filter
			pltmp[5] = 0x0EFEFBFE; // 0x1044 11a TX LS filter
			pltmp[6] = BB48_DEFAULT_AL2230_11G; // 0x1048 11b TX RC filter 20060613.2
			reg->BB48 = BB48_DEFAULT_AL2230_11G; // 20051221 ch14 20060613.2
			pltmp[7] = BB4C_DEFAULT_AL2230_11G; // 0x104c 11b TX RC filter 20060613.2
			reg->BB4C = BB4C_DEFAULT_AL2230_11G; // 20060613.1
			pltmp[8] = 0x27106200; // 0x1050 MODE_Ctrl
			reg->BB50 = 0x27106200;
			pltmp[9] = 0; // 0x1054
			reg->BB54 = 0x00000000;
			pltmp[10] = 0x52523232; // 20060419 0x52524242; // 0x1058 IQ_Alpha
			reg->BB58 = 0x52523232; // 20060419 0x52524242;
			pltmp[11] = 0xAA0AC000; // 0x105c DC_Cancel
			Wb35Reg_BurstWrite( pHwData, 0x1030, pltmp, 12, AUTO_INCREMENT );

			Wb35Reg_Write( pHwData, 0x1070, 0x00000045 );
			break;

		case RF_AIROHA_7230:
/*
			pltmp[0] = 0x16a84a77; // 0x1000 AGC_Ctrl1
			pltmp[1] = 0x9affafb2; // 0x1004 AGC_Ctrl2
			pltmp[2] = 0x55d00a04; // 0x1008 AGC_Ctrl3
			pltmp[3] = 0xFFFb203a; // 0x100c AGC_Ctrl4
			reg->BB0c = 0xFFFb203a;
			pltmp[4] = 0x0FBFDCB7; // 0x1010 AGC_Ctrl5
			pltmp[5] = 0x00caa333; // 0x1014 AGC_Ctrl6
			pltmp[6] = 0xf6632112; // 0x1018 AGC_Ctrl7
			pltmp[7] = 0x0FA3F0ED; // 0x101c AGC_Ctrl8
			pltmp[8] = 0x04C43640; // 0x1020 AGC_Ctrl9
			pltmp[9] = 0x00002A79; // 0x1024 AGC_Ctrl10
			pltmp[10] = 0x40000228;
			pltmp[11] = 0x232A9F30;// 0x102c A_ACQ_Ctrl
			reg->BB2c = 0x232A9F30;
			Wb35Reg_BurstWrite( pHwData, 0x1000, pltmp, 12, AUTO_INCREMENT );

			pltmp[0] = 0x00002C54; // 0x1030 B_ACQ_Ctrl
			reg->BB30 = 0x00002C54;
			pltmp[1] = 0x00C0D6C5; // 0x1034 A_TXRX_Ctrl
			pltmp[2] = 0x5B2C8769; // 0x1038 B_TXRX_Ctrl
			pltmp[3] = 0x00000000; // 0x103c 11a TX LS filter
			reg->BB3c = 0x00000000;
			pltmp[4] = 0x00003F29; // 0x1040 11a TX LS filter
			pltmp[5] = 0x0EFEFBFE; // 0x1044 11a TX LS filter
			pltmp[6] = 0x00453B24; // 0x1048 11b TX RC filter
			pltmp[7] = 0x0E00FEFF; // 0x104c 11b TX RC filter
			pltmp[8] = 0x27106200; // 0x1050 MODE_Ctrl
			reg->BB50 = 0x27106200;
			pltmp[9] = 0; // 0x1054
			reg->BB54 = 0x00000000;
			pltmp[10] = 0x64645252; // 0x1058 IQ_Alpha
			reg->BB58 = 0x64645252;
			pltmp[11] = 0xAA0AC000; // 0x105c DC_Cancel
			Wb35Reg_BurstWrite( pHwData, 0x1030, pltmp, 12, AUTO_INCREMENT );
*/
			BBProcessor_AL7230_2400( pHwData );

			Wb35Reg_Write( pHwData, 0x1070, 0x00000045 );
			break;

		case RF_WB_242:
		case RF_WB_242_1: // 20060619.5 Add

			pltmp[0] = 0x16A8525D; // 0x1000 AGC_Ctrl1
			pltmp[1] = 0x9AFF9ABA; // 0x1004 AGC_Ctrl2
			pltmp[2] = 0x55D00A04; // 0x1008 AGC_Ctrl3
			pltmp[3] = 0xEEE91C32; // 0x100c AGC_Ctrl4
			reg->BB0C = 0xEEE91C32;
			pltmp[4] = 0x0FACDCC5; // 0x1010 AGC_Ctrl5
			pltmp[5] = 0x000AA344; // 0x1014 AGC_Ctrl6
			pltmp[6] = 0x22222221; // 0x1018 AGC_Ctrl7
			pltmp[7] = 0x0FA3F0ED; // 0x101c AGC_Ctrl8
			pltmp[8] = 0x04CC3440; // 20051018 0x03CB3440; // 0x1020 AGC_Ctrl9 20051014 0x03C33440
			pltmp[9] = 0xA9002A79; // 0x1024 AGC_Ctrl10
			pltmp[10] = 0x40000528; // 0x1028
			pltmp[11] = 0x23457F30; // 0x102c A_ACQ_Ctrl
			reg->BB2C = 0x23457F30;
			Wb35Reg_BurstWrite( pHwData, 0x1000, pltmp, 12, AUTO_INCREMENT );

