mm-only debug patch...
[mmotm.git] / drivers / staging / winbond / reg.c
blobd915cbdd38ed1e3b15e013a503e6b39f11029efb
1 #include "sysdef.h"
2 #include "wbhal_f.h"
4 ///////////////////////////////////////////////////////////////////////////////////////////////////
5 // Original Phy.h
6 //*****************************************************************************
8 /*****************************************************************************
9 ; For MAXIM2825/6/7 Ver. 331 or more
10 ; Edited by Tiger, Sep-17-2003
11 ; revised by Ben, Sep-18-2003
13 0x00 0x000a2
14 0x01 0x21cc0
15 ;0x02 0x13802
16 0x02 0x1383a
18 ;channe1 01 ; 0x03 0x30142 ; 0x04 0x0b333;
19 ;channe1 02 ;0x03 0x32141 ;0x04 0x08444;
20 ;channe1 03 ;0x03 0x32143 ;0x04 0x0aeee;
21 ;channe1 04 ;0x03 0x32142 ;0x04 0x0b333;
22 ;channe1 05 ;0x03 0x31141 ;0x04 0x08444;
23 ;channe1 06 ;
24 0x03 0x31143;
25 0x04 0x0aeee;
26 ;channe1 07 ;0x03 0x31142 ;0x04 0x0b333;
27 ;channe1 08 ;0x03 0x33141 ;0x04 0x08444;
28 ;channe1 09 ;0x03 0x33143 ;0x04 0x0aeee;
29 ;channe1 10 ;0x03 0x33142 ;0x04 0x0b333;
30 ;channe1 11 ;0x03 0x30941 ;0x04 0x08444;
31 ;channe1 12 ;0x03 0x30943 ;0x04 0x0aeee;
32 ;channe1 13 ;0x03 0x30942 ;0x04 0x0b333;
34 0x05 0x28986
35 0x06 0x18008
36 0x07 0x38400
37 0x08 0x05100; 100 Hz DC
38 ;0x08 0x05900; 30 KHz DC
39 0x09 0x24f08
40 0x0a 0x17e00, 0x17ea0
41 0x0b 0x37d80
42 0x0c 0x0c900 // 0x0ca00 (lager power 9db than 0x0c000), 0x0c000
43 *****************************************************************************/
44 // MAX2825 (pure b/g)
45 u32 max2825_rf_data[] =
47 (0x00<<18)|0x000a2,
48 (0x01<<18)|0x21cc0,
49 (0x02<<18)|0x13806,
50 (0x03<<18)|0x30142,
51 (0x04<<18)|0x0b333,
52 (0x05<<18)|0x289A6,
53 (0x06<<18)|0x18008,
54 (0x07<<18)|0x38000,
55 (0x08<<18)|0x05100,
56 (0x09<<18)|0x24f08,
57 (0x0A<<18)|0x14000,
58 (0x0B<<18)|0x37d80,
59 (0x0C<<18)|0x0c100 // 11a: 0x0c300, 11g: 0x0c100
62 u32 max2825_channel_data_24[][3] =
64 {(0x03<<18)|0x30142, (0x04<<18)|0x0b333, (0x05<<18)|0x289A6}, // channe1 01
65 {(0x03<<18)|0x32141, (0x04<<18)|0x08444, (0x05<<18)|0x289A6}, // channe1 02
66 {(0x03<<18)|0x32143, (0x04<<18)|0x0aeee, (0x05<<18)|0x289A6}, // channe1 03
67 {(0x03<<18)|0x32142, (0x04<<18)|0x0b333, (0x05<<18)|0x289A6}, // channe1 04
68 {(0x03<<18)|0x31141, (0x04<<18)|0x08444, (0x05<<18)|0x289A6}, // channe1 05
69 {(0x03<<18)|0x31143, (0x04<<18)|0x0aeee, (0x05<<18)|0x289A6}, // channe1 06
70 {(0x03<<18)|0x31142, (0x04<<18)|0x0b333, (0x05<<18)|0x289A6}, // channe1 07
71 {(0x03<<18)|0x33141, (0x04<<18)|0x08444, (0x05<<18)|0x289A6}, // channe1 08
72 {(0x03<<18)|0x33143, (0x04<<18)|0x0aeee, (0x05<<18)|0x289A6}, // channe1 09
73 {(0x03<<18)|0x33142, (0x04<<18)|0x0b333, (0x05<<18)|0x289A6}, // channe1 10
74 {(0x03<<18)|0x30941, (0x04<<18)|0x08444, (0x05<<18)|0x289A6}, // channe1 11
75 {(0x03<<18)|0x30943, (0x04<<18)|0x0aeee, (0x05<<18)|0x289A6}, // channe1 12
76 {(0x03<<18)|0x30942, (0x04<<18)|0x0b333, (0x05<<18)|0x289A6}, // channe1 13
77 {(0x03<<18)|0x32941, (0x04<<18)|0x09999, (0x05<<18)|0x289A6} // 14 (2484MHz) hhmodify
80 u32 max2825_power_data_24[] = {(0x0C<<18)|0x0c000, (0x0C<<18)|0x0c100};
82 /****************************************************************************/
83 // MAX2827 (a/b/g)
84 u32 max2827_rf_data[] =
86 (0x00<<18)|0x000a2,
87 (0x01<<18)|0x21cc0,
88 (0x02<<18)|0x13806,
89 (0x03<<18)|0x30142,
90 (0x04<<18)|0x0b333,
91 (0x05<<18)|0x289A6,
92 (0x06<<18)|0x18008,
93 (0x07<<18)|0x38000,
94 (0x08<<18)|0x05100,
95 (0x09<<18)|0x24f08,
96 (0x0A<<18)|0x14000,
97 (0x0B<<18)|0x37d80,
98 (0x0C<<18)|0x0c100 // 11a: 0x0c300, 11g: 0x0c100
101 u32 max2827_channel_data_24[][3] =
103 {(0x03<<18)|0x30142, (0x04<<18)|0x0b333, (0x05<<18)|0x289A6}, // channe1 01
104 {(0x03<<18)|0x32141, (0x04<<18)|0x08444, (0x05<<18)|0x289A6}, // channe1 02
105 {(0x03<<18)|0x32143, (0x04<<18)|0x0aeee, (0x05<<18)|0x289A6}, // channe1 03
106 {(0x03<<18)|0x32142, (0x04<<18)|0x0b333, (0x05<<18)|0x289A6}, // channe1 04
107 {(0x03<<18)|0x31141, (0x04<<18)|0x08444, (0x05<<18)|0x289A6}, // channe1 05
108 {(0x03<<18)|0x31143, (0x04<<18)|0x0aeee, (0x05<<18)|0x289A6}, // channe1 06
109 {(0x03<<18)|0x31142, (0x04<<18)|0x0b333, (0x05<<18)|0x289A6}, // channe1 07
110 {(0x03<<18)|0x33141, (0x04<<18)|0x08444, (0x05<<18)|0x289A6}, // channe1 08
111 {(0x03<<18)|0x33143, (0x04<<18)|0x0aeee, (0x05<<18)|0x289A6}, // channe1 09
112 {(0x03<<18)|0x33142, (0x04<<18)|0x0b333, (0x05<<18)|0x289A6}, // channe1 10
113 {(0x03<<18)|0x30941, (0x04<<18)|0x08444, (0x05<<18)|0x289A6}, // channe1 11
114 {(0x03<<18)|0x30943, (0x04<<18)|0x0aeee, (0x05<<18)|0x289A6}, // channe1 12
115 {(0x03<<18)|0x30942, (0x04<<18)|0x0b333, (0x05<<18)|0x289A6}, // channe1 13
116 {(0x03<<18)|0x32941, (0x04<<18)|0x09999, (0x05<<18)|0x289A6} // 14 (2484MHz) hhmodify
119 u32 max2827_channel_data_50[][3] =
121 {(0x03<<18)|0x33cc3, (0x04<<18)|0x08ccc, (0x05<<18)|0x2A9A6}, // channel 36
122 {(0x03<<18)|0x302c0, (0x04<<18)|0x08000, (0x05<<18)|0x2A9A6}, // channel 40
123 {(0x03<<18)|0x302c2, (0x04<<18)|0x0b333, (0x05<<18)|0x2A9A6}, // channel 44
124 {(0x03<<18)|0x322c1, (0x04<<18)|0x09999, (0x05<<18)|0x2A9A6}, // channel 48
125 {(0x03<<18)|0x312c1, (0x04<<18)|0x0a666, (0x05<<18)|0x2A9A6}, // channel 52
126 {(0x03<<18)|0x332c3, (0x04<<18)|0x08ccc, (0x05<<18)|0x2A9A6}, // channel 56
127 {(0x03<<18)|0x30ac0, (0x04<<18)|0x08000, (0x05<<18)|0x2A9A6}, // channel 60
128 {(0x03<<18)|0x30ac2, (0x04<<18)|0x0b333, (0x05<<18)|0x2A9A6} // channel 64
131 u32 max2827_power_data_24[] = {(0x0C<<18)|0x0C000, (0x0C<<18)|0x0D600, (0x0C<<18)|0x0C100};
132 u32 max2827_power_data_50[] = {(0x0C<<18)|0x0C400, (0x0C<<18)|0x0D500, (0x0C<<18)|0x0C300};
134 /****************************************************************************/
135 // MAX2828 (a/b/g)
136 u32 max2828_rf_data[] =
138 (0x00<<18)|0x000a2,
139 (0x01<<18)|0x21cc0,
140 (0x02<<18)|0x13806,
141 (0x03<<18)|0x30142,
142 (0x04<<18)|0x0b333,
143 (0x05<<18)|0x289A6,
144 (0x06<<18)|0x18008,
145 (0x07<<18)|0x38000,
146 (0x08<<18)|0x05100,
147 (0x09<<18)|0x24f08,
148 (0x0A<<18)|0x14000,
149 (0x0B<<18)|0x37d80,
150 (0x0C<<18)|0x0c100 // 11a: 0x0c300, 11g: 0x0c100
153 u32 max2828_channel_data_24[][3] =
155 {(0x03<<18)|0x30142, (0x04<<18)|0x0b333, (0x05<<18)|0x289A6}, // channe1 01
156 {(0x03<<18)|0x32141, (0x04<<18)|0x08444, (0x05<<18)|0x289A6}, // channe1 02
157 {(0x03<<18)|0x32143, (0x04<<18)|0x0aeee, (0x05<<18)|0x289A6}, // channe1 03
158 {(0x03<<18)|0x32142, (0x04<<18)|0x0b333, (0x05<<18)|0x289A6}, // channe1 04
159 {(0x03<<18)|0x31141, (0x04<<18)|0x08444, (0x05<<18)|0x289A6}, // channe1 05
160 {(0x03<<18)|0x31143, (0x04<<18)|0x0aeee, (0x05<<18)|0x289A6}, // channe1 06
161 {(0x03<<18)|0x31142, (0x04<<18)|0x0b333, (0x05<<18)|0x289A6}, // channe1 07
162 {(0x03<<18)|0x33141, (0x04<<18)|0x08444, (0x05<<18)|0x289A6}, // channe1 08
163 {(0x03<<18)|0x33143, (0x04<<18)|0x0aeee, (0x05<<18)|0x289A6}, // channe1 09
164 {(0x03<<18)|0x33142, (0x04<<18)|0x0b333, (0x05<<18)|0x289A6}, // channe1 10
165 {(0x03<<18)|0x30941, (0x04<<18)|0x08444, (0x05<<18)|0x289A6}, // channe1 11
166 {(0x03<<18)|0x30943, (0x04<<18)|0x0aeee, (0x05<<18)|0x289A6}, // channe1 12
167 {(0x03<<18)|0x30942, (0x04<<18)|0x0b333, (0x05<<18)|0x289A6}, // channe1 13
168 {(0x03<<18)|0x32941, (0x04<<18)|0x09999, (0x05<<18)|0x289A6} // 14 (2484MHz) hhmodify
171 u32 max2828_channel_data_50[][3] =
173 {(0x03<<18)|0x33cc3, (0x04<<18)|0x08ccc, (0x05<<18)|0x289A6}, // channel 36
174 {(0x03<<18)|0x302c0, (0x04<<18)|0x08000, (0x05<<18)|0x289A6}, // channel 40
175 {(0x03<<18)|0x302c2, (0x04<<18)|0x0b333, (0x05<<18)|0x289A6}, // channel 44
176 {(0x03<<18)|0x322c1, (0x04<<18)|0x09999, (0x05<<18)|0x289A6}, // channel 48
177 {(0x03<<18)|0x312c1, (0x04<<18)|0x0a666, (0x05<<18)|0x289A6}, // channel 52
178 {(0x03<<18)|0x332c3, (0x04<<18)|0x08ccc, (0x05<<18)|0x289A6}, // channel 56
179 {(0x03<<18)|0x30ac0, (0x04<<18)|0x08000, (0x05<<18)|0x289A6}, // channel 60
180 {(0x03<<18)|0x30ac2, (0x04<<18)|0x0b333, (0x05<<18)|0x289A6} // channel 64
183 u32 max2828_power_data_24[] = {(0x0C<<18)|0x0c000, (0x0C<<18)|0x0c100};
184 u32 max2828_power_data_50[] = {(0x0C<<18)|0x0c000, (0x0C<<18)|0x0c100};
186 /****************************************************************************/
187 // LA20040728 kevin
188 // MAX2829 (a/b/g)
189 u32 max2829_rf_data[] =
191 (0x00<<18)|0x000a2,
192 (0x01<<18)|0x23520,
193 (0x02<<18)|0x13802,
194 (0x03<<18)|0x30142,
195 (0x04<<18)|0x0b333,
196 (0x05<<18)|0x28906,
197 (0x06<<18)|0x18008,
198 (0x07<<18)|0x3B500,
199 (0x08<<18)|0x05100,
200 (0x09<<18)|0x24f08,
201 (0x0A<<18)|0x14000,
202 (0x0B<<18)|0x37d80,
203 (0x0C<<18)|0x0F300 //TXVGA=51, (MAX-6 dB)
206 u32 max2829_channel_data_24[][3] =
208 {(3<<18)|0x30142, (4<<18)|0x0b333, (5<<18)|0x289C6}, // 01 (2412MHz)
209 {(3<<18)|0x32141, (4<<18)|0x08444, (5<<18)|0x289C6}, // 02 (2417MHz)
210 {(3<<18)|0x32143, (4<<18)|0x0aeee, (5<<18)|0x289C6}, // 03 (2422MHz)
211 {(3<<18)|0x32142, (4<<18)|0x0b333, (5<<18)|0x289C6}, // 04 (2427MHz)
212 {(3<<18)|0x31141, (4<<18)|0x08444, (5<<18)|0x289C6}, // 05 (2432MHz)
213 {(3<<18)|0x31143, (4<<18)|0x0aeee, (5<<18)|0x289C6}, // 06 (2437MHz)
214 {(3<<18)|0x31142, (4<<18)|0x0b333, (5<<18)|0x289C6}, // 07 (2442MHz)
215 {(3<<18)|0x33141, (4<<18)|0x08444, (5<<18)|0x289C6}, // 08 (2447MHz)
216 {(3<<18)|0x33143, (4<<18)|0x0aeee, (5<<18)|0x289C6}, // 09 (2452MHz)
217 {(3<<18)|0x33142, (4<<18)|0x0b333, (5<<18)|0x289C6}, // 10 (2457MHz)
218 {(3<<18)|0x30941, (4<<18)|0x08444, (5<<18)|0x289C6}, // 11 (2462MHz)
219 {(3<<18)|0x30943, (4<<18)|0x0aeee, (5<<18)|0x289C6}, // 12 (2467MHz)
220 {(3<<18)|0x30942, (4<<18)|0x0b333, (5<<18)|0x289C6}, // 13 (2472MHz)
221 {(3<<18)|0x32941, (4<<18)|0x09999, (5<<18)|0x289C6}, // 14 (2484MHz) hh-modify
224 u32 max2829_channel_data_50[][4] =
226 {36, (3<<18)|0x33cc3, (4<<18)|0x08ccc, (5<<18)|0x2A946}, // 36 (5.180GHz)
227 {40, (3<<18)|0x302c0, (4<<18)|0x08000, (5<<18)|0x2A946}, // 40 (5.200GHz)
228 {44, (3<<18)|0x302c2, (4<<18)|0x0b333, (5<<18)|0x2A946}, // 44 (5.220GHz)
229 {48, (3<<18)|0x322c1, (4<<18)|0x09999, (5<<18)|0x2A946}, // 48 (5.240GHz)
230 {52, (3<<18)|0x312c1, (4<<18)|0x0a666, (5<<18)|0x2A946}, // 52 (5.260GHz)
231 {56, (3<<18)|0x332c3, (4<<18)|0x08ccc, (5<<18)|0x2A946}, // 56 (5.280GHz)
232 {60, (3<<18)|0x30ac0, (4<<18)|0x08000, (5<<18)|0x2A946}, // 60 (5.300GHz)
233 {64, (3<<18)|0x30ac2, (4<<18)|0x0b333, (5<<18)|0x2A946}, // 64 (5.320GHz)
235 {100, (3<<18)|0x30ec0, (4<<18)|0x08000, (5<<18)|0x2A9C6}, // 100 (5.500GHz)
236 {104, (3<<18)|0x30ec2, (4<<18)|0x0b333, (5<<18)|0x2A9C6}, // 104 (5.520GHz)
237 {108, (3<<18)|0x32ec1, (4<<18)|0x09999, (5<<18)|0x2A9C6}, // 108 (5.540GHz)
238 {112, (3<<18)|0x31ec1, (4<<18)|0x0a666, (5<<18)|0x2A9C6}, // 112 (5.560GHz)
239 {116, (3<<18)|0x33ec3, (4<<18)|0x08ccc, (5<<18)|0x2A9C6}, // 116 (5.580GHz)
240 {120, (3<<18)|0x301c0, (4<<18)|0x08000, (5<<18)|0x2A9C6}, // 120 (5.600GHz)
241 {124, (3<<18)|0x301c2, (4<<18)|0x0b333, (5<<18)|0x2A9C6}, // 124 (5.620GHz)
242 {128, (3<<18)|0x321c1, (4<<18)|0x09999, (5<<18)|0x2A9C6}, // 128 (5.640GHz)
243 {132, (3<<18)|0x311c1, (4<<18)|0x0a666, (5<<18)|0x2A9C6}, // 132 (5.660GHz)
244 {136, (3<<18)|0x331c3, (4<<18)|0x08ccc, (5<<18)|0x2A9C6}, // 136 (5.680GHz)
245 {140, (3<<18)|0x309c0, (4<<18)|0x08000, (5<<18)|0x2A9C6}, // 140 (5.700GHz)
247 {149, (3<<18)|0x329c2, (4<<18)|0x0b333, (5<<18)|0x2A9C6}, // 149 (5.745GHz)
248 {153, (3<<18)|0x319c1, (4<<18)|0x09999, (5<<18)|0x2A9C6}, // 153 (5.765GHz)
249 {157, (3<<18)|0x339c1, (4<<18)|0x0a666, (5<<18)|0x2A9C6}, // 157 (5.785GHz)
250 {161, (3<<18)|0x305c3, (4<<18)|0x08ccc, (5<<18)|0x2A9C6}, // 161 (5.805GHz)
252 // Japan
253 { 184, (3<<18)|0x308c2, (4<<18)|0x0b333, (5<<18)|0x2A946}, // 184 (4.920GHz)
254 { 188, (3<<18)|0x328c1, (4<<18)|0x09999, (5<<18)|0x2A946}, // 188 (4.940GHz)
255 { 192, (3<<18)|0x318c1, (4<<18)|0x0a666, (5<<18)|0x2A946}, // 192 (4.960GHz)
256 { 196, (3<<18)|0x338c3, (4<<18)|0x08ccc, (5<<18)|0x2A946}, // 196 (4.980GHz)
257 { 8, (3<<18)|0x324c1, (4<<18)|0x09999, (5<<18)|0x2A946}, // 8 (5.040GHz)
258 { 12, (3<<18)|0x314c1, (4<<18)|0x0a666, (5<<18)|0x2A946}, // 12 (5.060GHz)
259 { 16, (3<<18)|0x334c3, (4<<18)|0x08ccc, (5<<18)|0x2A946}, // 16 (5.080GHz)
260 { 34, (3<<18)|0x31cc2, (4<<18)|0x0b333, (5<<18)|0x2A946}, // 34 (5.170GHz)
261 { 38, (3<<18)|0x33cc1, (4<<18)|0x09999, (5<<18)|0x2A946}, // 38 (5.190GHz)
262 { 42, (3<<18)|0x302c1, (4<<18)|0x0a666, (5<<18)|0x2A946}, // 42 (5.210GHz)
263 { 46, (3<<18)|0x322c3, (4<<18)|0x08ccc, (5<<18)|0x2A946}, // 46 (5.230GHz)
266 /*****************************************************************************
267 ; For MAXIM2825/6/7 Ver. 317 or less
268 ; Edited by Tiger, Sep-17-2003 for 2.4Ghz channels
269 ; Updated by Tiger, Sep-22-2003 for 5.0Ghz channels
270 ; Corrected by Tiger, Sep-23-2003, for 0x03 and 0x04 of 5.0Ghz channels
272 0x00 0x00080
273 0x01 0x214c0
274 0x02 0x13802
276 ;2.4GHz Channels
277 ;channe1 01 (2.412GHz); 0x03 0x30143 ;0x04 0x0accc
278 ;channe1 02 (2.417GHz); 0x03 0x32140 ;0x04 0x09111
279 ;channe1 03 (2.422GHz); 0x03 0x32142 ;0x04 0x0bbbb
280 ;channe1 04 (2.427GHz); 0x03 0x32143 ;0x04 0x0accc
281 ;channe1 05 (2.432GHz); 0x03 0x31140 ;0x04 0x09111
282 ;channe1 06 (2.437GHz); 0x03 0x31142 ;0x04 0x0bbbb
283 ;channe1 07 (2.442GHz); 0x03 0x31143 ;0x04 0x0accc
284 ;channe1 08 (2.447GHz); 0x03 0x33140 ;0x04 0x09111
285 ;channe1 09 (2.452GHz); 0x03 0x33142 ;0x04 0x0bbbb
286 ;channe1 10 (2.457GHz); 0x03 0x33143 ;0x04 0x0accc
287 ;channe1 11 (2.462GHz); 0x03 0x30940 ;0x04 0x09111
288 ;channe1 12 (2.467GHz); 0x03 0x30942 ;0x04 0x0bbbb
289 ;channe1 13 (2.472GHz); 0x03 0x30943 ;0x04 0x0accc
291 ;5.0Ghz Channels
292 ;channel 36 (5.180GHz); 0x03 0x33cc0 ;0x04 0x0b333
293 ;channel 40 (5.200GHz); 0x03 0x302c0 ;0x04 0x08000
294 ;channel 44 (5.220GHz); 0x03 0x302c2 ;0x04 0x0b333
295 ;channel 48 (5.240GHz); 0x03 0x322c1 ;0x04 0x09999
296 ;channel 52 (5.260GHz); 0x03 0x312c1 ;0x04 0x0a666
297 ;channel 56 (5.280GHz); 0x03 0x332c3 ;0x04 0x08ccc
298 ;channel 60 (5.300GHz); 0x03 0x30ac0 ;0x04 0x08000
299 ;channel 64 (5.320GHz); 0x03 0x30ac2 ;0x04 0x08333
301 ;2.4GHz band ;0x05 0x28986;
302 ;5.0GHz band
303 0x05 0x2a986
305 0x06 0x18008
306 0x07 0x38400
307 0x08 0x05108
308 0x09 0x27ff8
309 0x0a 0x14000
310 0x0b 0x37f99
311 0x0c 0x0c000
312 *****************************************************************************/
313 u32 maxim_317_rf_data[] =
315 (0x00<<18)|0x000a2,
316 (0x01<<18)|0x214c0,
317 (0x02<<18)|0x13802,
318 (0x03<<18)|0x30143,
319 (0x04<<18)|0x0accc,
320 (0x05<<18)|0x28986,
321 (0x06<<18)|0x18008,
322 (0x07<<18)|0x38400,
323 (0x08<<18)|0x05108,
324 (0x09<<18)|0x27ff8,
325 (0x0A<<18)|0x14000,
326 (0x0B<<18)|0x37f99,
327 (0x0C<<18)|0x0c000
330 u32 maxim_317_channel_data_24[][3] =
332 {(0x03<<18)|0x30143, (0x04<<18)|0x0accc, (0x05<<18)|0x28986}, // channe1 01
333 {(0x03<<18)|0x32140, (0x04<<18)|0x09111, (0x05<<18)|0x28986}, // channe1 02
334 {(0x03<<18)|0x32142, (0x04<<18)|0x0bbbb, (0x05<<18)|0x28986}, // channe1 03
335 {(0x03<<18)|0x32143, (0x04<<18)|0x0accc, (0x05<<18)|0x28986}, // channe1 04
336 {(0x03<<18)|0x31140, (0x04<<18)|0x09111, (0x05<<18)|0x28986}, // channe1 05
337 {(0x03<<18)|0x31142, (0x04<<18)|0x0bbbb, (0x05<<18)|0x28986}, // channe1 06
338 {(0x03<<18)|0x31143, (0x04<<18)|0x0accc, (0x05<<18)|0x28986}, // channe1 07
339 {(0x03<<18)|0x33140, (0x04<<18)|0x09111, (0x05<<18)|0x28986}, // channe1 08
340 {(0x03<<18)|0x33142, (0x04<<18)|0x0bbbb, (0x05<<18)|0x28986}, // channe1 09
341 {(0x03<<18)|0x33143, (0x04<<18)|0x0accc, (0x05<<18)|0x28986}, // channe1 10
342 {(0x03<<18)|0x30940, (0x04<<18)|0x09111, (0x05<<18)|0x28986}, // channe1 11
343 {(0x03<<18)|0x30942, (0x04<<18)|0x0bbbb, (0x05<<18)|0x28986}, // channe1 12
344 {(0x03<<18)|0x30943, (0x04<<18)|0x0accc, (0x05<<18)|0x28986} // channe1 13
347 u32 maxim_317_channel_data_50[][3] =
349 {(0x03<<18)|0x33cc0, (0x04<<18)|0x0b333, (0x05<<18)|0x2a986}, // channel 36
350 {(0x03<<18)|0x302c0, (0x04<<18)|0x08000, (0x05<<18)|0x2a986}, // channel 40
351 {(0x03<<18)|0x302c3, (0x04<<18)|0x0accc, (0x05<<18)|0x2a986}, // channel 44
352 {(0x03<<18)|0x322c1, (0x04<<18)|0x09666, (0x05<<18)|0x2a986}, // channel 48
353 {(0x03<<18)|0x312c2, (0x04<<18)|0x09999, (0x05<<18)|0x2a986}, // channel 52
354 {(0x03<<18)|0x332c0, (0x04<<18)|0x0b333, (0x05<<18)|0x2a99e}, // channel 56
355 {(0x03<<18)|0x30ac0, (0x04<<18)|0x08000, (0x05<<18)|0x2a99e}, // channel 60
356 {(0x03<<18)|0x30ac3, (0x04<<18)|0x0accc, (0x05<<18)|0x2a99e} // channel 64
359 u32 maxim_317_power_data_24[] = {(0x0C<<18)|0x0c000, (0x0C<<18)|0x0c100};
360 u32 maxim_317_power_data_50[] = {(0x0C<<18)|0x0c000, (0x0C<<18)|0x0c100};
362 /*****************************************************************************
363 ;;AL2230 MP (Mass Production Version)
364 ;;RF Registers Setting for Airoha AL2230 silicon after June 1st, 2004
365 ;;Updated by Tiger Huang (June 1st, 2004)
366 ;;20-bit length and LSB first
368 ;;Ch01 (2412MHz) ;0x00 0x09EFC ;0x01 0x8CCCC;
369 ;;Ch02 (2417MHz) ;0x00 0x09EFC ;0x01 0x8CCCD;
370 ;;Ch03 (2422MHz) ;0x00 0x09E7C ;0x01 0x8CCCC;
371 ;;Ch04 (2427MHz) ;0x00 0x09E7C ;0x01 0x8CCCD;
372 ;;Ch05 (2432MHz) ;0x00 0x05EFC ;0x01 0x8CCCC;
373 ;;Ch06 (2437MHz) ;0x00 0x05EFC ;0x01 0x8CCCD;
374 ;;Ch07 (2442MHz) ;0x00 0x05E7C ;0x01 0x8CCCC;
375 ;;Ch08 (2447MHz) ;0x00 0x05E7C ;0x01 0x8CCCD;
376 ;;Ch09 (2452MHz) ;0x00 0x0DEFC ;0x01 0x8CCCC;
377 ;;Ch10 (2457MHz) ;0x00 0x0DEFC ;0x01 0x8CCCD;
378 ;;Ch11 (2462MHz) ;0x00 0x0DE7C ;0x01 0x8CCCC;
379 ;;Ch12 (2467MHz) ;0x00 0x0DE7C ;0x01 0x8CCCD;
380 ;;Ch13 (2472MHz) ;0x00 0x03EFC ;0x01 0x8CCCC;
381 ;;Ch14 (2484Mhz) ;0x00 0x03E7C ;0x01 0x86666;
383 0x02 0x401D8; RXDCOC BW 100Hz for RXHP low
384 ;;0x02 0x481DC; RXDCOC BW 30Khz for RXHP low
386 0x03 0xCFFF0
387 0x04 0x23800
388 0x05 0xA3B72
389 0x06 0x6DA01
390 0x07 0xE1688
391 0x08 0x11600
392 0x09 0x99E02
393 0x0A 0x5DDB0
394 0x0B 0xD9900
395 0x0C 0x3FFBD
396 0x0D 0xB0000
397 0x0F 0xF00A0
399 ;RF Calibration for Airoha AL2230
400 ;Edit by Ben Chang (01/30/04)
401 ;Updated by Tiger Huang (03/03/04)
402 0x0f 0xf00a0 ; Initial Setting
403 0x0f 0xf00b0 ; Activate TX DCC
404 0x0f 0xf02a0 ; Activate Phase Calibration
405 0x0f 0xf00e0 ; Activate Filter RC Calibration
406 0x0f 0xf00a0 ; Restore Initial Setting
407 *****************************************************************************/
409 u32 al2230_rf_data[] =
411 (0x00<<20)|0x09EFC,
412 (0x01<<20)|0x8CCCC,
413 (0x02<<20)|0x40058,// 20060627 Anson 0x401D8,
414 (0x03<<20)|0xCFFF0,
415 (0x04<<20)|0x24100,// 20060627 Anson 0x23800,
416 (0x05<<20)|0xA3B2F,// 20060627 Anson 0xA3B72
417 (0x06<<20)|0x6DA01,
418 (0x07<<20)|0xE3628,// 20060627 Anson 0xE1688,
419 (0x08<<20)|0x11600,
420 (0x09<<20)|0x9DC02,// 20060627 Anosn 0x97602,//0x99E02, //0x9AE02
421 (0x0A<<20)|0x5ddb0, // 941206 For QCOM interference 0x588b0,//0x5DDB0, 940601 adj 0x5aa30 for bluetooth
422 (0x0B<<20)|0xD9900,
423 (0x0C<<20)|0x3FFBD,
424 (0x0D<<20)|0xB0000,
425 (0x0F<<20)|0xF01A0 // 20060627 Anson 0xF00A0
428 u32 al2230s_rf_data[] =
430 (0x00<<20)|0x09EFC,
431 (0x01<<20)|0x8CCCC,
432 (0x02<<20)|0x40058,// 20060419 0x401D8,
433 (0x03<<20)|0xCFFF0,
434 (0x04<<20)|0x24100,// 20060419 0x23800,
435 (0x05<<20)|0xA3B2F,// 20060419 0xA3B72,
436 (0x06<<20)|0x6DA01,
437 (0x07<<20)|0xE3628,// 20060419 0xE1688,
438 (0x08<<20)|0x11600,
439 (0x09<<20)|0x9DC02,// 20060419 0x97602,//0x99E02, //0x9AE02
440 (0x0A<<20)|0x5DDB0,// 941206 For QCOM interference 0x588b0,//0x5DDB0, 940601 adj 0x5aa30 for bluetooth
441 (0x0B<<20)|0xD9900,
442 (0x0C<<20)|0x3FFBD,
443 (0x0D<<20)|0xB0000,
444 (0x0F<<20)|0xF01A0 // 20060419 0xF00A0
447 u32 al2230_channel_data_24[][2] =
449 {(0x00<<20)|0x09EFC, (0x01<<20)|0x8CCCC}, // channe1 01
450 {(0x00<<20)|0x09EFC, (0x01<<20)|0x8CCCD}, // channe1 02
451 {(0x00<<20)|0x09E7C, (0x01<<20)|0x8CCCC}, // channe1 03
452 {(0x00<<20)|0x09E7C, (0x01<<20)|0x8CCCD}, // channe1 04
453 {(0x00<<20)|0x05EFC, (0x01<<20)|0x8CCCC}, // channe1 05
454 {(0x00<<20)|0x05EFC, (0x01<<20)|0x8CCCD}, // channe1 06
455 {(0x00<<20)|0x05E7C, (0x01<<20)|0x8CCCC}, // channe1 07
456 {(0x00<<20)|0x05E7C, (0x01<<20)|0x8CCCD}, // channe1 08
457 {(0x00<<20)|0x0DEFC, (0x01<<20)|0x8CCCC}, // channe1 09
458 {(0x00<<20)|0x0DEFC, (0x01<<20)|0x8CCCD}, // channe1 10
459 {(0x00<<20)|0x0DE7C, (0x01<<20)|0x8CCCC}, // channe1 11
460 {(0x00<<20)|0x0DE7C, (0x01<<20)|0x8CCCD}, // channe1 12
461 {(0x00<<20)|0x03EFC, (0x01<<20)|0x8CCCC}, // channe1 13
462 {(0x00<<20)|0x03E7C, (0x01<<20)|0x86666} // channe1 14
465 // Current setting. u32 airoha_power_data_24[] = {(0x09<<20)|0x90202, (0x09<<20)|0x96602, (0x09<<20)|0x97602};
466 #define AIROHA_TXVGA_LOW_INDEX 31 // Index for 0x90202
467 #define AIROHA_TXVGA_MIDDLE_INDEX 12 // Index for 0x96602
468 #define AIROHA_TXVGA_HIGH_INDEX 8 // Index for 0x97602 1.0.24.0 1.0.28.0
470 u32 airoha_power_data_24[] =
472 0x9FE02, // Max - 0 dB
473 0x9BE02, // Max - 1 dB
474 0x9DE02, // Max - 2 dB
475 0x99E02, // Max - 3 dB
476 0x9EE02, // Max - 4 dB
477 0x9AE02, // Max - 5 dB
478 0x9CE02, // Max - 6 dB
479 0x98E02, // Max - 7 dB
480 0x97602, // Max - 8 dB
481 0x93602, // Max - 9 dB
482 0x95602, // Max - 10 dB
483 0x91602, // Max - 11 dB
484 0x96602, // Max - 12 dB
485 0x92602, // Max - 13 dB
486 0x94602, // Max - 14 dB
487 0x90602, // Max - 15 dB
488 0x97A02, // Max - 16 dB
489 0x93A02, // Max - 17 dB
490 0x95A02, // Max - 18 dB
491 0x91A02, // Max - 19 dB
492 0x96A02, // Max - 20 dB
493 0x92A02, // Max - 21 dB
494 0x94A02, // Max - 22 dB
495 0x90A02, // Max - 23 dB
496 0x97202, // Max - 24 dB
497 0x93202, // Max - 25 dB
498 0x95202, // Max - 26 dB
499 0x91202, // Max - 27 dB
500 0x96202, // Max - 28 dB
501 0x92202, // Max - 29 dB
502 0x94202, // Max - 30 dB
503 0x90202 // Max - 31 dB
507 // 20040927 1.1.69.1000 ybjiang
508 // from John
509 u32 al2230_txvga_data[][2] =
511 //value , index
512 {0x090202, 0},
513 {0x094202, 2},
514 {0x092202, 4},
515 {0x096202, 6},
516 {0x091202, 8},
517 {0x095202, 10},
518 {0x093202, 12},
519 {0x097202, 14},
520 {0x090A02, 16},
521 {0x094A02, 18},
522 {0x092A02, 20},
523 {0x096A02, 22},
524 {0x091A02, 24},
525 {0x095A02, 26},
526 {0x093A02, 28},
527 {0x097A02, 30},
528 {0x090602, 32},
529 {0x094602, 34},
530 {0x092602, 36},
531 {0x096602, 38},
532 {0x091602, 40},
533 {0x095602, 42},
534 {0x093602, 44},
535 {0x097602, 46},
536 {0x090E02, 48},
537 {0x098E02, 49},
538 {0x094E02, 50},
539 {0x09CE02, 51},
540 {0x092E02, 52},
541 {0x09AE02, 53},
542 {0x096E02, 54},
543 {0x09EE02, 55},
544 {0x091E02, 56},
545 {0x099E02, 57},
546 {0x095E02, 58},
547 {0x09DE02, 59},
548 {0x093E02, 60},
549 {0x09BE02, 61},
550 {0x097E02, 62},
551 {0x09FE02, 63}
554 //--------------------------------
555 // For Airoha AL7230, 2.4Ghz band
556 // Edit by Tiger, (March, 9, 2005)
557 // 24bit, MSB first
559 //channel independent registers:
560 u32 al7230_rf_data_24[] =
562 (0x00<<24)|0x003790,
563 (0x01<<24)|0x133331,
564 (0x02<<24)|0x841FF2,
565 (0x03<<24)|0x3FDFA3,
566 (0x04<<24)|0x7FD784,
567 (0x05<<24)|0x802B55,
568 (0x06<<24)|0x56AF36,
569 (0x07<<24)|0xCE0207,
570 (0x08<<24)|0x6EBC08,
571 (0x09<<24)|0x221BB9,
572 (0x0A<<24)|0xE0000A,
573 (0x0B<<24)|0x08071B,
574 (0x0C<<24)|0x000A3C,
575 (0x0D<<24)|0xFFFFFD,
576 (0x0E<<24)|0x00000E,
577 (0x0F<<24)|0x1ABA8F
580 u32 al7230_channel_data_24[][2] =
582 {(0x00<<24)|0x003790, (0x01<<24)|0x133331}, // channe1 01
583 {(0x00<<24)|0x003790, (0x01<<24)|0x1B3331}, // channe1 02
584 {(0x00<<24)|0x003790, (0x01<<24)|0x033331}, // channe1 03
585 {(0x00<<24)|0x003790, (0x01<<24)|0x0B3331}, // channe1 04
586 {(0x00<<24)|0x0037A0, (0x01<<24)|0x133331}, // channe1 05
587 {(0x00<<24)|0x0037A0, (0x01<<24)|0x1B3331}, // channe1 06
588 {(0x00<<24)|0x0037A0, (0x01<<24)|0x033331}, // channe1 07
589 {(0x00<<24)|0x0037A0, (0x01<<24)|0x0B3331}, // channe1 08
590 {(0x00<<24)|0x0037B0, (0x01<<24)|0x133331}, // channe1 09
591 {(0x00<<24)|0x0037B0, (0x01<<24)|0x1B3331}, // channe1 10
592 {(0x00<<24)|0x0037B0, (0x01<<24)|0x033331}, // channe1 11
593 {(0x00<<24)|0x0037B0, (0x01<<24)|0x0B3331}, // channe1 12