			pltmp[0] = 0x00002C54; // 0x1030 B_ACQ_Ctrl
			reg->BB30 = 0x00002C54;
			pltmp[1] = 0x00C0D6C5; // 0x1034 A_TXRX_Ctrl
			pltmp[2] = 0x5B2C8769; // 0x1038 B_TXRX_Ctrl
			pltmp[3] = pHwData->BB3c_cal; // 0x103c 11a TX LS filter
			reg->BB3C = pHwData->BB3c_cal;
			pltmp[4] = 0x00003F29; // 0x1040 11a TX LS filter
			pltmp[5] = 0x0EFEFBFE; // 0x1044 11a TX LS filter
			pltmp[6] = BB48_DEFAULT_WB242_11G; // 0x1048 11b TX RC filter 20060613.2
			reg->BB48 = BB48_DEFAULT_WB242_11G; // 20060613.1 20060613.2
			pltmp[7] = BB4C_DEFAULT_WB242_11G; // 0x104c 11b TX RC filter 20060613.2
			reg->BB4C = BB4C_DEFAULT_WB242_11G; // 20060613.1 20060613.2
			pltmp[8] = 0x27106208; // 0x1050 MODE_Ctrl
			reg->BB50 = 0x27106208;
			pltmp[9] = pHwData->BB54_cal; // 0x1054
			reg->BB54 = pHwData->BB54_cal;
			pltmp[10] = 0x52523131; // 0x1058 IQ_Alpha
			reg->BB58 = 0x52523131;
			pltmp[11] = 0xAA0AC000; // 20060825 0xAA2AC000; // 0x105c DC_Cancel
			Wb35Reg_BurstWrite( pHwData, 0x1030, pltmp, 12, AUTO_INCREMENT );

			Wb35Reg_Write( pHwData, 0x1070, 0x00000045 );
			break;
    }

	// Fill the LNA table
	reg->LNAValue[0] = (u8)(reg->BB0C & 0xff);
	reg->LNAValue[1] = 0;
	reg->LNAValue[2] = (u8)((reg->BB0C & 0xff00)>>8);
	reg->LNAValue[3] = 0;

	// Fill SQ3 table
	for( i=0; i<MAX_SQ3_FILTER_SIZE; i++ )
		reg->SQ3_filter[i] = 0x2f; // half of Bit 0 ~ 6
}

void set_tx_power_per_channel_max2829(  struct hw_data * pHwData,  ChanInfo Channel)
{
	RFSynthesizer_SetPowerIndex( pHwData, 100 ); // 20060620.1 Modify
}

void set_tx_power_per_channel_al2230(  struct hw_data * pHwData,  ChanInfo Channel )
{
	u8	index = 100;

	if (pHwData->TxVgaFor24[Channel.ChanNo - 1] != 0xff) // 20060620.1 Add
		index = pHwData->TxVgaFor24[Channel.ChanNo - 1];

	RFSynthesizer_SetPowerIndex( pHwData, index );
}

void set_tx_power_per_channel_al7230(  struct hw_data * pHwData,  ChanInfo Channel)
{
	u8	i, index = 100;

	switch ( Channel.band )
	{
		case BAND_TYPE_DSSS:
		case BAND_TYPE_OFDM_24:
			{
				if (pHwData->TxVgaFor24[Channel.ChanNo - 1] != 0xff)
					index = pHwData->TxVgaFor24[Channel.ChanNo - 1];
			}
			break;
		case BAND_TYPE_OFDM_5:
			{
				for (i =0; i<35; i++)
				{
					if (Channel.ChanNo == pHwData->TxVgaFor50[i].ChanNo)
					{
						if (pHwData->TxVgaFor50[i].TxVgaValue != 0xff)
							index = pHwData->TxVgaFor50[i].TxVgaValue;
						break;
					}
				}
			}
			break;
	}
	RFSynthesizer_SetPowerIndex( pHwData, index );
}

void set_tx_power_per_channel_wb242(  struct hw_data * pHwData,  ChanInfo Channel)
{
	u8	index = 100;

	switch ( Channel.band )
	{
		case BAND_TYPE_DSSS:
		case BAND_TYPE_OFDM_24:
			{
				if (pHwData->TxVgaFor24[Channel.ChanNo - 1] != 0xff)
					index = pHwData->TxVgaFor24[Channel.ChanNo - 1];
			}
			break;
		case BAND_TYPE_OFDM_5:
			break;
	}
	RFSynthesizer_SetPowerIndex( pHwData, index );
}

//=============================================================================================================
// RFSynthesizer_SwitchingChannel --
//
// Description:
//   Swithch the RF channel.
//
// Arguments:
//   pHwData    - Handle of the USB Device.
//   Channel    - The channel no.
//
// Return values:
//   None.
//=============================================================================================================
void
RFSynthesizer_SwitchingChannel(  struct hw_data * pHwData,  ChanInfo Channel )
{
	struct wb35_reg *reg = &pHwData->reg;
	u32	pltmp[16]; // The 16 is the maximum capability of hardware
	u32	count, ltmp;
	u8	i, j, number;
	u8	ChnlTmp;

	switch( pHwData->phy_type )
	{
		case RF_MAXIM_2825:
		case RF_MAXIM_V1: // 11g Winbond 2nd BB(with Phy board (v1) + Maxim 331)

			if( Channel.band <= BAND_TYPE_OFDM_24 ) // channel 1 ~ 13
			{
				for( i=0; i<3; i++ )
					pltmp[i] = (1 << 31) | (0 << 30) | (18 << 24) | BitReverse( max2825_channel_data_24[Channel.ChanNo-1][i], 18);
				Wb35Reg_BurstWrite( pHwData, 0x0864, pltmp, 3, NO_INCREMENT );
			}
			RFSynthesizer_SetPowerIndex( pHwData, 100 );
			break;

		case RF_MAXIM_2827:

			if( Channel.band <= BAND_TYPE_OFDM_24 ) // channel 1 ~ 13
			{
				for( i=0; i<3; i++ )
					pltmp[i] = (1 << 31) | (0 << 30) | (18 << 24) | BitReverse( max2827_channel_data_24[Channel.ChanNo-1][i], 18);
				Wb35Reg_BurstWrite( pHwData, 0x0864, pltmp, 3, NO_INCREMENT );
			}
			else if( Channel.band == BAND_TYPE_OFDM_5 ) // channel 36 ~ 64
			{
				ChnlTmp = (Channel.ChanNo - 36) / 4;
				for( i=0; i<3; i++ )
					pltmp[i] = (1 << 31) | (0 << 30) | (18 << 24) | BitReverse( max2827_channel_data_50[ChnlTmp][i], 18);
				Wb35Reg_BurstWrite( pHwData, 0x0864, pltmp, 3, NO_INCREMENT );
			}
			RFSynthesizer_SetPowerIndex( pHwData, 100 );
			break;