594 {(0x00<<24)|0x0037C0, (0x01<<24)|0x133331}, // channe1 13
595 {(0x00<<24)|0x0037C0, (0x01<<24)|0x066661} // channel 14
598 //channel independent registers:
599 u32 al7230_rf_data_50[] =
601 (0x00<<24)|0x0FF520,
602 (0x01<<24)|0x000001,
603 (0x02<<24)|0x451FE2,
604 (0x03<<24)|0x5FDFA3,
605 (0x04<<24)|0x6FD784,
606 (0x05<<24)|0x853F55,
607 (0x06<<24)|0x56AF36,
608 (0x07<<24)|0xCE0207,
609 (0x08<<24)|0x6EBC08,
610 (0x09<<24)|0x221BB9,
611 (0x0A<<24)|0xE0600A,
612 (0x0B<<24)|0x08044B,
613 (0x0C<<24)|0x00143C,
614 (0x0D<<24)|0xFFFFFD,
615 (0x0E<<24)|0x00000E,
616 (0x0F<<24)|0x12BACF //5Ghz default state
619 u32 al7230_channel_data_5[][4] =
621 //channel dependent registers: 0x00, 0x01 and 0x04
622 //11J ===========
623 {184, (0x00<<24)|0x0FF520, (0x01<<24)|0x000001, (0x04<<24)|0x67F784}, // channel 184
624 {188, (0x00<<24)|0x0FF520, (0x01<<24)|0x0AAAA1, (0x04<<24)|0x77F784}, // channel 188
625 {192, (0x00<<24)|0x0FF530, (0x01<<24)|0x155551, (0x04<<24)|0x77F784}, // channel 192
626 {196, (0x00<<24)|0x0FF530, (0x01<<24)|0x000001, (0x04<<24)|0x67F784}, // channel 196
627 {8, (0x00<<24)|0x0FF540, (0x01<<24)|0x000001, (0x04<<24)|0x67F784}, // channel 008
628 {12, (0x00<<24)|0x0FF540, (0x01<<24)|0x0AAAA1, (0x04<<24)|0x77F784}, // channel 012
629 {16, (0x00<<24)|0x0FF550, (0x01<<24)|0x155551, (0x04<<24)|0x77F784}, // channel 016
630 {34, (0x00<<24)|0x0FF560, (0x01<<24)|0x055551, (0x04<<24)|0x77F784}, // channel 034
631 {38, (0x00<<24)|0x0FF570, (0x01<<24)|0x100001, (0x04<<24)|0x77F784}, // channel 038
632 {42, (0x00<<24)|0x0FF570, (0x01<<24)|0x1AAAA1, (0x04<<24)|0x77F784}, // channel 042
633 {46, (0x00<<24)|0x0FF570, (0x01<<24)|0x055551, (0x04<<24)|0x77F784}, // channel 046
634 //11 A/H =========
635 {36, (0x00<<24)|0x0FF560, (0x01<<24)|0x0AAAA1, (0x04<<24)|0x77F784}, // channel 036
636 {40, (0x00<<24)|0x0FF570, (0x01<<24)|0x155551, (0x04<<24)|0x77F784}, // channel 040
637 {44, (0x00<<24)|0x0FF570, (0x01<<24)|0x000001, (0x04<<24)|0x67F784}, // channel 044
638 {48, (0x00<<24)|0x0FF570, (0x01<<24)|0x0AAAA1, (0x04<<24)|0x77F784}, // channel 048
639 {52, (0x00<<24)|0x0FF580, (0x01<<24)|0x155551, (0x04<<24)|0x77F784}, // channel 052
640 {56, (0x00<<24)|0x0FF580, (0x01<<24)|0x000001, (0x04<<24)|0x67F784}, // channel 056
641 {60, (0x00<<24)|0x0FF580, (0x01<<24)|0x0AAAA1, (0x04<<24)|0x77F784}, // channel 060
642 {64, (0x00<<24)|0x0FF590, (0x01<<24)|0x155551, (0x04<<24)|0x77F784}, // channel 064
643 {100, (0x00<<24)|0x0FF5C0, (0x01<<24)|0x155551, (0x04<<24)|0x77F784}, // channel 100
644 {104, (0x00<<24)|0x0FF5C0, (0x01<<24)|0x000001, (0x04<<24)|0x67F784}, // channel 104
645 {108, (0x00<<24)|0x0FF5C0, (0x01<<24)|0x0AAAA1, (0x04<<24)|0x77F784}, // channel 108
646 {112, (0x00<<24)|0x0FF5D0, (0x01<<24)|0x155551, (0x04<<24)|0x77F784}, // channel 112
647 {116, (0x00<<24)|0x0FF5D0, (0x01<<24)|0x000001, (0x04<<24)|0x67F784}, // channel 116
648 {120, (0x00<<24)|0x0FF5D0, (0x01<<24)|0x0AAAA1, (0x04<<24)|0x77F784}, // channel 120
649 {124, (0x00<<24)|0x0FF5E0, (0x01<<24)|0x155551, (0x04<<24)|0x77F784}, // channel 124
650 {128, (0x00<<24)|0x0FF5E0, (0x01<<24)|0x000001, (0x04<<24)|0x67F784}, // channel 128
651 {132, (0x00<<24)|0x0FF5E0, (0x01<<24)|0x0AAAA1, (0x04<<24)|0x77F784}, // channel 132
652 {136, (0x00<<24)|0x0FF5F0, (0x01<<24)|0x155551, (0x04<<24)|0x77F784}, // channel 136
653 {140, (0x00<<24)|0x0FF5F0, (0x01<<24)|0x000001, (0x04<<24)|0x67F784}, // channel 140
654 {149, (0x00<<24)|0x0FF600, (0x01<<24)|0x180001, (0x04<<24)|0x77F784}, // channel 149
655 {153, (0x00<<24)|0x0FF600, (0x01<<24)|0x02AAA1, (0x04<<24)|0x77F784}, // channel 153
656 {157, (0x00<<24)|0x0FF600, (0x01<<24)|0x0D5551, (0x04<<24)|0x77F784}, // channel 157
657 {161, (0x00<<24)|0x0FF610, (0x01<<24)|0x180001, (0x04<<24)|0x77F784}, // channel 161
658 {165, (0x00<<24)|0x0FF610, (0x01<<24)|0x02AAA1, (0x04<<24)|0x77F784} // channel 165
661 //; RF Calibration <=== Register 0x0F
662 //0x0F 0x1ABA8F; start from 2.4Ghz default state
663 //0x0F 0x9ABA8F; TXDC compensation
664 //0x0F 0x3ABA8F; RXFIL adjustment
665 //0x0F 0x1ABA8F; restore 2.4Ghz default state
667 //;TXVGA Mapping Table <=== Register 0x0B
668 u32 al7230_txvga_data[][2] =
670 {0x08040B, 0}, //TXVGA=0;
671 {0x08041B, 1}, //TXVGA=1;
672 {0x08042B, 2}, //TXVGA=2;
673 {0x08043B, 3}, //TXVGA=3;
674 {0x08044B, 4}, //TXVGA=4;
675 {0x08045B, 5}, //TXVGA=5;
676 {0x08046B, 6}, //TXVGA=6;
677 {0x08047B, 7}, //TXVGA=7;
678 {0x08048B, 8}, //TXVGA=8;
679 {0x08049B, 9}, //TXVGA=9;
680 {0x0804AB, 10}, //TXVGA=10;
681 {0x0804BB, 11}, //TXVGA=11;
682 {0x0804CB, 12}, //TXVGA=12;
683 {0x0804DB, 13}, //TXVGA=13;
684 {0x0804EB, 14}, //TXVGA=14;
685 {0x0804FB, 15}, //TXVGA=15;
686 {0x08050B, 16}, //TXVGA=16;
687 {0x08051B, 17}, //TXVGA=17;
688 {0x08052B, 18}, //TXVGA=18;
689 {0x08053B, 19}, //TXVGA=19;
690 {0x08054B, 20}, //TXVGA=20;
691 {0x08055B, 21}, //TXVGA=21;
692 {0x08056B, 22}, //TXVGA=22;
693 {0x08057B, 23}, //TXVGA=23;
694 {0x08058B, 24}, //TXVGA=24;
695 {0x08059B, 25}, //TXVGA=25;
696 {0x0805AB, 26}, //TXVGA=26;
697 {0x0805BB, 27}, //TXVGA=27;
698 {0x0805CB, 28}, //TXVGA=28;
699 {0x0805DB, 29}, //TXVGA=29;
700 {0x0805EB, 30}, //TXVGA=30;
701 {0x0805FB, 31}, //TXVGA=31;
702 {0x08060B, 32}, //TXVGA=32;
703 {0x08061B, 33}, //TXVGA=33;
704 {0x08062B, 34}, //TXVGA=34;
705 {0x08063B, 35}, //TXVGA=35;
706 {0x08064B, 36}, //TXVGA=36;
707 {0x08065B, 37}, //TXVGA=37;
708 {0x08066B, 38}, //TXVGA=38;
709 {0x08067B, 39}, //TXVGA=39;
710 {0x08068B, 40}, //TXVGA=40;
711 {0x08069B, 41}, //TXVGA=41;
712 {0x0806AB, 42}, //TXVGA=42;
713 {0x0806BB, 43}, //TXVGA=43;
714 {0x0806CB, 44}, //TXVGA=44;
715 {0x0806DB, 45}, //TXVGA=45;
716 {0x0806EB, 46}, //TXVGA=46;
717 {0x0806FB, 47}, //TXVGA=47;
718 {0x08070B, 48}, //TXVGA=48;
719 {0x08071B, 49}, //TXVGA=49;
720 {0x08072B, 50}, //TXVGA=50;
721 {0x08073B, 51}, //TXVGA=51;
722 {0x08074B, 52}, //TXVGA=52;
723 {0x08075B, 53}, //TXVGA=53;
724 {0x08076B, 54}, //TXVGA=54;
725 {0x08077B, 55}, //TXVGA=55;
726 {0x08078B, 56}, //TXVGA=56;
727 {0x08079B, 57}, //TXVGA=57;
728 {0x0807AB, 58}, //TXVGA=58;
729 {0x0807BB, 59}, //TXVGA=59;
730 {0x0807CB, 60}, //TXVGA=60;
731 {0x0807DB, 61}, //TXVGA=61;
732 {0x0807EB, 62}, //TXVGA=62;
733 {0x0807FB, 63}, //TXVGA=63;
735 //--------------------------------
738 //; W89RF242 RFIC SPI programming initial data
739 //; Winbond WLAN 11g RFIC BB-SPI register -- version FA5976A rev 1.3b
740 //; Update Date: Ocotber 3, 2005 by PP10 Hsiang-Te Ho
742 //; Version 1.3b revision items: (Oct. 1, 2005 by HTHo) for FA5976A
743 u32 w89rf242_rf_data[] =
745 (0x00<<24)|0xF86100, // 20060721 0xF86100, //; 3E184; MODA (0x00) -- Normal mode ; calibration off
746 (0x01<<24)|0xEFFFC2, //; 3BFFF; MODB (0x01) -- turn off RSSI, and other circuits are turned on
747 (0x02<<24)|0x102504, //; 04094; FSET (0x02) -- default 20MHz crystal ; Icmp=1.5mA
748 (0x03<<24)|0x026286, //; 0098A; FCHN (0x03) -- default CH7, 2442MHz
749 (0x04<<24)|0x000208, // 20060612.1.a 0x0002C8, // 20050818 // 20050816 0x000388
750 //; 02008; FCAL (0x04) -- XTAL Freq Trim=001000 (socket board#1); FA5976AYG_v1.3C
751 (0x05<<24)|0x24C60A, // 20060612.1.a 0x24C58A, // 941003 0x24C48A, // 20050818.2 0x24848A, // 20050818 // 20050816 0x24C48A
752 //; 09316; GANA (0x05) -- TX VGA default (TXVGA=0x18(12)) & TXGPK=110 ; FA5976A_1.3D
753 (0x06<<24)|0x3432CC, // 941003 0x26C34C, // 20050818 0x06B40C
754 //; 0D0CB; GANB (0x06) -- RXDC(DC offset) on; LNA=11; RXVGA=001011(11) ; RXFLSW=11(010001); RXGPK=00; RXGCF=00; -50dBm input
755 (0x07<<24)|0x0C68CE, // 20050818.2 0x0C66CE, // 20050818 // 20050816 0x0C68CE
756 //; 031A3; FILT (0x07) -- TX/RX filter with auto-tuning; TFLBW=011; RFLBW=100
757 (0x08<<24)|0x100010, //; 04000; TCAL (0x08) -- //for LO
758 (0x09<<24)|0x004012, // 20060612.1.a 0x6E4012, // 0x004012,
759 //; 1B900; RCALA (0x09) -- FASTS=11; HPDE=01 (100nsec); SEHP=1 (select B0 pin=RXHP); RXHP=1 (Turn on RXHP function)(FA5976A_1.3C)
760 (0x0A<<24)|0x704014, //; 1C100; RCALB (0x0A)
761 (0x0B<<24)|0x18BDD6, // 941003 0x1805D6, // 20050818.2 0x1801D6, // 20050818 // 20050816 0x1805D6
762 //; 062F7; IQCAL (0x0B) -- Turn on LO phase tuner=0111 & RX-LO phase = 0111; FA5976A_1.3B (2005/09/29)
763 (0x0C<<24)|0x575558, // 20050818.2 0x555558, // 20050818 // 20050816 0x575558
764 //; 15D55 ; IBSA (0x0C) -- IFPre =11 ; TC5376A_v1.3A for corner
765 (0x0D<<24)|0x55545A, // 20060612.1.a 0x55555A,
766 //; 15555 ; IBSB (0x0D)
767 (0x0E<<24)|0x5557DC, // 20060612.1.a 0x55555C, // 941003 0x5557DC,
768 //; 1555F ; IBSC (0x0E) -- IRLNA & IRLNB (PTAT & Const current)=01/01; FA5976B_1.3F (2005/11/25)
769 (0x10<<24)|0x000C20, // 941003 0x000020, // 20050818
770 //; 00030 ; TMODA (0x10) -- LNA_gain_step=0011 ; LNA=15/16dB
771 (0x11<<24)|0x0C0022, // 941003 0x030022 // 20050818.2 0x030022 // 20050818 // 20050816 0x0C0022
772 //; 03000 ; TMODB (0x11) -- Turn ON RX-Q path Test Switch; To improve IQ path group delay (FA5976A_1.3C)
773 (0x12<<24)|0x000024 // 20060612.1.a 0x001824 // 941003 add
774 //; TMODC (0x12) -- Turn OFF Tempearure sensor
777 u32 w89rf242_channel_data_24[][2] =
779 {(0x03<<24)|0x025B06, (0x04<<24)|0x080408}, // channe1 01
780 {(0x03<<24)|0x025C46, (0x04<<24)|0x080408}, // channe1 02
781 {(0x03<<24)|0x025D86, (0x04<<24)|0x080408}, // channe1 03
782 {(0x03<<24)|0x025EC6, (0x04<<24)|0x080408}, // channe1 04
783 {(0x03<<24)|0x026006, (0x04<<24)|0x080408}, // channe1 05
784 {(0x03<<24)|0x026146, (0x04<<24)|0x080408}, // channe1 06
785 {(0x03<<24)|0x026286, (0x04<<24)|0x080408}, // channe1 07
786 {(0x03<<24)|0x0263C6, (0x04<<24)|0x080408}, // channe1 08
787 {(0x03<<24)|0x026506, (0x04<<24)|0x080408}, // channe1 09
788 {(0x03<<24)|0x026646, (0x04<<24)|0x080408}, // channe1 10
789 {(0x03<<24)|0x026786, (0x04<<24)|0x080408}, // channe1 11
790 {(0x03<<24)|0x0268C6, (0x04<<24)|0x080408}, // channe1 12
791 {(0x03<<24)|0x026A06, (0x04<<24)|0x080408}, // channe1 13
792 {(0x03<<24)|0x026D06, (0x04<<24)|0x080408} // channe1 14
795 u32 w89rf242_power_data_24[] = {(0x05<<24)|0x24C48A, (0x05<<24)|0x24C48A, (0x05<<24)|0x24C48A};
797 // 20060315.6 Enlarge for new scale
798 // 20060316.6 20060619.2.a add mapping array
799 u32 w89rf242_txvga_old_mapping[][2] =
801 {0, 0} , // New <-> Old
802 {1, 1} ,
803 {2, 2} ,
804 {3, 3} ,
805 {4, 4} ,
806 {6, 5} ,
807 {8, 6 },
808 {10, 7 },
809 {12, 8 },
810 {14, 9 },
811 {16, 10},
812 {18, 11},
813 {20, 12},
814 {22, 13},
815 {24, 14},
816 {26, 15},
817 {28, 16},
818 {30, 17},
819 {32, 18},
820 {34, 19},
825 // 20060619.3 modify from Bruce's mail
826 u32 w89rf242_txvga_data[][5] =
828 //low gain mode
829 { (0x05<<24)|0x24C00A, 0, 0x00292315, 0x0800FEFF, 0x52523131 },// ; min gain
830 { (0x05<<24)|0x24C80A, 1, 0x00292315, 0x0800FEFF, 0x52523131 },
831 { (0x05<<24)|0x24C04A, 2, 0x00292315, 0x0800FEFF, 0x52523131 },// (default) +14dBm (ANT)
832 { (0x05<<24)|0x24C84A, 3, 0x00292315, 0x0800FEFF, 0x52523131 },
834 //TXVGA=0x10
835 { (0x05<<24)|0x24C40A, 4, 0x00292315, 0x0800FEFF, 0x60603838 },
836 { (0x05<<24)|0x24C40A, 5, 0x00262114, 0x0700FEFF, 0x65653B3B },
838 //TXVGA=0x11
839 { (0x05<<24)|0x24C44A, 6, 0x00241F13, 0x0700FFFF, 0x58583333 },
840 { (0x05<<24)|0x24C44A, 7, 0x00292315, 0x0800FEFF, 0x5E5E3737 },
842 //TXVGA=0x12
843 { (0x05<<24)|0x24C48A, 8, 0x00262114, 0x0700FEFF, 0x53533030 },
844 { (0x05<<24)|0x24C48A, 9, 0x00241F13, 0x0700FFFF, 0x59593434 },
846 //TXVGA=0x13
847 { (0x05<<24)|0x24C4CA, 10, 0x00292315, 0x0800FEFF, 0x52523030 },
848 { (0x05<<24)|0x24C4CA, 11, 0x00262114, 0x0700FEFF, 0x56563232 },
850 //TXVGA=0x14
851 { (0x05<<24)|0x24C50A, 12, 0x00292315, 0x0800FEFF, 0x54543131 },
852 { (0x05<<24)|0x24C50A, 13, 0x00262114, 0x0700FEFF, 0x58583434 },
854 //TXVGA=0x15
855 { (0x05<<24)|0x24C54A, 14, 0x00292315, 0x0800FEFF, 0x54543131 },
856 { (0x05<<24)|0x24C54A, 15, 0x00262114, 0x0700FEFF, 0x59593434 },
858 //TXVGA=0x16
859 { (0x05<<24)|0x24C58A, 16, 0x00292315, 0x0800FEFF, 0x55553131 },
860 { (0x05<<24)|0x24C58A, 17, 0x00292315, 0x0800FEFF, 0x5B5B3535 },
862 //TXVGA=0x17
863 { (0x05<<24)|0x24C5CA, 18, 0x00262114, 0x0700FEFF, 0x51512F2F },
864 { (0x05<<24)|0x24C5CA, 19, 0x00241F13, 0x0700FFFF, 0x55553131 },
866 //TXVGA=0x18
867 { (0x05<<24)|0x24C60A, 20, 0x00292315, 0x0800FEFF, 0x4F4F2E2E },
868 { (0x05<<24)|0x24C60A, 21, 0x00262114, 0x0700FEFF, 0x53533030 },
870 //TXVGA=0x19
871 { (0x05<<24)|0x24C64A, 22, 0x00292315, 0x0800FEFF, 0x4E4E2D2D },
872 { (0x05<<24)|0x24C64A, 23, 0x00262114, 0x0700FEFF, 0x53533030 },
874 //TXVGA=0x1A
875 { (0x05<<24)|0x24C68A, 24, 0x00292315, 0x0800FEFF, 0x50502E2E },
876 { (0x05<<24)|0x24C68A, 25, 0x00262114, 0x0700FEFF, 0x55553131 },
878 //TXVGA=0x1B
879 { (0x05<<24)|0x24C6CA, 26, 0x00262114, 0x0700FEFF, 0x53533030 },
880 { (0x05<<24)|0x24C6CA, 27, 0x00292315, 0x0800FEFF, 0x5A5A3434 },
882 //TXVGA=0x1C
883 { (0x05<<24)|0x24C70A, 28, 0x00292315, 0x0800FEFF, 0x55553131 },
884 { (0x05<<24)|0x24C70A, 29, 0x00292315, 0x0800FEFF, 0x5D5D3636 },
886 //TXVGA=0x1D
887 { (0x05<<24)|0x24C74A, 30, 0x00292315, 0x0800FEFF, 0x5F5F3737 },
888 { (0x05<<24)|0x24C74A, 31, 0x00262114, 0x0700FEFF, 0x65653B3B },
890 //TXVGA=0x1E
891 { (0x05<<24)|0x24C78A, 32, 0x00292315, 0x0800FEFF, 0x66663B3B },
892 { (0x05<<24)|0x24C78A, 33, 0x00262114, 0x0700FEFF, 0x70704141 },
894 //TXVGA=0x1F
895 { (0x05<<24)|0x24C7CA, 34, 0x00292315, 0x0800FEFF, 0x72724242 }
898 ///////////////////////////////////////////////////////////////////////////////////////////////////
899 ///////////////////////////////////////////////////////////////////////////////////////////////////
900 ///////////////////////////////////////////////////////////////////////////////////////////////////
904 //=============================================================================================================
905 // Uxx_ReadEthernetAddress --
907 // Routine Description:
908 // Reads in the Ethernet address from the IC.
910 // Arguments:
911 // pHwData - The pHwData structure
913 // Return Value:
915 // The address is stored in EthernetIDAddr.
916 //=============================================================================================================
917 void
918 Uxx_ReadEthernetAddress( struct hw_data * pHwData )
920 u32 ltmp;
922 // Reading Ethernet address from EEPROM and set into hardware due to MAC address maybe change.
923 // Only unplug and plug again can make hardware read EEPROM again. 20060727
924 Wb35Reg_WriteSync( pHwData, 0x03b4, 0x08000000 ); // Start EEPROM access + Read + address(0x0d)
925 Wb35Reg_ReadSync( pHwData, 0x03b4, &ltmp );
926 *(u16 *)pHwData->PermanentMacAddress = cpu_to_le16((u16)ltmp); //20060926 anson's endian
927 Wb35Reg_WriteSync( pHwData, 0x03b4, 0x08010000 ); // Start EEPROM access + Read + address(0x0d)
928 Wb35Reg_ReadSync( pHwData, 0x03b4, &ltmp );
929 *(u16 *)(pHwData->PermanentMacAddress + 2) = cpu_to_le16((u16)ltmp); //20060926 anson's endian
930 Wb35Reg_WriteSync( pHwData, 0x03b4, 0x08020000 ); // Start EEPROM access + Read + address(0x0d)
931 Wb35Reg_ReadSync( pHwData, 0x03b4, &ltmp );
932 *(u16 *)(pHwData->PermanentMacAddress + 4) = cpu_to_le16((u16)ltmp); //20060926 anson's endian
933 *(u16 *)(pHwData->PermanentMacAddress + 6) = 0;
934 Wb35Reg_WriteSync( pHwData, 0x03e8, cpu_to_le32(*(u32 *)pHwData->PermanentMacAddress) ); //20060926 anson's endian
935 Wb35Reg_WriteSync( pHwData, 0x03ec, cpu_to_le32(*(u32 *)(pHwData->PermanentMacAddress+4)) ); //20060926 anson's endian
939 //===============================================================================================================
940 // CardGetMulticastBit --
941 // Description:
942 // For a given multicast address, returns the byte and bit in the card multicast registers that it hashes to.
943 // Calls CardComputeCrc() to determine the CRC value.
944 // Arguments:
945 // Address - the address
946 // Byte - the byte that it hashes to
947 // Value - will have a 1 in the relevant bit
948 // Return Value:
949 // None.
950 //==============================================================================================================
951 void CardGetMulticastBit( u8 Address[ETH_ALEN], u8 *Byte, u8 *Value )
953 u32 Crc;
954 u32 BitNumber;
956 // First compute the CRC.
957 Crc = CardComputeCrc(Address, ETH_ALEN);
959 // The computed CRC is bit0~31 from left to right
960 //At first we should do right shift 25bits, and read 7bits by using '&', 2^7=128
961 BitNumber = (u32) ((Crc >> 26) & 0x3f);
963 *Byte = (u8) (BitNumber >> 3);// 900514 original (BitNumber / 8)
964 *Value = (u8) ((u8)1 << (BitNumber % 8));
967 void Uxx_power_on_procedure( struct hw_data * pHwData )
969 u32 ltmp, loop;
971 if( pHwData->phy_type <= RF_MAXIM_V1 )
972 Wb35Reg_WriteSync( pHwData, 0x03d4, 0xffffff38 );
973 else
975 Wb35Reg_WriteSync( pHwData, 0x03f4, 0xFF5807FF );// 20060721 For NEW IC 0xFF5807FF
977 // 20060511.1 Fix the following 4 steps for Rx of RF 2230 initial fail
978 Wb35Reg_WriteSync( pHwData, 0x03d4, 0x80 );// regulator on only
979 msleep(10); // Modify 20051221.1.b
980 Wb35Reg_WriteSync( pHwData, 0x03d4, 0xb8 );// REG_ON RF_RSTN on, and
981 msleep(10); // Modify 20051221.1.b
983 ltmp = 0x4968;
984 if( (pHwData->phy_type == RF_WB_242) ||
985 (RF_WB_242_1 == pHwData->phy_type) ) // 20060619.5 Add
986 ltmp = 0x4468;
987 Wb35Reg_WriteSync( pHwData, 0x03d0, ltmp );
989 Wb35Reg_WriteSync( pHwData, 0x03d4, 0xa0 );// PLL_PD REF_PD set to 0
991 msleep(20); // Modify 20051221.1.b
992 Wb35Reg_ReadSync( pHwData, 0x03d0, &ltmp );
993 loop = 500; // Wait for 5 second 20061101
994 while( !(ltmp & 0x20) && loop-- )
996 msleep(10); // Modify 20051221.1.b
997 if( !Wb35Reg_ReadSync( pHwData, 0x03d0, &ltmp ) )
998 break;
1001 Wb35Reg_WriteSync( pHwData, 0x03d4, 0xe0 );// MLK_EN
1004 Wb35Reg_WriteSync( pHwData, 0x03b0, 1 );// Reset hardware first
1005 msleep(10); // Add this 20051221.1.b
1007 // Set burst write delay
1008 Wb35Reg_WriteSync( pHwData, 0x03f8, 0x7ff );
1011 void Set_ChanIndep_RfData_al7230_24( struct hw_data * pHwData, u32 *pltmp ,char number)
1013 u8 i;
1015 for( i=0; i<number; i++ )
1017 pHwData->phy_para[i] = al7230_rf_data_24[i];
1018 pltmp[i] = (1 << 31) | (0 << 30) | (24 << 24) | (al7230_rf_data_24[i]&0xffffff);
1022 void Set_ChanIndep_RfData_al7230_50( struct hw_data * pHwData, u32 *pltmp, char number)
1024 u8 i;
1026 for( i=0; i<number; i++ )
1028 pHwData->phy_para[i] = al7230_rf_data_50[i];
1029 pltmp[i] = (1 << 31) | (0 << 30) | (24 << 24) | (al7230_rf_data_50[i]&0xffffff);
1034 //=============================================================================================================
1035 // RFSynthesizer_initial --
1036 //=============================================================================================================
1037 void
1038 RFSynthesizer_initial(struct hw_data * pHwData)
1040 u32 altmp[32];
1041 u32 * pltmp = altmp;
1042 u32 ltmp;
1043 u8 number=0x00; // The number of register vale
1044 u8 i;
1047 // bit[31] SPI Enable.
1048 // 1=perform synthesizer program operation. This bit will
1049 // cleared automatically after the operation is completed.
1050 // bit[30] SPI R/W Control
1051 // 0=write, 1=read
1052 // bit[29:24] SPI Data Format Length
1053 // bit[17:4 ] RF Data bits.
1054 // bit[3 :0 ] RF address.
1055 switch( pHwData->phy_type )
1057 case RF_MAXIM_2825:
1058 case RF_MAXIM_V1: // 11g Winbond 2nd BB(with Phy board (v1) + Maxim 331)
1059 number = sizeof(max2825_rf_data)/sizeof(max2825_rf_data[0]);
1060 for( i=0; i<number; i++ )
1062 pHwData->phy_para[i] = max2825_rf_data[i];// Backup Rf parameter
1063 pltmp[i] = (1 << 31) | (0 << 30) | (18 << 24) | BitReverse( max2825_rf_data[i], 18);
1065 break;
1067 case RF_MAXIM_2827:
1068 number = sizeof(max2827_rf_data)/sizeof(max2827_rf_data[0]);
1069 for( i=0; i<number; i++ )
1071 pHwData->phy_para[i] = max2827_rf_data[i];
1072 pltmp[i] = (1 << 31) | (0 << 30) | (18 << 24) | BitReverse( max2827_rf_data[i], 18);
1074 break;
1076 case RF_MAXIM_2828:
1077 number = sizeof(max2828_rf_data)/sizeof(max2828_rf_data[0]);
1078 for( i=0; i<number; i++ )
1080 pHwData->phy_para[i] = max2828_rf_data[i];
1081 pltmp[i] = (1 << 31) | (0 << 30) | (18 << 24) | BitReverse( max2828_rf_data[i], 18);
1083 break;
1085 case RF_MAXIM_2829:
1086 number = sizeof(max2829_rf_data)/sizeof(max2829_rf_data[0]);
1087 for( i=0; i<number; i++ )
1089 pHwData->phy_para[i] = max2829_rf_data[i];
1090 pltmp[i] = (1 << 31) | (0 << 30) | (18 << 24) | BitReverse( max2829_rf_data[i], 18);
1092 break;
1094 case RF_AIROHA_2230:
1095 number = sizeof(al2230_rf_data)/sizeof(al2230_rf_data[0]);
1096 for( i=0; i<number; i++ )
1098 pHwData->phy_para[i] = al2230_rf_data[i];
1099 pltmp[i] = (1 << 31) | (0 << 30) | (20 << 24) | BitReverse( al2230_rf_data[i], 20);
1101 break;
1103 case RF_AIROHA_2230S:
1104 number = sizeof(al2230s_rf_data)/sizeof(al2230s_rf_data[0]);
1105 for( i=0; i<number; i++ )
1107 pHwData->phy_para[i] = al2230s_rf_data[i];
1108 pltmp[i] = (1 << 31) | (0 << 30) | (20 << 24) | BitReverse( al2230s_rf_data[i], 20);
1110 break;
1112 case RF_AIROHA_7230:
1114 //Start to fill RF parameters, PLL_ON should be pulled low.
1115 Wb35Reg_WriteSync( pHwData, 0x03dc, 0x00000000 );
1116 #ifdef _PE_STATE_DUMP_
1117 printk("* PLL_ON low\n");
1118 #endif
1120 number = sizeof(al7230_rf_data_24)/sizeof(al7230_rf_data_24[0]);
1121 Set_ChanIndep_RfData_al7230_24(pHwData, pltmp, number);
1122 break;
1124 case RF_WB_242:
1125 case RF_WB_242_1: // 20060619.5 Add
1126 number = sizeof(w89rf242_rf_data)/sizeof(w89rf242_rf_data[0]);
1127 for( i=0; i<number; i++ )
1129 ltmp = w89rf242_rf_data[i];
1130 if( i == 4 ) // Update the VCO trim from EEPROM
1132 ltmp &= ~0xff0; // Mask bit4 ~bit11
1133 ltmp |= pHwData->VCO_trim<<4;
1136 pHwData->phy_para[i] = ltmp;
1137 pltmp[i] = (1 << 31) | (0 << 30) | (24 << 24) | BitReverse( ltmp, 24);
1139 break;
1142 pHwData->phy_number = number;
1144 // The 16 is the maximum capability of hardware. Here use 12
1145 if( number > 12 ) {
1146 //Wb35Reg_BurstWrite( pHwData, 0x0864, pltmp, 12, NO_INCREMENT );
1147 for( i=0; i<12; i++ ) // For Al2230
1148 Wb35Reg_WriteSync( pHwData, 0x0864, pltmp[i] );
1150 pltmp += 12;
1151 number -= 12;
1154 // Write to register. number must less and equal than 16
1155 for( i=0; i<number; i++ )
1156 Wb35Reg_WriteSync( pHwData, 0x864, pltmp[i] );
1158 // 20060630.1 Calibration only 1 time
1159 if( pHwData->CalOneTime )
1160 return;
1161 pHwData->CalOneTime = 1;
1163 switch( pHwData->phy_type )
1165 case RF_AIROHA_2230:
1167 // 20060511.1 --- Modifying the follow step for Rx issue-----------------
1168 ltmp = (1 << 31) | (0 << 30) | (20 << 24) | BitReverse( (0x07<<20)|0xE168E, 20);
1169 Wb35Reg_WriteSync( pHwData, 0x0864, ltmp );
1170 msleep(10);
1171 ltmp = (1 << 31) | (0 << 30) | (20 << 24) | BitReverse( al2230_rf_data[7], 20);
1172 Wb35Reg_WriteSync( pHwData, 0x0864, ltmp );
1173 msleep(10);
1175 case RF_AIROHA_2230S: // 20060420 Add this
1177 // 20060511.1 --- Modifying the follow step for Rx issue-----------------
1178 Wb35Reg_WriteSync( pHwData, 0x03d4, 0x80 );// regulator on only
1179 msleep(10); // Modify 20051221.1.b
1181 Wb35Reg_WriteSync( pHwData, 0x03d4, 0xa0 );// PLL_PD REF_PD set to 0
1182 msleep(10); // Modify 20051221.1.b
1184 Wb35Reg_WriteSync( pHwData, 0x03d4, 0xe0 );// MLK_EN
1185 Wb35Reg_WriteSync( pHwData, 0x03b0, 1 );// Reset hardware first
1186 msleep(10); // Add this 20051221.1.b
1187 //------------------------------------------------------------------------
1189 // The follow code doesn't use the burst-write mode
1190 //phy_set_rf_data(phw_data, 0x0F, (0x0F<<20) | 0xF01A0); //Raise Initial Setting
1191 ltmp = (1 << 31) | (0 << 30) | (20 << 24) | BitReverse( (0x0F<<20) | 0xF01A0, 20);
1192 Wb35Reg_WriteSync( pHwData, 0x0864, ltmp );
1194 ltmp = pHwData->reg.BB5C & 0xfffff000;
1195 Wb35Reg_WriteSync( pHwData, 0x105c, ltmp );
1196 pHwData->reg.BB50 |= 0x13;//(MASK_IQCAL_MODE|MASK_CALIB_START);//20060315.1 modify
1197 Wb35Reg_WriteSync(pHwData, 0x1050, pHwData->reg.BB50);
1198 msleep(5);
1200 //phy_set_rf_data(phw_data, 0x0F, (0x0F<<20) | 0xF01B0); //Activate Filter Cal.