		case RF_MAXIM_2828:

			if( Channel.band <= BAND_TYPE_OFDM_24 ) // channel 1 ~ 13
			{
				for( i=0; i<3; i++ )
					pltmp[i] = (1 << 31) | (0 << 30) | (18 << 24) | BitReverse( max2828_channel_data_24[Channel.ChanNo-1][i], 18);
				Wb35Reg_BurstWrite( pHwData, 0x0864, pltmp, 3, NO_INCREMENT );
			}
			else if( Channel.band == BAND_TYPE_OFDM_5 ) // channel 36 ~ 64
			{
				ChnlTmp = (Channel.ChanNo - 36) / 4;
				for ( i = 0; i < 3; i++)
					pltmp[i] = (1 << 31) | (0 << 30) | (18 << 24) | BitReverse( max2828_channel_data_50[ChnlTmp][i], 18);
				Wb35Reg_BurstWrite( pHwData, 0x0864, pltmp, 3, NO_INCREMENT );
			}
			RFSynthesizer_SetPowerIndex( pHwData, 100 );
			break;

		case RF_MAXIM_2829:

			if( Channel.band <= BAND_TYPE_OFDM_24)
			{
				for( i=0; i<3; i++ )
					pltmp[i] = (1 << 31) | (0 << 30) | (18 << 24) | BitReverse( max2829_channel_data_24[Channel.ChanNo-1][i], 18);
				Wb35Reg_BurstWrite( pHwData, 0x0864, pltmp, 3, NO_INCREMENT );
			}
			else if( Channel.band == BAND_TYPE_OFDM_5 )
			{
				count = sizeof(max2829_channel_data_50) / sizeof(max2829_channel_data_50[0]);

				for( i=0; i<count; i++ )
				{
					if( max2829_channel_data_50[i][0] == Channel.ChanNo )
					{
						for( j=0; j<3; j++ )
							pltmp[j] = (1 << 31) | (0 << 30) | (18 << 24) | BitReverse( max2829_channel_data_50[i][j+1], 18);
						Wb35Reg_BurstWrite( pHwData, 0x0864, pltmp, 3, NO_INCREMENT );

						if( (max2829_channel_data_50[i][3] & 0x3FFFF) == 0x2A946 )
						{
							ltmp = (1 << 31) | (0 << 30) | (18 << 24) | BitReverse( (5<<18)|0x2A906, 18);
							Wb35Reg_Write( pHwData, 0x0864, ltmp );
						}
						else    // 0x2A9C6
						{
							ltmp = (1 << 31) | (0 << 30) | (18 << 24) | BitReverse( (5<<18)|0x2A986, 18);
							Wb35Reg_Write( pHwData, 0x0864, ltmp );
						}
					}
				}
			}
			set_tx_power_per_channel_max2829( pHwData, Channel );
			break;

		case RF_AIROHA_2230:
		case RF_AIROHA_2230S: // 20060420 Add this

			if( Channel.band <= BAND_TYPE_OFDM_24 ) // channel 1 ~ 14
			{
				for( i=0; i<2; i++ )
					pltmp[i] = (1 << 31) | (0 << 30) | (20 << 24) | BitReverse( al2230_channel_data_24[Channel.ChanNo-1][i], 20);
				Wb35Reg_BurstWrite( pHwData, 0x0864, pltmp, 2, NO_INCREMENT );
			}
			set_tx_power_per_channel_al2230( pHwData, Channel );
			break;

		case RF_AIROHA_7230:

			//Start to fill RF parameters, PLL_ON should be pulled low.
			//Wb35Reg_Write( pHwData, 0x03dc, 0x00000000 );
			//printk("* PLL_ON    low\n");

			//Channel independent registers
			if( Channel.band != pHwData->band)
			{
				if (Channel.band <= BAND_TYPE_OFDM_24)
				{
					//Update BB register
					BBProcessor_AL7230_2400(pHwData);

					number = sizeof(al7230_rf_data_24)/sizeof(al7230_rf_data_24[0]);
					Set_ChanIndep_RfData_al7230_24(pHwData, pltmp, number);
				}
				else
				{
					//Update BB register
					BBProcessor_AL7230_5000(pHwData);

					number = sizeof(al7230_rf_data_50)/sizeof(al7230_rf_data_50[0]);
					Set_ChanIndep_RfData_al7230_50(pHwData, pltmp, number);
				}

				// Write to register. number must less and equal than 16
				Wb35Reg_BurstWrite( pHwData, 0x0864, pltmp, number, NO_INCREMENT );
				#ifdef _PE_STATE_DUMP_
				printk("Band changed\n");
				#endif
			}

			if( Channel.band <= BAND_TYPE_OFDM_24 ) // channel 1 ~ 14
			{
				for( i=0; i<2; i++ )
					pltmp[i] = (1 << 31) | (0 << 30) | (24 << 24) | (al7230_channel_data_24[Channel.ChanNo-1][i]&0xffffff);
				Wb35Reg_BurstWrite( pHwData, 0x0864, pltmp, 2, NO_INCREMENT );
			}
			else if( Channel.band == BAND_TYPE_OFDM_5 )
			{
				//Update Reg12
				if ((Channel.ChanNo > 64) && (Channel.ChanNo <= 165))
				{
					ltmp = (1 << 31) | (0 << 30) | (24 << 24) | 0x00143c;
					Wb35Reg_Write( pHwData, 0x0864, ltmp );
				}
				else	//reg12 = 0x00147c at Channel 4920 ~ 5320
				{
					ltmp = (1 << 31) | (0 << 30) | (24 << 24) | 0x00147c;
					Wb35Reg_Write( pHwData, 0x0864, ltmp );
				}