1201 ltmp = (1 << 31) | (0 << 30) | (20 << 24) | BitReverse( (0x0F<<20) | 0xF01B0, 20);
1202 Wb35Reg_WriteSync( pHwData, 0x0864, ltmp );
1203 msleep(5);
1205 //phy_set_rf_data(phw_data, 0x0F, (0x0F<<20) | 0xF01e0); //Activate TX DCC
1206 ltmp = (1 << 31) | (0 << 30) | (20 << 24) | BitReverse( (0x0F<<20) | 0xF01E0, 20);
1207 Wb35Reg_WriteSync( pHwData, 0x0864, ltmp );
1208 msleep(5);
1210 //phy_set_rf_data(phw_data, 0x0F, (0x0F<<20) | 0xF01A0); //Resotre Initial Setting
1211 ltmp = (1 << 31) | (0 << 30) | (20 << 24) | BitReverse( (0x0F<<20) | 0xF01A0, 20);
1212 Wb35Reg_WriteSync( pHwData, 0x0864, ltmp );
1214 // //Force TXI(Q)P(N) to normal control
1215 Wb35Reg_WriteSync( pHwData, 0x105c, pHwData->reg.BB5C );
1216 pHwData->reg.BB50 &= ~0x13;//(MASK_IQCAL_MODE|MASK_CALIB_START);
1217 Wb35Reg_WriteSync( pHwData, 0x1050, pHwData->reg.BB50);
1218 break;
1220 case RF_AIROHA_7230:
1222 //RF parameters have filled completely, PLL_ON should be
1223 //pulled high
1224 Wb35Reg_WriteSync( pHwData, 0x03dc, 0x00000080 );
1225 #ifdef _PE_STATE_DUMP_
1226 printk("* PLL_ON high\n");
1227 #endif
1229 //2.4GHz
1230 //ltmp = (1 << 31) | (0 << 30) | (24 << 24) | 0x1ABA8F;
1231 //Wb35Reg_WriteSync pHwData, 0x0864, ltmp );
1232 //msleep(1); // Sleep 1 ms
1233 ltmp = (1 << 31) | (0 << 30) | (24 << 24) | 0x9ABA8F;
1234 Wb35Reg_WriteSync( pHwData, 0x0864, ltmp );
1235 msleep(5);
1236 ltmp = (1 << 31) | (0 << 30) | (24 << 24) | 0x3ABA8F;
1237 Wb35Reg_WriteSync( pHwData, 0x0864, ltmp );
1238 msleep(5);
1239 ltmp = (1 << 31) | (0 << 30) | (24 << 24) | 0x1ABA8F;
1240 Wb35Reg_WriteSync( pHwData, 0x0864, ltmp );
1241 msleep(5);
1243 //5GHz
1244 Wb35Reg_WriteSync( pHwData, 0x03dc, 0x00000000 );
1245 #ifdef _PE_STATE_DUMP_
1246 printk("* PLL_ON low\n");
1247 #endif
1249 number = sizeof(al7230_rf_data_50)/sizeof(al7230_rf_data_50[0]);
1250 Set_ChanIndep_RfData_al7230_50(pHwData, pltmp, number);
1251 // Write to register. number must less and equal than 16
1252 for( i=0; i<number; i++ )
1253 Wb35Reg_WriteSync( pHwData, 0x0864, pltmp[i] );
1254 msleep(5);
1256 Wb35Reg_WriteSync( pHwData, 0x03dc, 0x00000080 );
1257 #ifdef _PE_STATE_DUMP_
1258 printk("* PLL_ON high\n");
1259 #endif
1261 //ltmp = (1 << 31) | (0 << 30) | (24 << 24) | 0x12BACF;
1262 //Wb35Reg_WriteSync( pHwData, 0x0864, ltmp );
1263 ltmp = (1 << 31) | (0 << 30) | (24 << 24) | 0x9ABA8F;
1264 Wb35Reg_WriteSync( pHwData, 0x0864, ltmp );
1265 msleep(5);
1266 ltmp = (1 << 31) | (0 << 30) | (24 << 24) | 0x3ABA8F;
1267 Wb35Reg_WriteSync( pHwData, 0x0864, ltmp );
1268 msleep(5);
1269 ltmp = (1 << 31) | (0 << 30) | (24 << 24) | 0x12BACF;
1270 Wb35Reg_WriteSync( pHwData, 0x0864, ltmp );
1271 msleep(5);
1273 //Wb35Reg_WriteSync( pHwData, 0x03dc, 0x00000080 );
1274 //printk("* PLL_ON high\n");
1275 break;
1277 case RF_WB_242:
1278 case RF_WB_242_1: // 20060619.5 Add
1281 // ; Version 1.3B revision items: for FA5976A , October 3, 2005 by HTHo
1283 ltmp = pHwData->reg.BB5C & 0xfffff000;
1284 Wb35Reg_WriteSync( pHwData, 0x105c, ltmp );
1285 Wb35Reg_WriteSync( pHwData, 0x1058, 0 );
1286 pHwData->reg.BB50 |= 0x3;//(MASK_IQCAL_MODE|MASK_CALIB_START);//20060630
1287 Wb35Reg_WriteSync(pHwData, 0x1050, pHwData->reg.BB50);
1289 //----- Calibration (1). VCO frequency calibration
1290 //Calibration (1a.0). Synthesizer reset (HTHo corrected 2005/05/10)
1291 ltmp = (1 << 31) | (0 << 30) | (24 << 24) | BitReverse( (0x0F<<24) | 0x00101E, 24);
1292 Wb35Reg_WriteSync( pHwData, 0x0864, ltmp );
1293 msleep(5); // Sleep 5ms
1294 //Calibration (1a). VCO frequency calibration mode ; waiting 2msec VCO calibration time
1295 ltmp = (1 << 31) | (0 << 30) | (24 << 24) | BitReverse( (0x00<<24) | 0xFE69c0, 24);
1296 Wb35Reg_WriteSync( pHwData, 0x0864, ltmp );
1297 msleep(2); // Sleep 2ms
1299 //----- Calibration (2). TX baseband Gm-C filter auto-tuning
1300 //Calibration (2a). turn off ENCAL signal
1301 ltmp = (1 << 31) | (0 << 30) | (24 << 24) | BitReverse( (0x00<<24) | 0xF8EBC0, 24);
1302 Wb35Reg_WriteSync( pHwData, 0x0864, ltmp );
1303 //Calibration (2b.0). TX filter auto-tuning BW: TFLBW=101 (TC5376A default)
1304 ltmp = (1 << 31) | (0 << 30) | (24 << 24) | BitReverse( (0x07<<24) | 0x0C68CE, 24);
1305 Wb35Reg_WriteSync( pHwData, 0x0864, ltmp );
1306 //Calibration (2b). send TX reset signal (HTHo corrected May 10, 2005)
1307 ltmp = (1 << 31) | (0 << 30) | (24 << 24) | BitReverse( (0x0F<<24) | 0x00201E, 24);
1308 Wb35Reg_WriteSync( pHwData, 0x0864, ltmp );
1309 //Calibration (2c). turn-on TX Gm-C filter auto-tuning
1310 ltmp = (1 << 31) | (0 << 30) | (24 << 24) | BitReverse( (0x00<<24) | 0xFCEBC0, 24);
1311 Wb35Reg_WriteSync( pHwData, 0x0864, ltmp );
1312 udelay(150); // Sleep 150 us
1313 //turn off ENCAL signal
1314 ltmp = (1 << 31) | (0 << 30) | (24 << 24) | BitReverse( (0x00<<24) | 0xF8EBC0, 24);
1315 Wb35Reg_WriteSync( pHwData, 0x0864, ltmp );
1317 //----- Calibration (3). RX baseband Gm-C filter auto-tuning
1318 //Calibration (3a). turn off ENCAL signal
1319 ltmp = (1 << 31) | (0 << 30) | (24 << 24) | BitReverse( (0x00<<24) | 0xFAEDC0, 24);
1320 Wb35Reg_WriteSync( pHwData, 0x0864, ltmp );
1321 //Calibration (3b.0). RX filter auto-tuning BW: RFLBW=100 (TC5376A+corner default; July 26, 2005)
1322 ltmp = (1 << 31) | (0 << 30) | (24 << 24) | BitReverse( (0x07<<24) | 0x0C68CE, 24);
1323 Wb35Reg_WriteSync( pHwData, 0x0864, ltmp );
1324 //Calibration (3b). send RX reset signal (HTHo corrected May 10, 2005)
1325 ltmp = (1 << 31) | (0 << 30) | (24 << 24) | BitReverse( (0x0F<<24) | 0x00401E, 24);
1326 Wb35Reg_WriteSync( pHwData, 0x0864, ltmp );
1327 //Calibration (3c). turn-on RX Gm-C filter auto-tuning
1328 ltmp = (1 << 31) | (0 << 30) | (24 << 24) | BitReverse( (0x00<<24) | 0xFEEDC0, 24);
1329 Wb35Reg_WriteSync( pHwData, 0x0864, ltmp );
1330 udelay(150); // Sleep 150 us
1331 //Calibration (3e). turn off ENCAL signal
1332 ltmp = (1 << 31) | (0 << 30) | (24 << 24) | BitReverse( (0x00<<24) | 0xFAEDC0, 24);
1333 Wb35Reg_WriteSync( pHwData, 0x0864, ltmp );
1335 //----- Calibration (4). TX LO leakage calibration
1336 //Calibration (4a). TX LO leakage calibration
1337 ltmp = (1 << 31) | (0 << 30) | (24 << 24) | BitReverse( (0x00<<24) | 0xFD6BC0, 24);
1338 Wb35Reg_WriteSync( pHwData, 0x0864, ltmp );
1339 udelay(150); // Sleep 150 us
1341 //----- Calibration (5). RX DC offset calibration
1342 //Calibration (5a). turn off ENCAL signal and set to RX SW DC caliration mode
1343 ltmp = (1 << 31) | (0 << 30) | (24 << 24) | BitReverse( (0x00<<24) | 0xFAEDC0, 24);
1344 Wb35Reg_WriteSync( pHwData, 0x0864, ltmp );
1345 //Calibration (5b). turn off AGC servo-loop & RSSI
1346 ltmp = (1 << 31) | (0 << 30) | (24 << 24) | BitReverse( (0x01<<24) | 0xEBFFC2, 24);
1347 Wb35Reg_WriteSync( pHwData, 0x0864, ltmp );
1349 //; for LNA=11 --------
1350 //Calibration (5c-h). RX DC offset current bias ON; & LNA=11; RXVGA=111111
1351 ltmp = (1 << 31) | (0 << 30) | (24 << 24) | BitReverse( (0x06<<24) | 0x343FCC, 24);
1352 Wb35Reg_WriteSync( pHwData, 0x0864, ltmp );
1353 //Calibration (5d). turn on RX DC offset cal function; and waiting 2 msec cal time
1354 ltmp = (1 << 31) | (0 << 30) | (24 << 24) | BitReverse( (0x00<<24) | 0xFF6DC0, 24);
1355 Wb35Reg_WriteSync( pHwData, 0x0864, ltmp );
1356 msleep(2); // Sleep 2ms
1357 //Calibration (5f). turn off ENCAL signal
1358 ltmp = (1 << 31) | (0 << 30) | (24 << 24) | BitReverse( (0x00<<24) | 0xFAEDC0, 24);
1359 Wb35Reg_WriteSync( pHwData, 0x0864, ltmp );
1361 //; for LNA=10 --------
1362 //Calibration (5c-m). RX DC offset current bias ON; & LNA=10; RXVGA=111111
1363 ltmp = (1 << 31) | (0 << 30) | (24 << 24) | BitReverse( (0x06<<24) | 0x342FCC, 24);
1364 Wb35Reg_WriteSync( pHwData, 0x0864, ltmp );
1365 //Calibration (5d). turn on RX DC offset cal function; and waiting 2 msec cal time
1366 ltmp = (1 << 31) | (0 << 30) | (24 << 24) | BitReverse( (0x00<<24) | 0xFF6DC0, 24);
1367 Wb35Reg_WriteSync( pHwData, 0x0864, ltmp );
1368 msleep(2); // Sleep 2ms
1369 //Calibration (5f). turn off ENCAL signal
1370 ltmp = (1 << 31) | (0 << 30) | (24 << 24) | BitReverse( (0x00<<24) | 0xFAEDC0, 24);
1371 Wb35Reg_WriteSync( pHwData, 0x0864, ltmp );
1373 //; for LNA=01 --------
1374 //Calibration (5c-m). RX DC offset current bias ON; & LNA=01; RXVGA=111111
1375 ltmp = (1 << 31) | (0 << 30) | (24 << 24) | BitReverse( (0x06<<24) | 0x341FCC, 24);
1376 Wb35Reg_WriteSync( pHwData, 0x0864, ltmp );
1377 //Calibration (5d). turn on RX DC offset cal function; and waiting 2 msec cal time
1378 ltmp = (1 << 31) | (0 << 30) | (24 << 24) | BitReverse( (0x00<<24) | 0xFF6DC0, 24);
1379 Wb35Reg_WriteSync( pHwData, 0x0864, ltmp );
1380 msleep(2); // Sleep 2ms
1381 //Calibration (5f). turn off ENCAL signal
1382 ltmp = (1 << 31) | (0 << 30) | (24 << 24) | BitReverse( (0x00<<24) | 0xFAEDC0, 24);
1383 Wb35Reg_WriteSync( pHwData, 0x0864, ltmp );
1385 //; for LNA=00 --------
1386 //Calibration (5c-l). RX DC offset current bias ON; & LNA=00; RXVGA=111111
1387 ltmp = (1 << 31) | (0 << 30) | (24 << 24) | BitReverse( (0x06<<24) | 0x340FCC, 24);
1388 Wb35Reg_WriteSync( pHwData, 0x0864, ltmp );
1389 //Calibration (5d). turn on RX DC offset cal function; and waiting 2 msec cal time
1390 ltmp = (1 << 31) | (0 << 30) | (24 << 24) | BitReverse( (0x00<<24) | 0xFF6DC0, 24);
1391 Wb35Reg_WriteSync( pHwData, 0x0864, ltmp );
1392 msleep(2); // Sleep 2ms
1393 //Calibration (5f). turn off ENCAL signal
1394 ltmp = (1 << 31) | (0 << 30) | (24 << 24) | BitReverse( (0x00<<24) | 0xFAEDC0, 24);
1395 Wb35Reg_WriteSync( pHwData, 0x0864, ltmp );
1396 //Calibration (5g). turn on AGC servo-loop
1397 ltmp = (1 << 31) | (0 << 30) | (24 << 24) | BitReverse( (0x01<<24) | 0xEFFFC2, 24);
1398 Wb35Reg_WriteSync( pHwData, 0x0864, ltmp );
1400 //; ----- Calibration (7). Switch RF chip to normal mode
1401 //0x00 0xF86100 ; 3E184 ; Switch RF chip to normal mode
1402 // msleep(10); // @@ 20060721
1403 ltmp = (1 << 31) | (0 << 30) | (24 << 24) | BitReverse( (0x00<<24) | 0xF86100, 24);
1404 Wb35Reg_WriteSync( pHwData, 0x0864, ltmp );
1405 msleep(5); // Sleep 5 ms
1407 // //write back
1408 // Wb35Reg_WriteSync(pHwData, 0x105c, pHwData->reg.BB5C);
1409 // pHwData->reg.BB50 &= ~0x13;//(MASK_IQCAL_MODE|MASK_CALIB_START); // 20060315.1 fix
1410 // Wb35Reg_WriteSync(pHwData, 0x1050, pHwData->reg.BB50);
1411 // msleep(1); // Sleep 1 ms
1412 break;
1416 void BBProcessor_AL7230_2400( struct hw_data * pHwData)
1418 struct wb35_reg *reg = &pHwData->reg;
1419 u32 pltmp[12];
1421 pltmp[0] = 0x16A8337A; // 0x16a5215f; // 0x1000 AGC_Ctrl1
1422 pltmp[1] = 0x9AFF9AA6; // 0x9aff9ca6; // 0x1004 AGC_Ctrl2
1423 pltmp[2] = 0x55D00A04; // 0x55d00a04; // 0x1008 AGC_Ctrl3
1424 pltmp[3] = 0xFFF72031; // 0xFfFf2138; // 0x100c AGC_Ctrl4
1425 reg->BB0C = 0xFFF72031;
1426 pltmp[4] = 0x0FacDCC5; // 0x1010 AGC_Ctrl5 // 20050927 0x0FacDCB7
1427 pltmp[5] = 0x00CAA333; // 0x00eaa333; // 0x1014 AGC_Ctrl6
1428 pltmp[6] = 0xF2211111; // 0x11111111; // 0x1018 AGC_Ctrl7
1429 pltmp[7] = 0x0FA3F0ED; // 0x101c AGC_Ctrl8
1430 pltmp[8] = 0x06443440; // 0x1020 AGC_Ctrl9
1431 pltmp[9] = 0xA8002A79; // 0xa9002A79; // 0x1024 AGC_Ctrl10
1432 pltmp[10] = 0x40000528; // 20050927 0x40000228
1433 pltmp[11] = 0x232D7F30; // 0x23457f30;// 0x102c A_ACQ_Ctrl
1434 reg->BB2C = 0x232D7F30;
1435 Wb35Reg_BurstWrite( pHwData, 0x1000, pltmp, 12, AUTO_INCREMENT );
1437 pltmp[0] = 0x00002c54; // 0x1030 B_ACQ_Ctrl
1438 reg->BB30 = 0x00002c54;
1439 pltmp[1] = 0x00C0D6C5; // 0x1034 A_TXRX_Ctrl
1440 pltmp[2] = 0x5B2C8769; // 0x1038 B_TXRX_Ctrl
1441 pltmp[3] = 0x00000000; // 0x103c 11a TX LS filter
1442 reg->BB3C = 0x00000000;
1443 pltmp[4] = 0x00003F29; // 0x1040 11a TX LS filter
1444 pltmp[5] = 0x0EFEFBFE; // 0x1044 11a TX LS filter
1445 pltmp[6] = 0x00332C1B; // 0x00453B24; // 0x1048 11b TX RC filter
1446 pltmp[7] = 0x0A00FEFF; // 0x0E00FEFF; // 0x104c 11b TX RC filter
1447 pltmp[8] = 0x2B106208; // 0x1050 MODE_Ctrl
1448 reg->BB50 = 0x2B106208;
1449 pltmp[9] = 0; // 0x1054
1450 reg->BB54 = 0x00000000;
1451 pltmp[10] = 0x52524242; // 0x64645252; // 0x1058 IQ_Alpha
1452 reg->BB58 = 0x52524242;
1453 pltmp[11] = 0xAA0AC000; // 0x105c DC_Cancel
1454 Wb35Reg_BurstWrite( pHwData, 0x1030, pltmp, 12, AUTO_INCREMENT );
1458 void BBProcessor_AL7230_5000( struct hw_data * pHwData)
1460 struct wb35_reg *reg = &pHwData->reg;
1461 u32 pltmp[12];
1463 pltmp[0] = 0x16AA6678; // 0x1000 AGC_Ctrl1
1464 pltmp[1] = 0x9AFFA0B2; // 0x1004 AGC_Ctrl2
1465 pltmp[2] = 0x55D00A04; // 0x1008 AGC_Ctrl3
1466 pltmp[3] = 0xEFFF233E; // 0x100c AGC_Ctrl4
1467 reg->BB0C = 0xEFFF233E;
1468 pltmp[4] = 0x0FacDCC5; // 0x1010 AGC_Ctrl5 // 20050927 0x0FacDCB7
1469 pltmp[5] = 0x00CAA333; // 0x1014 AGC_Ctrl6
1470 pltmp[6] = 0xF2432111; // 0x1018 AGC_Ctrl7
1471 pltmp[7] = 0x0FA3F0ED; // 0x101c AGC_Ctrl8
1472 pltmp[8] = 0x05C43440; // 0x1020 AGC_Ctrl9
1473 pltmp[9] = 0x00002A79; // 0x1024 AGC_Ctrl10
1474 pltmp[10] = 0x40000528; // 20050927 0x40000228
1475 pltmp[11] = 0x232FDF30;// 0x102c A_ACQ_Ctrl
1476 reg->BB2C = 0x232FDF30;
1477 Wb35Reg_BurstWrite( pHwData, 0x1000, pltmp, 12, AUTO_INCREMENT );
1479 pltmp[0] = 0x80002C7C; // 0x1030 B_ACQ_Ctrl
1480 pltmp[1] = 0x00C0D6C5; // 0x1034 A_TXRX_Ctrl
1481 pltmp[2] = 0x5B2C8769; // 0x1038 B_TXRX_Ctrl
1482 pltmp[3] = 0x00000000; // 0x103c 11a TX LS filter
1483 reg->BB3C = 0x00000000;
1484 pltmp[4] = 0x00003F29; // 0x1040 11a TX LS filter
1485 pltmp[5] = 0x0EFEFBFE; // 0x1044 11a TX LS filter
1486 pltmp[6] = 0x00332C1B; // 0x1048 11b TX RC filter
1487 pltmp[7] = 0x0A00FEFF; // 0x104c 11b TX RC filter
1488 pltmp[8] = 0x2B107208; // 0x1050 MODE_Ctrl
1489 reg->BB50 = 0x2B107208;
1490 pltmp[9] = 0; // 0x1054
1491 reg->BB54 = 0x00000000;
1492 pltmp[10] = 0x52524242; // 0x1058 IQ_Alpha
1493 reg->BB58 = 0x52524242;
1494 pltmp[11] = 0xAA0AC000; // 0x105c DC_Cancel
1495 Wb35Reg_BurstWrite( pHwData, 0x1030, pltmp, 12, AUTO_INCREMENT );
1499 //=============================================================================================================
1500 // BBProcessorPowerupInit --
1502 // Description:
1503 // Initialize the Baseband processor.
1505 // Arguments:
1506 // pHwData - Handle of the USB Device.
1508 // Return values:
1509 // None.
1510 //=============================================================================================================
1511 void
1512 BBProcessor_initial( struct hw_data * pHwData )
1514 struct wb35_reg *reg = &pHwData->reg;
1515 u32 i, pltmp[12];
1517 switch( pHwData->phy_type )
1519 case RF_MAXIM_V1: // Initializng the Winbond 2nd BB(with Phy board (v1) + Maxim 331)
1521 pltmp[0] = 0x16F47E77; // 0x1000 AGC_Ctrl1
1522 pltmp[1] = 0x9AFFAEA4; // 0x1004 AGC_Ctrl2
1523 pltmp[2] = 0x55D00A04; // 0x1008 AGC_Ctrl3
1524 pltmp[3] = 0xEFFF1A34; // 0x100c AGC_Ctrl4
1525 reg->BB0C = 0xEFFF1A34;
1526 pltmp[4] = 0x0FABE0B7; // 0x1010 AGC_Ctrl5
1527 pltmp[5] = 0x00CAA332; // 0x1014 AGC_Ctrl6
1528 pltmp[6] = 0xF6632111; // 0x1018 AGC_Ctrl7
1529 pltmp[7] = 0x0FA3F0ED; // 0x101c AGC_Ctrl8
1530 pltmp[8] = 0x04CC3640; // 0x1020 AGC_Ctrl9
1531 pltmp[9] = 0x00002A79; // 0x1024 AGC_Ctrl10
1532 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)
1533 pltmp[11] = 0x232FDF30; // 0x102c A_ACQ_Ctrl
1534 reg->BB2C = 0x232FDF30; //Modify for 33's 1.0.95.xxx version, antenna 1
1535 Wb35Reg_BurstWrite( pHwData, 0x1000, pltmp, 12, AUTO_INCREMENT );
1537 pltmp[0] = 0x00002C54; // 0x1030 B_ACQ_Ctrl
1538 reg->BB30 = 0x00002C54;
1539 pltmp[1] = 0x00C0D6C5; // 0x1034 A_TXRX_Ctrl
1540 pltmp[2] = 0x5B6C8769; // 0x1038 B_TXRX_Ctrl
1541 pltmp[3] = 0x00000000; // 0x103c 11a TX LS filter
1542 reg->BB3C = 0x00000000;
1543 pltmp[4] = 0x00003F29; // 0x1040 11a TX LS filter
1544 pltmp[5] = 0x0EFEFBFE; // 0x1044 11a TX LS filter
1545 pltmp[6] = 0x00453B24; // 0x1048 11b TX RC filter
1546 pltmp[7] = 0x0E00FEFF; // 0x104c 11b TX RC filter
1547 pltmp[8] = 0x27106208; // 0x1050 MODE_Ctrl
1548 reg->BB50 = 0x27106208;
1549 pltmp[9] = 0; // 0x1054
1550 reg->BB54 = 0x00000000;
1551 pltmp[10] = 0x64646464; // 0x1058 IQ_Alpha
1552 reg->BB58 = 0x64646464;
1553 pltmp[11] = 0xAA0AC000; // 0x105c DC_Cancel
1554 Wb35Reg_BurstWrite( pHwData, 0x1030, pltmp, 12, AUTO_INCREMENT );
1556 Wb35Reg_Write( pHwData, 0x1070, 0x00000045 );
1557 break;
1559 //------------------------------------------------------------------
1560 //[20040722 WK]
1561 //Only for baseband version 2
1562 // case RF_MAXIM_317:
1563 case RF_MAXIM_2825:
1564 case RF_MAXIM_2827:
1565 case RF_MAXIM_2828:
1567 pltmp[0] = 0x16b47e77; // 0x1000 AGC_Ctrl1
1568 pltmp[1] = 0x9affaea4; // 0x1004 AGC_Ctrl2
1569 pltmp[2] = 0x55d00a04; // 0x1008 AGC_Ctrl3
1570 pltmp[3] = 0xefff1a34; // 0x100c AGC_Ctrl4
1571 reg->BB0C = 0xefff1a34;
1572 pltmp[4] = 0x0fabe0b7; // 0x1010 AGC_Ctrl5
1573 pltmp[5] = 0x00caa332; // 0x1014 AGC_Ctrl6
1574 pltmp[6] = 0xf6632111; // 0x1018 AGC_Ctrl7
1575 pltmp[7] = 0x0FA3F0ED; // 0x101c AGC_Ctrl8
1576 pltmp[8] = 0x04CC3640; // 0x1020 AGC_Ctrl9
1577 pltmp[9] = 0x00002A79; // 0x1024 AGC_Ctrl10
1578 pltmp[10] = 0x40000528; // 0x40000128; Modify for 33's 1.0.95
1579 pltmp[11] = 0x232fdf30; // 0x102c A_ACQ_Ctrl
1580 reg->BB2C = 0x232fdf30; //Modify for 33's 1.0.95.xxx version, antenna 1
1581 Wb35Reg_BurstWrite( pHwData, 0x1000, pltmp, 12, AUTO_INCREMENT );
1583 pltmp[0] = 0x00002C54; // 0x1030 B_ACQ_Ctrl
1584 reg->BB30 = 0x00002C54;
1585 pltmp[1] = 0x00C0D6C5; // 0x1034 A_TXRX_Ctrl
1586 pltmp[2] = 0x5B6C8769; // 0x1038 B_TXRX_Ctrl
1587 pltmp[3] = 0x00000000; // 0x103c 11a TX LS filter
1588 reg->BB3C = 0x00000000;
1589 pltmp[4] = 0x00003F29; // 0x1040 11a TX LS filter
1590 pltmp[5] = 0x0EFEFBFE; // 0x1044 11a TX LS filter
1591 pltmp[6] = 0x00453B24; // 0x1048 11b TX RC filter
1592 pltmp[7] = 0x0D00FDFF; // 0x104c 11b TX RC filter
1593 pltmp[8] = 0x27106208; // 0x1050 MODE_Ctrl
1594 reg->BB50 = 0x27106208;
1595 pltmp[9] = 0; // 0x1054
1596 reg->BB54 = 0x00000000;
1597 pltmp[10] = 0x64646464; // 0x1058 IQ_Alpha
1598 reg->BB58 = 0x64646464;
1599 pltmp[11] = 0xAA28C000; // 0x105c DC_Cancel
1600 Wb35Reg_BurstWrite( pHwData, 0x1030, pltmp, 12, AUTO_INCREMENT );
1602 Wb35Reg_Write( pHwData, 0x1070, 0x00000045 );
1603 break;
1605 case RF_MAXIM_2829:
1607 pltmp[0] = 0x16b47e77; // 0x1000 AGC_Ctrl1
1608 pltmp[1] = 0x9affaea4; // 0x1004 AGC_Ctrl2
1609 pltmp[2] = 0x55d00a04; // 0x1008 AGC_Ctrl3
1610 pltmp[3] = 0xf4ff1632; // 0xefff1a34; // 0x100c AGC_Ctrl4 Modify for 33's 1.0.95
1611 reg->BB0C = 0xf4ff1632; // 0xefff1a34; Modify for 33's 1.0.95
1612 pltmp[4] = 0x0fabe0b7; // 0x1010 AGC_Ctrl5
1613 pltmp[5] = 0x00caa332; // 0x1014 AGC_Ctrl6
1614 pltmp[6] = 0xf8632112; // 0xf6632111; // 0x1018 AGC_Ctrl7 Modify for 33's 1.0.95
1615 pltmp[7] = 0x0FA3F0ED; // 0x101c AGC_Ctrl8
1616 pltmp[8] = 0x04CC3640; // 0x1020 AGC_Ctrl9
1617 pltmp[9] = 0x00002A79; // 0x1024 AGC_Ctrl10
1618 pltmp[10] = 0x40000528; // 0x40000128; modify for 33's 1.0.95
1619 pltmp[11] = 0x232fdf30; // 0x102c A_ACQ_Ctrl
1620 reg->BB2C = 0x232fdf30; //Modify for 33's 1.0.95.xxx version, antenna 1
1621 Wb35Reg_BurstWrite( pHwData, 0x1000, pltmp, 12, AUTO_INCREMENT );
1623 pltmp[0] = 0x00002C54; // 0x1030 B_ACQ_Ctrl
1624 reg->BB30 = 0x00002C54;
1625 pltmp[1] = 0x00C0D6C5; // 0x1034 A_TXRX_Ctrl
1626 pltmp[2] = 0x5b2c8769; // 0x5B6C8769; // 0x1038 B_TXRX_Ctrl Modify for 33's 1.0.95
1627 pltmp[3] = 0x00000000; // 0x103c 11a TX LS filter
1628 reg->BB3C = 0x00000000;
1629 pltmp[4] = 0x00003F29; // 0x1040 11a TX LS filter
1630 pltmp[5] = 0x0EFEFBFE; // 0x1044 11a TX LS filter
1631 pltmp[6] = 0x002c2617; // 0x00453B24; // 0x1048 11b TX RC filter Modify for 33's 1.0.95
1632 pltmp[7] = 0x0800feff; // 0x0D00FDFF; // 0x104c 11b TX RC filter Modify for 33's 1.0.95
1633 pltmp[8] = 0x27106208; // 0x1050 MODE_Ctrl
1634 reg->BB50 = 0x27106208;
1635 pltmp[9] = 0; // 0x1054
1636 reg->BB54 = 0x00000000;
1637 pltmp[10] = 0x64644a4a; // 0x64646464; // 0x1058 IQ_Alpha Modify for 33's 1.0.95
1638 reg->BB58 = 0x64646464;
1639 pltmp[11] = 0xAA28C000; // 0x105c DC_Cancel
1640 Wb35Reg_BurstWrite( pHwData, 0x1030, pltmp, 12, AUTO_INCREMENT );
1642 Wb35Reg_Write( pHwData, 0x1070, 0x00000045 );
1643 break;
1645 case RF_AIROHA_2230:
1647 pltmp[0] = 0X16764A77; // 0x1000 AGC_Ctrl1 //0x16765A77
1648 pltmp[1] = 0x9affafb2; // 0x1004 AGC_Ctrl2
1649 pltmp[2] = 0x55d00a04; // 0x1008 AGC_Ctrl3
1650 pltmp[3] = 0xFFFd203c; // 0xFFFb203a; // 0x100c AGC_Ctrl4 Modify for 33's 1.0.95.xxx version
1651 reg->BB0C = 0xFFFd203c;
1652 pltmp[4] = 0X0FBFDCc5; // 0X0FBFDCA0; // 0x1010 AGC_Ctrl5 //0x0FB2E0B7 Modify for 33's 1.0.95.xxx version
1653 pltmp[5] = 0x00caa332; // 0x00caa333; // 0x1014 AGC_Ctrl6 Modify for 33's 1.0.95.xxx version
1654 pltmp[6] = 0XF6632111; // 0XF1632112; // 0x1018 AGC_Ctrl7 //0xf6632112 Modify for 33's 1.0.95.xxx version
1655 pltmp[7] = 0x0FA3F0ED; // 0x101c AGC_Ctrl8
1656 pltmp[8] = 0x04C43640; // 0x1020 AGC_Ctrl9
1657 pltmp[9] = 0x00002A79; // 0x1024 AGC_Ctrl10
1658 pltmp[10] = 0X40000528; //0x40000228
1659 pltmp[11] = 0x232dfF30; // 0x232A9F30; // 0x102c A_ACQ_Ctrl //0x232a9730
1660 reg->BB2C = 0x232dfF30; //Modify for 33's 1.0.95.xxx version, antenna 1
1661 Wb35Reg_BurstWrite( pHwData, 0x1000, pltmp, 12, AUTO_INCREMENT );
1663 pltmp[0] = 0x00002C54; // 0x1030 B_ACQ_Ctrl
1664 reg->BB30 = 0x00002C54;
1665 pltmp[1] = 0x00C0D6C5; // 0x1034 A_TXRX_Ctrl
1666 pltmp[2] = 0x5B2C8769; // 0x1038 B_TXRX_Ctrl //0x5B6C8769
1667 pltmp[3] = 0x00000000; // 0x103c 11a TX LS filter
1668 reg->BB3C = 0x00000000;
1669 pltmp[4] = 0x00003F29; // 0x1040 11a TX LS filter
1670 pltmp[5] = 0x0EFEFBFE; // 0x1044 11a TX LS filter
1671 pltmp[6] = BB48_DEFAULT_AL2230_11G; // 0x1048 11b TX RC filter 20060613.2
1672 reg->BB48 = BB48_DEFAULT_AL2230_11G; // 20051221 ch14 20060613.2
1673 pltmp[7] = BB4C_DEFAULT_AL2230_11G; // 0x104c 11b TX RC filter 20060613.2
1674 reg->BB4C = BB4C_DEFAULT_AL2230_11G; // 20060613.1 20060613.2
1675 pltmp[8] = 0x27106200; // 0x1050 MODE_Ctrl
1676 reg->BB50 = 0x27106200;
1677 pltmp[9] = 0; // 0x1054
1678 reg->BB54 = 0x00000000;
1679 pltmp[10] = 0x52524242; // 0x1058 IQ_Alpha
1680 reg->BB58 = 0x52524242;
1681 pltmp[11] = 0xAA0AC000; // 0x105c DC_Cancel
1682 Wb35Reg_BurstWrite( pHwData, 0x1030, pltmp, 12, AUTO_INCREMENT );
1684 Wb35Reg_Write( pHwData, 0x1070, 0x00000045 );
1685 break;
1687 case RF_AIROHA_2230S: // 20060420 Add this
1689 pltmp[0] = 0X16764A77; // 0x1000 AGC_Ctrl1 //0x16765A77
1690 pltmp[1] = 0x9affafb2; // 0x1004 AGC_Ctrl2
1691 pltmp[2] = 0x55d00a04; // 0x1008 AGC_Ctrl3
1692 pltmp[3] = 0xFFFd203c; // 0xFFFb203a; // 0x100c AGC_Ctrl4 Modify for 33's 1.0.95.xxx version
1693 reg->BB0C = 0xFFFd203c;
1694 pltmp[4] = 0X0FBFDCc5; // 0X0FBFDCA0; // 0x1010 AGC_Ctrl5 //0x0FB2E0B7 Modify for 33's 1.0.95.xxx version
1695 pltmp[5] = 0x00caa332; // 0x00caa333; // 0x1014 AGC_Ctrl6 Modify for 33's 1.0.95.xxx version
1696 pltmp[6] = 0XF6632111; // 0XF1632112; // 0x1018 AGC_Ctrl7 //0xf6632112 Modify for 33's 1.0.95.xxx version
1697 pltmp[7] = 0x0FA3F0ED; // 0x101c AGC_Ctrl8
1698 pltmp[8] = 0x04C43640; // 0x1020 AGC_Ctrl9
1699 pltmp[9] = 0x00002A79; // 0x1024 AGC_Ctrl10
1700 pltmp[10] = 0X40000528; //0x40000228
1701 pltmp[11] = 0x232dfF30; // 0x232A9F30; // 0x102c A_ACQ_Ctrl //0x232a9730
1702 reg->BB2C = 0x232dfF30; //Modify for 33's 1.0.95.xxx version, antenna 1
1703 Wb35Reg_BurstWrite( pHwData, 0x1000, pltmp, 12, AUTO_INCREMENT );
1705 pltmp[0] = 0x00002C54; // 0x1030 B_ACQ_Ctrl
1706 reg->BB30 = 0x00002C54;
1707 pltmp[1] = 0x00C0D6C5; // 0x1034 A_TXRX_Ctrl
1708 pltmp[2] = 0x5B2C8769; // 0x1038 B_TXRX_Ctrl //0x5B6C8769
1709 pltmp[3] = 0x00000000; // 0x103c 11a TX LS filter
1710 reg->BB3C = 0x00000000;
1711 pltmp[4] = 0x00003F29; // 0x1040 11a TX LS filter
1712 pltmp[5] = 0x0EFEFBFE; // 0x1044 11a TX LS filter
1713 pltmp[6] = BB48_DEFAULT_AL2230_11G; // 0x1048 11b TX RC filter 20060613.2
1714 reg->BB48 = BB48_DEFAULT_AL2230_11G; // 20051221 ch14 20060613.2
1715 pltmp[7] = BB4C_DEFAULT_AL2230_11G; // 0x104c 11b TX RC filter 20060613.2
1716 reg->BB4C = BB4C_DEFAULT_AL2230_11G; // 20060613.1
1717 pltmp[8] = 0x27106200; // 0x1050 MODE_Ctrl
1718 reg->BB50 = 0x27106200;