				count = sizeof(al7230_channel_data_5) / sizeof(al7230_channel_data_5[0]);

				for (i=0; i<count; i++)
				{
					if (al7230_channel_data_5[i][0] == Channel.ChanNo)
					{
						for( j=0; j<3; j++ )
							pltmp[j] = (1 << 31) | (0 << 30) | (24 << 24) | ( al7230_channel_data_5[i][j+1]&0xffffff);
						Wb35Reg_BurstWrite( pHwData, 0x0864, pltmp, 3, NO_INCREMENT );
					}
				}
			}
			set_tx_power_per_channel_al7230(pHwData, Channel);
			break;

		case RF_WB_242:
		case RF_WB_242_1: // 20060619.5 Add

			if( Channel.band <= BAND_TYPE_OFDM_24 ) // channel 1 ~ 14
			{
				ltmp = (1 << 31) | (0 << 30) | (24 << 24) | BitReverse( w89rf242_channel_data_24[Channel.ChanNo-1][0], 24);
				Wb35Reg_Write( pHwData, 0x864, ltmp );
			}
			set_tx_power_per_channel_wb242(pHwData, Channel);
			break;
	}

	if( Channel.band <= BAND_TYPE_OFDM_24 )
	{
        // BB: select 2.4 GHz, bit[12-11]=00
		reg->BB50 &= ~(BIT(11)|BIT(12));
		Wb35Reg_Write( pHwData, 0x1050, reg->BB50 ); // MODE_Ctrl
        // MAC: select 2.4 GHz, bit[5]=0
		reg->M78_ERPInformation &= ~BIT(5);
		Wb35Reg_Write( pHwData, 0x0878, reg->M78_ERPInformation );
        // enable 11b Baseband
		reg->BB30 &= ~BIT(31);
		Wb35Reg_Write( pHwData, 0x1030, reg->BB30 );
	}
	else if( (Channel.band == BAND_TYPE_OFDM_5) )
	{
        // BB: select 5 GHz
		reg->BB50 &= ~(BIT(11)|BIT(12));
		if (Channel.ChanNo <=64 )
			reg->BB50 |= BIT(12);				// 10-5.25GHz
		else if ((Channel.ChanNo >= 100) && (Channel.ChanNo <= 124))
			reg->BB50 |= BIT(11);				// 01-5.48GHz
		else if ((Channel.ChanNo >=128) && (Channel.ChanNo <= 161))
			reg->BB50 |= (BIT(12)|BIT(11));	// 11-5.775GHz
		else	//Chan 184 ~ 196 will use bit[12-11] = 10 in version sh-src-1.2.25
			reg->BB50 |= BIT(12);
		Wb35Reg_Write( pHwData, 0x1050, reg->BB50 ); // MODE_Ctrl

		//(1) M78 should alway use 2.4G setting when using RF_AIROHA_7230
		//(2) BB30 has been updated previously.
		if (pHwData->phy_type != RF_AIROHA_7230)
		{
    	    // MAC: select 5 GHz, bit[5]=1
			reg->M78_ERPInformation |= BIT(5);
			Wb35Reg_Write( pHwData, 0x0878, reg->M78_ERPInformation );

    	    // disable 11b Baseband
			reg->BB30 |= BIT(31);
			Wb35Reg_Write( pHwData, 0x1030, reg->BB30 );
		}
	}
}

//Set the tx power directly from DUT GUI, not from the EEPROM. Return the current setting
u8 RFSynthesizer_SetPowerIndex(  struct hw_data * pHwData,  u8 PowerIndex )
{
	u32	Band = pHwData->band;
	u8	index=0;

	if( pHwData->power_index == PowerIndex ) // 20060620.1 Add
		return PowerIndex;

	if (RF_MAXIM_2825 == pHwData->phy_type)
	{
		// Channel 1 - 13
		index = RFSynthesizer_SetMaxim2825Power( pHwData, PowerIndex );
	}
	else if (RF_MAXIM_2827 == pHwData->phy_type)
	{
		if( Band <= BAND_TYPE_OFDM_24 )    // Channel 1 - 13
			index = RFSynthesizer_SetMaxim2827_24Power( pHwData, PowerIndex );
		else// if( Band == BAND_TYPE_OFDM_5 )  // Channel 36 - 64
			index = RFSynthesizer_SetMaxim2827_50Power( pHwData, PowerIndex );
	}
	else if (RF_MAXIM_2828 == pHwData->phy_type)
	{
		if( Band <= BAND_TYPE_OFDM_24 )    // Channel 1 - 13
			index = RFSynthesizer_SetMaxim2828_24Power( pHwData, PowerIndex );
		else// if( Band == BAND_TYPE_OFDM_5 )  // Channel 36 - 64
			index = RFSynthesizer_SetMaxim2828_50Power( pHwData, PowerIndex );
	}
	else if( RF_AIROHA_2230 == pHwData->phy_type )
	{
		//Power index: 0 ~ 63 // Channel 1 - 14
		index = RFSynthesizer_SetAiroha2230Power( pHwData, PowerIndex );
		index = (u8)al2230_txvga_data[index][1];
	}
	else if( RF_AIROHA_2230S == pHwData->phy_type ) // 20060420 Add this
	{
		//Power index: 0 ~ 63 // Channel 1 - 14
		index = RFSynthesizer_SetAiroha2230Power( pHwData, PowerIndex );
		index = (u8)al2230_txvga_data[index][1];
	}
	else if( RF_AIROHA_7230 == pHwData->phy_type )
	{
		//Power index: 0 ~ 63
		index = RFSynthesizer_SetAiroha7230Power( pHwData, PowerIndex );
		index = (u8)al7230_txvga_data[index][1];
	}
	else if( (RF_WB_242 == pHwData->phy_type) ||
		 (RF_WB_242_1 == pHwData->phy_type) ) // 20060619.5 Add
	{
		//Power index: 0 ~ 19 for original. New range is 0 ~ 33
		index = RFSynthesizer_SetWinbond242Power( pHwData, PowerIndex );
		index = (u8)w89rf242_txvga_data[index][1];
	}

	pHwData->power_index = index;  // Backup current
	return index;
}

//-- Sub function
u8 RFSynthesizer_SetMaxim2828_24Power(  struct hw_data * pHwData, u8 index )
{
	u32		PowerData;
	if( index > 1 ) index = 1;
	PowerData = (1 << 31) | (0 << 30) | (18 << 24) | BitReverse( max2828_power_data_24[index], 18);
	Wb35Reg_Write( pHwData, 0x0864, PowerData );
	return index;
}
//--
u8 RFSynthesizer_SetMaxim2828_50Power(  struct hw_data * pHwData, u8 index )
{
	u32		PowerData;
	if( index > 1 ) index = 1;
	PowerData = (1 << 31) | (0 << 30) | (18 << 24) | BitReverse( max2828_power_data_50[index], 18);
	Wb35Reg_Write( pHwData, 0x0864, PowerData );
	return index;
}
//--
u8 RFSynthesizer_SetMaxim2827_24Power(  struct hw_data * pHwData, u8 index )
{
	u32		PowerData;
	if( index > 1 ) index = 1;
	PowerData = (1 << 31) | (0 << 30) | (18 << 24) | BitReverse( max2827_power_data_24[index], 18);
	Wb35Reg_Write( pHwData, 0x0864, PowerData );
	return index;
}
//--
u8 RFSynthesizer_SetMaxim2827_50Power(  struct hw_data * pHwData, u8 index )
{
	u32		PowerData;
	if( index > 1 ) index = 1;
	PowerData = (1 << 31) | (0 << 30) | (18 << 24) | BitReverse( max2827_power_data_50[index], 18);
	Wb35Reg_Write( pHwData, 0x0864, PowerData );
	return index;
}
//--
u8 RFSynthesizer_SetMaxim2825Power(  struct hw_data * pHwData, u8 index )
{
	u32		PowerData;
	if( index > 1 ) index = 1;
	PowerData = (1 << 31) | (0 << 30) | (18 << 24) | BitReverse( max2825_power_data_24[index], 18);
	Wb35Reg_Write( pHwData, 0x0864, PowerData );
	return index;
}
//--
u8 RFSynthesizer_SetAiroha2230Power(  struct hw_data * pHwData, u8 index )
{
	u32		PowerData;
	u8		i,count;

	count = sizeof(al2230_txvga_data) / sizeof(al2230_txvga_data[0]);
	for (i=0; i<count; i++)
	{
		if (al2230_txvga_data[i][1] >= index)
			break;
	}
	if (i == count)
		i--;

	PowerData = (1 << 31) | (0 << 30) | (20 << 24) | BitReverse( al2230_txvga_data[i][0], 20);
	Wb35Reg_Write( pHwData, 0x0864, PowerData );
	return i;
}
//--
u8 RFSynthesizer_SetAiroha7230Power(  struct hw_data * pHwData, u8 index )
{
	u32		PowerData;
	u8		i,count;

	//PowerData = (1 << 31) | (0 << 30) | (20 << 24) | BitReverse( airoha_power_data_24[index], 20);
	count = sizeof(al7230_txvga_data) / sizeof(al7230_txvga_data[0]);
	for (i=0; i<count; i++)
	{
		if (al7230_txvga_data[i][1] >= index)
			break;
	}
	if (i == count)
		i--;
	PowerData = (1 << 31) | (0 << 30) | (24 << 24) | (al7230_txvga_data[i][0]&0xffffff);
	Wb35Reg_Write( pHwData, 0x0864, PowerData );
	return i;
}

u8 RFSynthesizer_SetWinbond242Power(  struct hw_data * pHwData, u8 index )
{
	u32		PowerData;
	u8		i,count;

	count = sizeof(w89rf242_txvga_data) / sizeof(w89rf242_txvga_data[0]);
	for (i=0; i<count; i++)
	{
		if (w89rf242_txvga_data[i][1] >= index)
			break;
	}
	if (i == count)
		i--;

	// Set TxVga into RF
	PowerData = (1 << 31) | (0 << 30) | (24 << 24) | BitReverse( w89rf242_txvga_data[i][0], 24);
	Wb35Reg_Write( pHwData, 0x0864, PowerData );

	// Update BB48 BB4C BB58 for high precision txvga
	Wb35Reg_Write( pHwData, 0x1048, w89rf242_txvga_data[i][2] );
	Wb35Reg_Write( pHwData, 0x104c, w89rf242_txvga_data[i][3] );
	Wb35Reg_Write( pHwData, 0x1058, w89rf242_txvga_data[i][4] );

// Rf vga 0 ~ 3 for temperature compensate. It will affect the scan Bss.
// The i value equals to 8 or 7 usually. So It's not necessary to setup this RF register.
//	if( i <= 3 )
//		PowerData = (1 << 31) | (0 << 30) | (24 << 24) | BitReverse( 0x000024, 24 );
//	else
//		PowerData = (1 << 31) | (0 << 30) | (24 << 24) | BitReverse( 0x001824, 24 );
//	Wb35Reg_Write( pHwData, 0x0864, PowerData );
	return i;
}

//===========================================================================================================
// Dxx_initial --
// Mxx_initial --
	//
//  Routine Description:
//		Initial the hardware setting and module variable
	//
//===========================================================================================================
void Dxx_initial(  struct hw_data * pHwData )
{
	struct wb35_reg *reg = &pHwData->reg;