1719 pltmp[9] = 0; // 0x1054
1720 reg->BB54 = 0x00000000;
1721 pltmp[10] = 0x52523232; // 20060419 0x52524242; // 0x1058 IQ_Alpha
1722 reg->BB58 = 0x52523232; // 20060419 0x52524242;
1723 pltmp[11] = 0xAA0AC000; // 0x105c DC_Cancel
1724 Wb35Reg_BurstWrite( pHwData, 0x1030, pltmp, 12, AUTO_INCREMENT );
1726 Wb35Reg_Write( pHwData, 0x1070, 0x00000045 );
1727 break;
1729 case RF_AIROHA_7230:
1731 pltmp[0] = 0x16a84a77; // 0x1000 AGC_Ctrl1
1732 pltmp[1] = 0x9affafb2; // 0x1004 AGC_Ctrl2
1733 pltmp[2] = 0x55d00a04; // 0x1008 AGC_Ctrl3
1734 pltmp[3] = 0xFFFb203a; // 0x100c AGC_Ctrl4
1735 reg->BB0c = 0xFFFb203a;
1736 pltmp[4] = 0x0FBFDCB7; // 0x1010 AGC_Ctrl5
1737 pltmp[5] = 0x00caa333; // 0x1014 AGC_Ctrl6
1738 pltmp[6] = 0xf6632112; // 0x1018 AGC_Ctrl7
1739 pltmp[7] = 0x0FA3F0ED; // 0x101c AGC_Ctrl8
1740 pltmp[8] = 0x04C43640; // 0x1020 AGC_Ctrl9
1741 pltmp[9] = 0x00002A79; // 0x1024 AGC_Ctrl10
1742 pltmp[10] = 0x40000228;
1743 pltmp[11] = 0x232A9F30;// 0x102c A_ACQ_Ctrl
1744 reg->BB2c = 0x232A9F30;
1745 Wb35Reg_BurstWrite( pHwData, 0x1000, pltmp, 12, AUTO_INCREMENT );
1747 pltmp[0] = 0x00002C54; // 0x1030 B_ACQ_Ctrl
1748 reg->BB30 = 0x00002C54;
1749 pltmp[1] = 0x00C0D6C5; // 0x1034 A_TXRX_Ctrl
1750 pltmp[2] = 0x5B2C8769; // 0x1038 B_TXRX_Ctrl
1751 pltmp[3] = 0x00000000; // 0x103c 11a TX LS filter
1752 reg->BB3c = 0x00000000;
1753 pltmp[4] = 0x00003F29; // 0x1040 11a TX LS filter
1754 pltmp[5] = 0x0EFEFBFE; // 0x1044 11a TX LS filter
1755 pltmp[6] = 0x00453B24; // 0x1048 11b TX RC filter
1756 pltmp[7] = 0x0E00FEFF; // 0x104c 11b TX RC filter
1757 pltmp[8] = 0x27106200; // 0x1050 MODE_Ctrl
1758 reg->BB50 = 0x27106200;
1759 pltmp[9] = 0; // 0x1054
1760 reg->BB54 = 0x00000000;
1761 pltmp[10] = 0x64645252; // 0x1058 IQ_Alpha
1762 reg->BB58 = 0x64645252;
1763 pltmp[11] = 0xAA0AC000; // 0x105c DC_Cancel
1764 Wb35Reg_BurstWrite( pHwData, 0x1030, pltmp, 12, AUTO_INCREMENT );
1766 BBProcessor_AL7230_2400( pHwData );
1768 Wb35Reg_Write( pHwData, 0x1070, 0x00000045 );
1769 break;
1771 case RF_WB_242:
1772 case RF_WB_242_1: // 20060619.5 Add
1774 pltmp[0] = 0x16A8525D; // 0x1000 AGC_Ctrl1
1775 pltmp[1] = 0x9AFF9ABA; // 0x1004 AGC_Ctrl2
1776 pltmp[2] = 0x55D00A04; // 0x1008 AGC_Ctrl3
1777 pltmp[3] = 0xEEE91C32; // 0x100c AGC_Ctrl4
1778 reg->BB0C = 0xEEE91C32;
1779 pltmp[4] = 0x0FACDCC5; // 0x1010 AGC_Ctrl5
1780 pltmp[5] = 0x000AA344; // 0x1014 AGC_Ctrl6
1781 pltmp[6] = 0x22222221; // 0x1018 AGC_Ctrl7
1782 pltmp[7] = 0x0FA3F0ED; // 0x101c AGC_Ctrl8
1783 pltmp[8] = 0x04CC3440; // 20051018 0x03CB3440; // 0x1020 AGC_Ctrl9 20051014 0x03C33440
1784 pltmp[9] = 0xA9002A79; // 0x1024 AGC_Ctrl10
1785 pltmp[10] = 0x40000528; // 0x1028
1786 pltmp[11] = 0x23457F30; // 0x102c A_ACQ_Ctrl
1787 reg->BB2C = 0x23457F30;
1788 Wb35Reg_BurstWrite( pHwData, 0x1000, pltmp, 12, AUTO_INCREMENT );
1790 pltmp[0] = 0x00002C54; // 0x1030 B_ACQ_Ctrl
1791 reg->BB30 = 0x00002C54;
1792 pltmp[1] = 0x00C0D6C5; // 0x1034 A_TXRX_Ctrl
1793 pltmp[2] = 0x5B2C8769; // 0x1038 B_TXRX_Ctrl
1794 pltmp[3] = pHwData->BB3c_cal; // 0x103c 11a TX LS filter
1795 reg->BB3C = pHwData->BB3c_cal;
1796 pltmp[4] = 0x00003F29; // 0x1040 11a TX LS filter
1797 pltmp[5] = 0x0EFEFBFE; // 0x1044 11a TX LS filter
1798 pltmp[6] = BB48_DEFAULT_WB242_11G; // 0x1048 11b TX RC filter 20060613.2
1799 reg->BB48 = BB48_DEFAULT_WB242_11G; // 20060613.1 20060613.2
1800 pltmp[7] = BB4C_DEFAULT_WB242_11G; // 0x104c 11b TX RC filter 20060613.2
1801 reg->BB4C = BB4C_DEFAULT_WB242_11G; // 20060613.1 20060613.2
1802 pltmp[8] = 0x27106208; // 0x1050 MODE_Ctrl
1803 reg->BB50 = 0x27106208;
1804 pltmp[9] = pHwData->BB54_cal; // 0x1054
1805 reg->BB54 = pHwData->BB54_cal;
1806 pltmp[10] = 0x52523131; // 0x1058 IQ_Alpha
1807 reg->BB58 = 0x52523131;
1808 pltmp[11] = 0xAA0AC000; // 20060825 0xAA2AC000; // 0x105c DC_Cancel
1809 Wb35Reg_BurstWrite( pHwData, 0x1030, pltmp, 12, AUTO_INCREMENT );
1811 Wb35Reg_Write( pHwData, 0x1070, 0x00000045 );
1812 break;
1815 // Fill the LNA table
1816 reg->LNAValue[0] = (u8)(reg->BB0C & 0xff);
1817 reg->LNAValue[1] = 0;
1818 reg->LNAValue[2] = (u8)((reg->BB0C & 0xff00)>>8);
1819 reg->LNAValue[3] = 0;
1821 // Fill SQ3 table
1822 for( i=0; i<MAX_SQ3_FILTER_SIZE; i++ )
1823 reg->SQ3_filter[i] = 0x2f; // half of Bit 0 ~ 6
1826 void set_tx_power_per_channel_max2829( struct hw_data * pHwData, ChanInfo Channel)
1828 RFSynthesizer_SetPowerIndex( pHwData, 100 ); // 20060620.1 Modify
1831 void set_tx_power_per_channel_al2230( struct hw_data * pHwData, ChanInfo Channel )
1833 u8 index = 100;
1835 if (pHwData->TxVgaFor24[Channel.ChanNo - 1] != 0xff) // 20060620.1 Add
1836 index = pHwData->TxVgaFor24[Channel.ChanNo - 1];
1838 RFSynthesizer_SetPowerIndex( pHwData, index );
1841 void set_tx_power_per_channel_al7230( struct hw_data * pHwData, ChanInfo Channel)
1843 u8 i, index = 100;
1845 switch ( Channel.band )
1847 case BAND_TYPE_DSSS:
1848 case BAND_TYPE_OFDM_24:
1850 if (pHwData->TxVgaFor24[Channel.ChanNo - 1] != 0xff)
1851 index = pHwData->TxVgaFor24[Channel.ChanNo - 1];
1853 break;
1854 case BAND_TYPE_OFDM_5:
1856 for (i =0; i<35; i++)
1858 if (Channel.ChanNo == pHwData->TxVgaFor50[i].ChanNo)
1860 if (pHwData->TxVgaFor50[i].TxVgaValue != 0xff)
1861 index = pHwData->TxVgaFor50[i].TxVgaValue;
1862 break;
1866 break;
1868 RFSynthesizer_SetPowerIndex( pHwData, index );
1871 void set_tx_power_per_channel_wb242( struct hw_data * pHwData, ChanInfo Channel)
1873 u8 index = 100;
1875 switch ( Channel.band )
1877 case BAND_TYPE_DSSS:
1878 case BAND_TYPE_OFDM_24:
1880 if (pHwData->TxVgaFor24[Channel.ChanNo - 1] != 0xff)
1881 index = pHwData->TxVgaFor24[Channel.ChanNo - 1];
1883 break;
1884 case BAND_TYPE_OFDM_5:
1885 break;
1887 RFSynthesizer_SetPowerIndex( pHwData, index );
1890 //=============================================================================================================
1891 // RFSynthesizer_SwitchingChannel --
1893 // Description:
1894 // Swithch the RF channel.
1896 // Arguments:
1897 // pHwData - Handle of the USB Device.
1898 // Channel - The channel no.
1900 // Return values:
1901 // None.
1902 //=============================================================================================================
1903 void
1904 RFSynthesizer_SwitchingChannel( struct hw_data * pHwData, ChanInfo Channel )
1906 struct wb35_reg *reg = &pHwData->reg;
1907 u32 pltmp[16]; // The 16 is the maximum capability of hardware
1908 u32 count, ltmp;
1909 u8 i, j, number;
1910 u8 ChnlTmp;
1912 switch( pHwData->phy_type )
1914 case RF_MAXIM_2825:
1915 case RF_MAXIM_V1: // 11g Winbond 2nd BB(with Phy board (v1) + Maxim 331)
1917 if( Channel.band <= BAND_TYPE_OFDM_24 ) // channel 1 ~ 13
1919 for( i=0; i<3; i++ )
1920 pltmp[i] = (1 << 31) | (0 << 30) | (18 << 24) | BitReverse( max2825_channel_data_24[Channel.ChanNo-1][i], 18);
1921 Wb35Reg_BurstWrite( pHwData, 0x0864, pltmp, 3, NO_INCREMENT );
1923 RFSynthesizer_SetPowerIndex( pHwData, 100 );
1924 break;
1926 case RF_MAXIM_2827:
1928 if( Channel.band <= BAND_TYPE_OFDM_24 ) // channel 1 ~ 13
1930 for( i=0; i<3; i++ )
1931 pltmp[i] = (1 << 31) | (0 << 30) | (18 << 24) | BitReverse( max2827_channel_data_24[Channel.ChanNo-1][i], 18);
1932 Wb35Reg_BurstWrite( pHwData, 0x0864, pltmp, 3, NO_INCREMENT );
1934 else if( Channel.band == BAND_TYPE_OFDM_5 ) // channel 36 ~ 64
1936 ChnlTmp = (Channel.ChanNo - 36) / 4;
1937 for( i=0; i<3; i++ )
1938 pltmp[i] = (1 << 31) | (0 << 30) | (18 << 24) | BitReverse( max2827_channel_data_50[ChnlTmp][i], 18);
1939 Wb35Reg_BurstWrite( pHwData, 0x0864, pltmp, 3, NO_INCREMENT );
1941 RFSynthesizer_SetPowerIndex( pHwData, 100 );
1942 break;
1944 case RF_MAXIM_2828:
1946 if( Channel.band <= BAND_TYPE_OFDM_24 ) // channel 1 ~ 13
1948 for( i=0; i<3; i++ )
1949 pltmp[i] = (1 << 31) | (0 << 30) | (18 << 24) | BitReverse( max2828_channel_data_24[Channel.ChanNo-1][i], 18);
1950 Wb35Reg_BurstWrite( pHwData, 0x0864, pltmp, 3, NO_INCREMENT );
1952 else if( Channel.band == BAND_TYPE_OFDM_5 ) // channel 36 ~ 64
1954 ChnlTmp = (Channel.ChanNo - 36) / 4;
1955 for ( i = 0; i < 3; i++)
1956 pltmp[i] = (1 << 31) | (0 << 30) | (18 << 24) | BitReverse( max2828_channel_data_50[ChnlTmp][i], 18);
1957 Wb35Reg_BurstWrite( pHwData, 0x0864, pltmp, 3, NO_INCREMENT );
1959 RFSynthesizer_SetPowerIndex( pHwData, 100 );
1960 break;
1962 case RF_MAXIM_2829:
1964 if( Channel.band <= BAND_TYPE_OFDM_24)
1966 for( i=0; i<3; i++ )
1967 pltmp[i] = (1 << 31) | (0 << 30) | (18 << 24) | BitReverse( max2829_channel_data_24[Channel.ChanNo-1][i], 18);
1968 Wb35Reg_BurstWrite( pHwData, 0x0864, pltmp, 3, NO_INCREMENT );
1970 else if( Channel.band == BAND_TYPE_OFDM_5 )
1972 count = sizeof(max2829_channel_data_50) / sizeof(max2829_channel_data_50[0]);
1974 for( i=0; i<count; i++ )
1976 if( max2829_channel_data_50[i][0] == Channel.ChanNo )
1978 for( j=0; j<3; j++ )
1979 pltmp[j] = (1 << 31) | (0 << 30) | (18 << 24) | BitReverse( max2829_channel_data_50[i][j+1], 18);
1980 Wb35Reg_BurstWrite( pHwData, 0x0864, pltmp, 3, NO_INCREMENT );
1982 if( (max2829_channel_data_50[i][3] & 0x3FFFF) == 0x2A946 )
1984 ltmp = (1 << 31) | (0 << 30) | (18 << 24) | BitReverse( (5<<18)|0x2A906, 18);
1985 Wb35Reg_Write( pHwData, 0x0864, ltmp );
1987 else // 0x2A9C6
1989 ltmp = (1 << 31) | (0 << 30) | (18 << 24) | BitReverse( (5<<18)|0x2A986, 18);
1990 Wb35Reg_Write( pHwData, 0x0864, ltmp );
1995 set_tx_power_per_channel_max2829( pHwData, Channel );
1996 break;
1998 case RF_AIROHA_2230:
1999 case RF_AIROHA_2230S: // 20060420 Add this
2001 if( Channel.band <= BAND_TYPE_OFDM_24 ) // channel 1 ~ 14
2003 for( i=0; i<2; i++ )
2004 pltmp[i] = (1 << 31) | (0 << 30) | (20 << 24) | BitReverse( al2230_channel_data_24[Channel.ChanNo-1][i], 20);
2005 Wb35Reg_BurstWrite( pHwData, 0x0864, pltmp, 2, NO_INCREMENT );
2007 set_tx_power_per_channel_al2230( pHwData, Channel );
2008 break;
2010 case RF_AIROHA_7230:
2012 //Start to fill RF parameters, PLL_ON should be pulled low.