	// Old IC:Single mode only.
	// New IC: operation decide by Software set bit[4]. 1:multiple 0: single
	reg->D00_DmaControl = 0xc0000004;	//Txon, Rxon, multiple Rx for new 4k DMA
											//Txon, Rxon, single Rx for old 8k ASIC
	if( !HAL_USB_MODE_BURST( pHwData ) )
		reg->D00_DmaControl = 0xc0000000;//Txon, Rxon, single Rx for new 4k DMA

	Wb35Reg_WriteSync( pHwData, 0x0400, reg->D00_DmaControl );
}

void Mxx_initial(  struct hw_data * pHwData )
{
	struct wb35_reg *reg = &pHwData->reg;
	u32		tmp;
	u32		pltmp[11];
	u16	i;


	//======================================================
	// Initial Mxx register
	//======================================================

	// M00 bit set
#ifdef _IBSS_BEACON_SEQ_STICK_
	reg->M00_MacControl = 0; // Solve beacon sequence number stop by software
#else
	reg->M00_MacControl = 0x80000000; // Solve beacon sequence number stop by hardware
#endif

	// M24 disable enter power save, BB RxOn and enable NAV attack
	reg->M24_MacControl = 0x08040042;
	pltmp[0] = reg->M24_MacControl;

	pltmp[1] = 0; // Skip M28, because no initialize value is required.

	// M2C CWmin and CWmax setting
	pHwData->cwmin = DEFAULT_CWMIN;
	pHwData->cwmax = DEFAULT_CWMAX;
	reg->M2C_MacControl = DEFAULT_CWMIN << 10;
	reg->M2C_MacControl |= DEFAULT_CWMAX;
	pltmp[2] = reg->M2C_MacControl;

	// M30 BSSID
	pltmp[3] = *(u32 *)pHwData->bssid;

	// M34
	pHwData->AID = DEFAULT_AID;
	tmp = *(u16 *)(pHwData->bssid+4);
	tmp |= DEFAULT_AID << 16;
	pltmp[4] = tmp;

	// M38
	reg->M38_MacControl = (DEFAULT_RATE_RETRY_LIMIT<<8) | (DEFAULT_LONG_RETRY_LIMIT << 4) | DEFAULT_SHORT_RETRY_LIMIT;
	pltmp[5] = reg->M38_MacControl;

	// M3C
	tmp = (DEFAULT_PIFST << 26) | (DEFAULT_EIFST << 16) | (DEFAULT_DIFST << 8) | (DEFAULT_SIFST << 4) | DEFAULT_OSIFST ;
	reg->M3C_MacControl = tmp;
	pltmp[6] = tmp;

	// M40
	pHwData->slot_time_select = DEFAULT_SLOT_TIME;
	tmp = (DEFAULT_ATIMWD << 16) | DEFAULT_SLOT_TIME;
	reg->M40_MacControl = tmp;
	pltmp[7] = tmp;

	// M44
	tmp = DEFAULT_MAX_TX_MSDU_LIFE_TIME << 10; // *1024
	reg->M44_MacControl = tmp;
	pltmp[8] = tmp;

	// M48
	pHwData->BeaconPeriod = DEFAULT_BEACON_INTERVAL;
	pHwData->ProbeDelay = DEFAULT_PROBE_DELAY_TIME;
	tmp = (DEFAULT_BEACON_INTERVAL << 16) | DEFAULT_PROBE_DELAY_TIME;
	reg->M48_MacControl = tmp;
	pltmp[9] = tmp;

	//M4C
	reg->M4C_MacStatus = (DEFAULT_PROTOCOL_VERSION << 30) | (DEFAULT_MAC_POWER_STATE << 28) | (DEFAULT_DTIM_ALERT_TIME << 24);
	pltmp[10] = reg->M4C_MacStatus;

	// Burst write
	//Wb35Reg_BurstWrite( pHwData, 0x0824, pltmp, 11, AUTO_INCREMENT );
	for( i=0; i<11; i++ )
		Wb35Reg_WriteSync( pHwData, 0x0824 + i*4, pltmp[i] );

	// M60
	Wb35Reg_WriteSync( pHwData, 0x0860, 0x12481248 );
	reg->M60_MacControl = 0x12481248;

	// M68
	Wb35Reg_WriteSync( pHwData, 0x0868, 0x00050900 ); // 20051018 0x000F0F00 ); // 940930 0x00131300
	reg->M68_MacControl = 0x00050900;

	// M98
	Wb35Reg_WriteSync( pHwData, 0x0898, 0xffff8888 );
	reg->M98_MacControl = 0xffff8888;
}


void Uxx_power_off_procedure(  struct hw_data * pHwData )
{
	// SW, PMU reset and turn off clock
	Wb35Reg_WriteSync( pHwData, 0x03b0, 3 );
	Wb35Reg_WriteSync( pHwData, 0x03f0, 0xf9 );
}

//Decide the TxVga of every channel
void GetTxVgaFromEEPROM(  struct hw_data * pHwData )
{
	u32		i, j, ltmp;
	u16		Value[MAX_TXVGA_EEPROM];
	u8		*pctmp;
	u8		ctmp=0;

	// Get the entire TxVga setting in EEPROM
	for( i=0; i<MAX_TXVGA_EEPROM; i++ )
	{
		Wb35Reg_WriteSync( pHwData, 0x03b4, 0x08100000 + 0x00010000*i );
		Wb35Reg_ReadSync( pHwData, 0x03b4, &ltmp );
		Value[i] = (u16)( ltmp & 0xffff ); // Get 16 bit available
		Value[i] = cpu_to_le16( Value[i] ); // [7:0]2412 [7:0]2417 ....
	}

	// Adjust the filed which fills with reserved value.
	pctmp = (u8 *)Value;
	for( i=0; i<(MAX_TXVGA_EEPROM*2); i++ )
	{
		if( pctmp[i] != 0xff )
			ctmp = pctmp[i];
		else
			pctmp[i] = ctmp;
	}

	// Adjust WB_242 to WB_242_1 TxVga scale
	if( pHwData->phy_type == RF_WB_242 )
	{
		for( i=0; i<4; i++ ) // Only 2412 2437 2462 2484 case must be modified
		{
			for( j=0; j<(sizeof(w89rf242_txvga_old_mapping)/sizeof(w89rf242_txvga_old_mapping[0])); j++ )
			{
				if( pctmp[i] < (u8)w89rf242_txvga_old_mapping[j][1] )
				{
					pctmp[i] = (u8)w89rf242_txvga_old_mapping[j][0];
					break;
				}
			}

			if( j == (sizeof(w89rf242_txvga_old_mapping)/sizeof(w89rf242_txvga_old_mapping[0])) )
				pctmp[i] = (u8)w89rf242_txvga_old_mapping[j-1][0];
		}
	}

	// 20060621 Add
	memcpy( pHwData->TxVgaSettingInEEPROM, pctmp, MAX_TXVGA_EEPROM*2 ); //MAX_TXVGA_EEPROM is u16 count
	EEPROMTxVgaAdjust( pHwData );
}

// This function will affect the TxVga parameter in HAL. If hal_set_current_channel
// or RFSynthesizer_SetPowerIndex be called, new TxVga will take effect.
// TxVgaSettingInEEPROM of sHwData is an u8 array point to EEPROM contain for IS89C35
// This function will use default TxVgaSettingInEEPROM data to calculate new TxVga.
void EEPROMTxVgaAdjust(  struct hw_data * pHwData ) // 20060619.5 Add
{
	u8	*	pTxVga = pHwData->TxVgaSettingInEEPROM;
	s16		i, stmp;

	//-- 2.4G -- 20060704.2 Request from Tiger
	//channel 1 ~ 5
	stmp = pTxVga[1] - pTxVga[0];
	for( i=0; i<5; i++ )
		pHwData->TxVgaFor24[i] = pTxVga[0] + stmp*i/4;
	//channel 6 ~ 10
	stmp = pTxVga[2] - pTxVga[1];
	for( i=5; i<10; i++ )
		pHwData->TxVgaFor24[i] = pTxVga[1] + stmp*(i-5)/4;
	//channel 11 ~ 13
	stmp = pTxVga[3] - pTxVga[2];
	for( i=10; i<13; i++ )
		pHwData->TxVgaFor24[i] = pTxVga[2] + stmp*(i-10)/2;
	//channel 14
	pHwData->TxVgaFor24[13] = pTxVga[3];

	//-- 5G --
	if( pHwData->phy_type == RF_AIROHA_7230 )
	{
		//channel 184
		pHwData->TxVgaFor50[0].ChanNo = 184;
		pHwData->TxVgaFor50[0].TxVgaValue = pTxVga[4];
		//channel 196
		pHwData->TxVgaFor50[3].ChanNo = 196;
		pHwData->TxVgaFor50[3].TxVgaValue = pTxVga[5];
		//interpolate
		pHwData->TxVgaFor50[1].ChanNo = 188;
		pHwData->TxVgaFor50[2].ChanNo = 192;
		stmp = pTxVga[5] - pTxVga[4];
		pHwData->TxVgaFor50[2].TxVgaValue = pTxVga[5] - stmp/3;
		pHwData->TxVgaFor50[1].TxVgaValue = pTxVga[5] - stmp*2/3;

		//channel 16
		pHwData->TxVgaFor50[6].ChanNo = 16;
		pHwData->TxVgaFor50[6].TxVgaValue = pTxVga[6];
		pHwData->TxVgaFor50[4].ChanNo = 8;
		pHwData->TxVgaFor50[4].TxVgaValue = pTxVga[6];
		pHwData->TxVgaFor50[5].ChanNo = 12;
		pHwData->TxVgaFor50[5].TxVgaValue = pTxVga[6];

		//channel 36
		pHwData->TxVgaFor50[8].ChanNo = 36;
		pHwData->TxVgaFor50[8].TxVgaValue = pTxVga[7];
		pHwData->TxVgaFor50[7].ChanNo = 34;
		pHwData->TxVgaFor50[7].TxVgaValue = pTxVga[7];
		pHwData->TxVgaFor50[9].ChanNo = 38;
		pHwData->TxVgaFor50[9].TxVgaValue = pTxVga[7];

		//channel 40
		pHwData->TxVgaFor50[10].ChanNo = 40;
		pHwData->TxVgaFor50[10].TxVgaValue = pTxVga[8];
		//channel 48
		pHwData->TxVgaFor50[14].ChanNo = 48;
		pHwData->TxVgaFor50[14].TxVgaValue = pTxVga[9];
		//interpolate
		pHwData->TxVgaFor50[11].ChanNo = 42;
		pHwData->TxVgaFor50[12].ChanNo = 44;
		pHwData->TxVgaFor50[13].ChanNo = 46;
		stmp = pTxVga[9] - pTxVga[8];
		pHwData->TxVgaFor50[13].TxVgaValue = pTxVga[9] - stmp/4;
		pHwData->TxVgaFor50[12].TxVgaValue = pTxVga[9] - stmp*2/4;
		pHwData->TxVgaFor50[11].TxVgaValue = pTxVga[9] - stmp*3/4;

		//channel 52
		pHwData->TxVgaFor50[15].ChanNo = 52;
		pHwData->TxVgaFor50[15].TxVgaValue = pTxVga[10];
		//channel 64
		pHwData->TxVgaFor50[18].ChanNo = 64;
		pHwData->TxVgaFor50[18].TxVgaValue = pTxVga[11];
		//interpolate
		pHwData->TxVgaFor50[16].ChanNo = 56;
		pHwData->TxVgaFor50[17].ChanNo = 60;
		stmp = pTxVga[11] - pTxVga[10];
		pHwData->TxVgaFor50[17].TxVgaValue = pTxVga[11] - stmp/3;
		pHwData->TxVgaFor50[16].TxVgaValue = pTxVga[11] - stmp*2/3;

		//channel 100
		pHwData->TxVgaFor50[19].ChanNo = 100;
		pHwData->TxVgaFor50[19].TxVgaValue = pTxVga[12];
		//channel 112
		pHwData->TxVgaFor50[22].ChanNo = 112;
		pHwData->TxVgaFor50[22].TxVgaValue = pTxVga[13];
		//interpolate
		pHwData->TxVgaFor50[20].ChanNo = 104;
		pHwData->TxVgaFor50[21].ChanNo = 108;
		stmp = pTxVga[13] - pTxVga[12];
		pHwData->TxVgaFor50[21].TxVgaValue = pTxVga[13] - stmp/3;
		pHwData->TxVgaFor50[20].TxVgaValue = pTxVga[13] - stmp*2/3;

		//channel 128
		pHwData->TxVgaFor50[26].ChanNo = 128;
		pHwData->TxVgaFor50[26].TxVgaValue = pTxVga[14];
		//interpolate
		pHwData->TxVgaFor50[23].ChanNo = 116;
		pHwData->TxVgaFor50[24].ChanNo = 120;
		pHwData->TxVgaFor50[25].ChanNo = 124;
		stmp = pTxVga[14] - pTxVga[13];
		pHwData->TxVgaFor50[25].TxVgaValue = pTxVga[14] - stmp/4;
		pHwData->TxVgaFor50[24].TxVgaValue = pTxVga[14] - stmp*2/4;
		pHwData->TxVgaFor50[23].TxVgaValue = pTxVga[14] - stmp*3/4;

		//channel 140
		pHwData->TxVgaFor50[29].ChanNo = 140;
		pHwData->TxVgaFor50[29].TxVgaValue = pTxVga[15];
		//interpolate
		pHwData->TxVgaFor50[27].ChanNo = 132;
		pHwData->TxVgaFor50[28].ChanNo = 136;
		stmp = pTxVga[15] - pTxVga[14];
		pHwData->TxVgaFor50[28].TxVgaValue = pTxVga[15] - stmp/3;
		pHwData->TxVgaFor50[27].TxVgaValue = pTxVga[15] - stmp*2/3;

		//channel 149
		pHwData->TxVgaFor50[30].ChanNo = 149;
		pHwData->TxVgaFor50[30].TxVgaValue = pTxVga[16];
		//channel 165
		pHwData->TxVgaFor50[34].ChanNo = 165;
		pHwData->TxVgaFor50[34].TxVgaValue = pTxVga[17];
		//interpolate
		pHwData->TxVgaFor50[31].ChanNo = 153;
		pHwData->TxVgaFor50[32].ChanNo = 157;
		pHwData->TxVgaFor50[33].ChanNo = 161;
		stmp = pTxVga[17] - pTxVga[16];
		pHwData->TxVgaFor50[33].TxVgaValue = pTxVga[17] - stmp/4;
		pHwData->TxVgaFor50[32].TxVgaValue = pTxVga[17] - stmp*2/4;
		pHwData->TxVgaFor50[31].TxVgaValue = pTxVga[17] - stmp*3/4;
	}

	#ifdef _PE_STATE_DUMP_
	printk(" TxVgaFor24 : \n");
	DataDmp((u8 *)pHwData->TxVgaFor24, 14 ,0);
	printk(" TxVgaFor50 : \n");
	DataDmp((u8 *)pHwData->TxVgaFor50, 70 ,0);
	#endif
}

void BBProcessor_RateChanging(  struct hw_data * pHwData,  u8 rate ) // 20060613.1
{
	struct wb35_reg *reg = &pHwData->reg;
	unsigned char		Is11bRate;

	Is11bRate = (rate % 6) ? 1 : 0;
	switch( pHwData->phy_type )
	{
		case RF_AIROHA_2230:
		case RF_AIROHA_2230S: // 20060420 Add this
			if( Is11bRate )
			{
				if( (reg->BB48 != BB48_DEFAULT_AL2230_11B) &&
					(reg->BB4C != BB4C_DEFAULT_AL2230_11B) )
				{
					Wb35Reg_Write( pHwData, 0x1048, BB48_DEFAULT_AL2230_11B );
					Wb35Reg_Write( pHwData, 0x104c, BB4C_DEFAULT_AL2230_11B );
				}
			}
			else
			{
				if( (reg->BB48 != BB48_DEFAULT_AL2230_11G) &&
					(reg->BB4C != BB4C_DEFAULT_AL2230_11G) )
				{
					Wb35Reg_Write( pHwData, 0x1048, BB48_DEFAULT_AL2230_11G );
					Wb35Reg_Write( pHwData, 0x104c, BB4C_DEFAULT_AL2230_11G );
				}
			}
			break;

		case RF_WB_242: // 20060623 The fix only for old TxVGA setting
			if( Is11bRate )
			{
				if( (reg->BB48 != BB48_DEFAULT_WB242_11B) &&
					(reg->BB4C != BB4C_DEFAULT_WB242_11B) )
				{
					reg->BB48 = BB48_DEFAULT_WB242_11B;
					reg->BB4C = BB4C_DEFAULT_WB242_11B;
					Wb35Reg_Write( pHwData, 0x1048, BB48_DEFAULT_WB242_11B );
					Wb35Reg_Write( pHwData, 0x104c, BB4C_DEFAULT_WB242_11B );
				}
			}
			else
			{
				if( (reg->BB48 != BB48_DEFAULT_WB242_11G) &&
					(reg->BB4C != BB4C_DEFAULT_WB242_11G) )
				{
					reg->BB48 = BB48_DEFAULT_WB242_11G;
					reg->BB4C = BB4C_DEFAULT_WB242_11G;
					Wb35Reg_Write( pHwData, 0x1048, BB48_DEFAULT_WB242_11G );
					Wb35Reg_Write( pHwData, 0x104c, BB4C_DEFAULT_WB242_11G );
				}
			}
			break;
	}
}