2013 //Wb35Reg_Write( pHwData, 0x03dc, 0x00000000 );
2014 //printk("* PLL_ON low\n");
2016 //Channel independent registers
2017 if( Channel.band != pHwData->band)
2019 if (Channel.band <= BAND_TYPE_OFDM_24)
2021 //Update BB register
2022 BBProcessor_AL7230_2400(pHwData);
2024 number = sizeof(al7230_rf_data_24)/sizeof(al7230_rf_data_24[0]);
2025 Set_ChanIndep_RfData_al7230_24(pHwData, pltmp, number);
2027 else
2029 //Update BB register
2030 BBProcessor_AL7230_5000(pHwData);
2032 number = sizeof(al7230_rf_data_50)/sizeof(al7230_rf_data_50[0]);
2033 Set_ChanIndep_RfData_al7230_50(pHwData, pltmp, number);
2036 // Write to register. number must less and equal than 16
2037 Wb35Reg_BurstWrite( pHwData, 0x0864, pltmp, number, NO_INCREMENT );
2038 #ifdef _PE_STATE_DUMP_
2039 printk("Band changed\n");
2040 #endif
2043 if( Channel.band <= BAND_TYPE_OFDM_24 ) // channel 1 ~ 14
2045 for( i=0; i<2; i++ )
2046 pltmp[i] = (1 << 31) | (0 << 30) | (24 << 24) | (al7230_channel_data_24[Channel.ChanNo-1][i]&0xffffff);
2047 Wb35Reg_BurstWrite( pHwData, 0x0864, pltmp, 2, NO_INCREMENT );
2049 else if( Channel.band == BAND_TYPE_OFDM_5 )
2051 //Update Reg12
2052 if ((Channel.ChanNo > 64) && (Channel.ChanNo <= 165))
2054 ltmp = (1 << 31) | (0 << 30) | (24 << 24) | 0x00143c;
2055 Wb35Reg_Write( pHwData, 0x0864, ltmp );
2057 else //reg12 = 0x00147c at Channel 4920 ~ 5320
2059 ltmp = (1 << 31) | (0 << 30) | (24 << 24) | 0x00147c;
2060 Wb35Reg_Write( pHwData, 0x0864, ltmp );
2063 count = sizeof(al7230_channel_data_5) / sizeof(al7230_channel_data_5[0]);
2065 for (i=0; i<count; i++)
2067 if (al7230_channel_data_5[i][0] == Channel.ChanNo)
2069 for( j=0; j<3; j++ )
2070 pltmp[j] = (1 << 31) | (0 << 30) | (24 << 24) | ( al7230_channel_data_5[i][j+1]&0xffffff);
2071 Wb35Reg_BurstWrite( pHwData, 0x0864, pltmp, 3, NO_INCREMENT );
2075 set_tx_power_per_channel_al7230(pHwData, Channel);
2076 break;
2078 case RF_WB_242:
2079 case RF_WB_242_1: // 20060619.5 Add
2081 if( Channel.band <= BAND_TYPE_OFDM_24 ) // channel 1 ~ 14
2083 ltmp = (1 << 31) | (0 << 30) | (24 << 24) | BitReverse( w89rf242_channel_data_24[Channel.ChanNo-1][0], 24);
2084 Wb35Reg_Write( pHwData, 0x864, ltmp );
2086 set_tx_power_per_channel_wb242(pHwData, Channel);
2087 break;
2090 if( Channel.band <= BAND_TYPE_OFDM_24 )
2092 // BB: select 2.4 GHz, bit[12-11]=00
2093 reg->BB50 &= ~(BIT(11)|BIT(12));
2094 Wb35Reg_Write( pHwData, 0x1050, reg->BB50 ); // MODE_Ctrl
2095 // MAC: select 2.4 GHz, bit[5]=0
2096 reg->M78_ERPInformation &= ~BIT(5);
2097 Wb35Reg_Write( pHwData, 0x0878, reg->M78_ERPInformation );
2098 // enable 11b Baseband
2099 reg->BB30 &= ~BIT(31);
2100 Wb35Reg_Write( pHwData, 0x1030, reg->BB30 );
2102 else if( (Channel.band == BAND_TYPE_OFDM_5) )
2104 // BB: select 5 GHz
2105 reg->BB50 &= ~(BIT(11)|BIT(12));
2106 if (Channel.ChanNo <=64 )
2107 reg->BB50 |= BIT(12); // 10-5.25GHz
2108 else if ((Channel.ChanNo >= 100) && (Channel.ChanNo <= 124))
2109 reg->BB50 |= BIT(11); // 01-5.48GHz
2110 else if ((Channel.ChanNo >=128) && (Channel.ChanNo <= 161))
2111 reg->BB50 |= (BIT(12)|BIT(11)); // 11-5.775GHz
2112 else //Chan 184 ~ 196 will use bit[12-11] = 10 in version sh-src-1.2.25
2113 reg->BB50 |= BIT(12);
2114 Wb35Reg_Write( pHwData, 0x1050, reg->BB50 ); // MODE_Ctrl
2116 //(1) M78 should alway use 2.4G setting when using RF_AIROHA_7230
2117 //(2) BB30 has been updated previously.
2118 if (pHwData->phy_type != RF_AIROHA_7230)
2120 // MAC: select 5 GHz, bit[5]=1
2121 reg->M78_ERPInformation |= BIT(5);
2122 Wb35Reg_Write( pHwData, 0x0878, reg->M78_ERPInformation );
2124 // disable 11b Baseband
2125 reg->BB30 |= BIT(31);
2126 Wb35Reg_Write( pHwData, 0x1030, reg->BB30 );
2131 //Set the tx power directly from DUT GUI, not from the EEPROM. Return the current setting
2132 u8 RFSynthesizer_SetPowerIndex( struct hw_data * pHwData, u8 PowerIndex )
2134 u32 Band = pHwData->band;
2135 u8 index=0;
2137 if( pHwData->power_index == PowerIndex ) // 20060620.1 Add
2138 return PowerIndex;
2140 if (RF_MAXIM_2825 == pHwData->phy_type)
2142 // Channel 1 - 13
2143 index = RFSynthesizer_SetMaxim2825Power( pHwData, PowerIndex );
2145 else if (RF_MAXIM_2827 == pHwData->phy_type)
2147 if( Band <= BAND_TYPE_OFDM_24 ) // Channel 1 - 13
2148 index = RFSynthesizer_SetMaxim2827_24Power( pHwData, PowerIndex );
2149 else// if( Band == BAND_TYPE_OFDM_5 ) // Channel 36 - 64
2150 index = RFSynthesizer_SetMaxim2827_50Power( pHwData, PowerIndex );
2152 else if (RF_MAXIM_2828 == pHwData->phy_type)
2154 if( Band <= BAND_TYPE_OFDM_24 ) // Channel 1 - 13
2155 index = RFSynthesizer_SetMaxim2828_24Power( pHwData, PowerIndex );
2156 else// if( Band == BAND_TYPE_OFDM_5 ) // Channel 36 - 64
2157 index = RFSynthesizer_SetMaxim2828_50Power( pHwData, PowerIndex );
2159 else if( RF_AIROHA_2230 == pHwData->phy_type )
2161 //Power index: 0 ~ 63 // Channel 1 - 14
2162 index = RFSynthesizer_SetAiroha2230Power( pHwData, PowerIndex );
2163 index = (u8)al2230_txvga_data[index][1];
2165 else if( RF_AIROHA_2230S == pHwData->phy_type ) // 20060420 Add this
2167 //Power index: 0 ~ 63 // Channel 1 - 14
2168 index = RFSynthesizer_SetAiroha2230Power( pHwData, PowerIndex );
2169 index = (u8)al2230_txvga_data[index][1];
2171 else if( RF_AIROHA_7230 == pHwData->phy_type )
2173 //Power index: 0 ~ 63
2174 index = RFSynthesizer_SetAiroha7230Power( pHwData, PowerIndex );
2175 index = (u8)al7230_txvga_data[index][1];
2177 else if( (RF_WB_242 == pHwData->phy_type) ||
2178 (RF_WB_242_1 == pHwData->phy_type) ) // 20060619.5 Add
2180 //Power index: 0 ~ 19 for original. New range is 0 ~ 33
2181 index = RFSynthesizer_SetWinbond242Power( pHwData, PowerIndex );
2182 index = (u8)w89rf242_txvga_data[index][1];
2185 pHwData->power_index = index; // Backup current
2186 return index;
2189 //-- Sub function
2190 u8 RFSynthesizer_SetMaxim2828_24Power( struct hw_data * pHwData, u8 index )
2192 u32 PowerData;
2193 if( index > 1 ) index = 1;
2194 PowerData = (1 << 31) | (0 << 30) | (18 << 24) | BitReverse( max2828_power_data_24[index], 18);
2195 Wb35Reg_Write( pHwData, 0x0864, PowerData );
2196 return index;
2198 //--
2199 u8 RFSynthesizer_SetMaxim2828_50Power( struct hw_data * pHwData, u8 index )
2201 u32 PowerData;
2202 if( index > 1 ) index = 1;
2203 PowerData = (1 << 31) | (0 << 30) | (18 << 24) | BitReverse( max2828_power_data_50[index], 18);
2204 Wb35Reg_Write( pHwData, 0x0864, PowerData );
2205 return index;
2207 //--
2208 u8 RFSynthesizer_SetMaxim2827_24Power( struct hw_data * pHwData, u8 index )
2210 u32 PowerData;
2211 if( index > 1 ) index = 1;
2212 PowerData = (1 << 31) | (0 << 30) | (18 << 24) | BitReverse( max2827_power_data_24[index], 18);
2213 Wb35Reg_Write( pHwData, 0x0864, PowerData );
2214 return index;
2216 //--
2217 u8 RFSynthesizer_SetMaxim2827_50Power( struct hw_data * pHwData, u8 index )
2219 u32 PowerData;
2220 if( index > 1 ) index = 1;
2221 PowerData = (1 << 31) | (0 << 30) | (18 << 24) | BitReverse( max2827_power_data_50[index], 18);
2222 Wb35Reg_Write( pHwData, 0x0864, PowerData );
2223 return index;
2225 //--
2226 u8 RFSynthesizer_SetMaxim2825Power( struct hw_data * pHwData, u8 index )
2228 u32 PowerData;
2229 if( index > 1 ) index = 1;
2230 PowerData = (1 << 31) | (0 << 30) | (18 << 24) | BitReverse( max2825_power_data_24[index], 18);
2231 Wb35Reg_Write( pHwData, 0x0864, PowerData );
2232 return index;
2234 //--
2235 u8 RFSynthesizer_SetAiroha2230Power( struct hw_data * pHwData, u8 index )
2237 u32 PowerData;
2238 u8 i,count;
2240 count = sizeof(al2230_txvga_data) / sizeof(al2230_txvga_data[0]);
2241 for (i=0; i<count; i++)
2243 if (al2230_txvga_data[i][1] >= index)
2244 break;
2246 if (i == count)
2247 i--;
2249 PowerData = (1 << 31) | (0 << 30) | (20 << 24) | BitReverse( al2230_txvga_data[i][0], 20);
2250 Wb35Reg_Write( pHwData, 0x0864, PowerData );
2251 return i;
2253 //--
2254 u8 RFSynthesizer_SetAiroha7230Power( struct hw_data * pHwData, u8 index )
2256 u32 PowerData;
2257 u8 i,count;
2259 //PowerData = (1 << 31) | (0 << 30) | (20 << 24) | BitReverse( airoha_power_data_24[index], 20);
2260 count = sizeof(al7230_txvga_data) / sizeof(al7230_txvga_data[0]);
2261 for (i=0; i<count; i++)
2263 if (al7230_txvga_data[i][1] >= index)
2264 break;
2266 if (i == count)
2267 i--;
2268 PowerData = (1 << 31) | (0 << 30) | (24 << 24) | (al7230_txvga_data[i][0]&0xffffff);
2269 Wb35Reg_Write( pHwData, 0x0864, PowerData );
2270 return i;
2273 u8 RFSynthesizer_SetWinbond242Power( struct hw_data * pHwData, u8 index )
2275 u32 PowerData;
2276 u8 i,count;
2278 count = sizeof(w89rf242_txvga_data) / sizeof(w89rf242_txvga_data[0]);
2279 for (i=0; i<count; i++)
2281 if (w89rf242_txvga_data[i][1] >= index)
2282 break;
2284 if (i == count)
2285 i--;
2287 // Set TxVga into RF
2288 PowerData = (1 << 31) | (0 << 30) | (24 << 24) | BitReverse( w89rf242_txvga_data[i][0], 24);
2289 Wb35Reg_Write( pHwData, 0x0864, PowerData );
2291 // Update BB48 BB4C BB58 for high precision txvga
2292 Wb35Reg_Write( pHwData, 0x1048, w89rf242_txvga_data[i][2] );
2293 Wb35Reg_Write( pHwData, 0x104c, w89rf242_txvga_data[i][3] );
2294 Wb35Reg_Write( pHwData, 0x1058, w89rf242_txvga_data[i][4] );
2296 // Rf vga 0 ~ 3 for temperature compensate. It will affect the scan Bss.
2297 // The i value equals to 8 or 7 usually. So It's not necessary to setup this RF register.
2298 // if( i <= 3 )
2299 // PowerData = (1 << 31) | (0 << 30) | (24 << 24) | BitReverse( 0x000024, 24 );
2300 // else
2301 // PowerData = (1 << 31) | (0 << 30) | (24 << 24) | BitReverse( 0x001824, 24 );
2302 // Wb35Reg_Write( pHwData, 0x0864, PowerData );
2303 return i;
2306 //===========================================================================================================
2307 // Dxx_initial --
2308 // Mxx_initial --
2310 // Routine Description:
2311 // Initial the hardware setting and module variable
2313 //===========================================================================================================
2314 void Dxx_initial( struct hw_data * pHwData )
2316 struct wb35_reg *reg = &pHwData->reg;
2318 // Old IC:Single mode only.
2319 // New IC: operation decide by Software set bit[4]. 1:multiple 0: single
2320 reg->D00_DmaControl = 0xc0000004; //Txon, Rxon, multiple Rx for new 4k DMA
2321 //Txon, Rxon, single Rx for old 8k ASIC
2322 if( !HAL_USB_MODE_BURST( pHwData ) )
2323 reg->D00_DmaControl = 0xc0000000;//Txon, Rxon, single Rx for new 4k DMA
2325 Wb35Reg_WriteSync( pHwData, 0x0400, reg->D00_DmaControl );
2328 void Mxx_initial( struct hw_data * pHwData )
2330 struct wb35_reg *reg = &pHwData->reg;
2331 u32 tmp;
2332 u32 pltmp[11];
2333 u16 i;
2336 //======================================================
2337 // Initial Mxx register
2338 //======================================================
2340 // M00 bit set
2341 #ifdef _IBSS_BEACON_SEQ_STICK_
2342 reg->M00_MacControl = 0; // Solve beacon sequence number stop by software
2343 #else
2344 reg->M00_MacControl = 0x80000000; // Solve beacon sequence number stop by hardware
2345 #endif
2347 // M24 disable enter power save, BB RxOn and enable NAV attack
2348 reg->M24_MacControl = 0x08040042;
2349 pltmp[0] = reg->M24_MacControl;
2351 pltmp[1] = 0; // Skip M28, because no initialize value is required.
2353 // M2C CWmin and CWmax setting
2354 pHwData->cwmin = DEFAULT_CWMIN;
2355 pHwData->cwmax = DEFAULT_CWMAX;
2356 reg->M2C_MacControl = DEFAULT_CWMIN << 10;
2357 reg->M2C_MacControl |= DEFAULT_CWMAX;
2358 pltmp[2] = reg->M2C_MacControl;
2360 // M30 BSSID
2361 pltmp[3] = *(u32 *)pHwData->bssid;
2363 // M34
2364 pHwData->AID = DEFAULT_AID;
2365 tmp = *(u16 *)(pHwData->bssid+4);
2366 tmp |= DEFAULT_AID << 16;
2367 pltmp[4] = tmp;
2369 // M38
2370 reg->M38_MacControl = (DEFAULT_RATE_RETRY_LIMIT<<8) | (DEFAULT_LONG_RETRY_LIMIT << 4) | DEFAULT_SHORT_RETRY_LIMIT;
2371 pltmp[5] = reg->M38_MacControl;
2373 // M3C
2374 tmp = (DEFAULT_PIFST << 26) | (DEFAULT_EIFST << 16) | (DEFAULT_DIFST << 8) | (DEFAULT_SIFST << 4) | DEFAULT_OSIFST ;
2375 reg->M3C_MacControl = tmp;
2376 pltmp[6] = tmp;
2378 // M40
2379 pHwData->slot_time_select = DEFAULT_SLOT_TIME;
2380 tmp = (DEFAULT_ATIMWD << 16) | DEFAULT_SLOT_TIME;
2381 reg->M40_MacControl = tmp;
2382 pltmp[7] = tmp;
2384 // M44
2385 tmp = DEFAULT_MAX_TX_MSDU_LIFE_TIME << 10; // *1024
2386 reg->M44_MacControl = tmp;
2387 pltmp[8] = tmp;
2389 // M48
2390 pHwData->BeaconPeriod = DEFAULT_BEACON_INTERVAL;
2391 pHwData->ProbeDelay = DEFAULT_PROBE_DELAY_TIME;
2392 tmp = (DEFAULT_BEACON_INTERVAL << 16) | DEFAULT_PROBE_DELAY_TIME;
2393 reg->M48_MacControl = tmp;
2394 pltmp[9] = tmp;
2396 //M4C
2397 reg->M4C_MacStatus = (DEFAULT_PROTOCOL_VERSION << 30) | (DEFAULT_MAC_POWER_STATE << 28) | (DEFAULT_DTIM_ALERT_TIME << 24);
2398 pltmp[10] = reg->M4C_MacStatus;
2400 // Burst write
2401 //Wb35Reg_BurstWrite( pHwData, 0x0824, pltmp, 11, AUTO_INCREMENT );
2402 for( i=0; i<11; i++ )
2403 Wb35Reg_WriteSync( pHwData, 0x0824 + i*4, pltmp[i] );
2405 // M60
2406 Wb35Reg_WriteSync( pHwData, 0x0860, 0x12481248 );
2407 reg->M60_MacControl = 0x12481248;
2409 // M68
2410 Wb35Reg_WriteSync( pHwData, 0x0868, 0x00050900 ); // 20051018 0x000F0F00 ); // 940930 0x00131300
2411 reg->M68_MacControl = 0x00050900;
2413 // M98
2414 Wb35Reg_WriteSync( pHwData, 0x0898, 0xffff8888 );
2415 reg->M98_MacControl = 0xffff8888;
2419 void Uxx_power_off_procedure( struct hw_data * pHwData )
2421 // SW, PMU reset and turn off clock
2422 Wb35Reg_WriteSync( pHwData, 0x03b0, 3 );
2423 Wb35Reg_WriteSync( pHwData, 0x03f0, 0xf9 );
2426 //Decide the TxVga of every channel
2427 void GetTxVgaFromEEPROM( struct hw_data * pHwData )
2429 u32 i, j, ltmp;
2430 u16 Value[MAX_TXVGA_EEPROM];
2431 u8 *pctmp;
2432 u8 ctmp=0;
2434 // Get the entire TxVga setting in EEPROM
2435 for( i=0; i<MAX_TXVGA_EEPROM; i++ )
2437 Wb35Reg_WriteSync( pHwData, 0x03b4, 0x08100000 + 0x00010000*i );
2438 Wb35Reg_ReadSync( pHwData, 0x03b4, &ltmp );
2439 Value[i] = (u16)( ltmp & 0xffff ); // Get 16 bit available
2440 Value[i] = cpu_to_le16( Value[i] ); // [7:0]2412 [7:0]2417 ....
2443 // Adjust the filed which fills with reserved value.
2444 pctmp = (u8 *)Value;
2445 for( i=0; i<(MAX_TXVGA_EEPROM*2); i++ )
2447 if( pctmp[i] != 0xff )
2448 ctmp = pctmp[i];
2449 else
2450 pctmp[i] = ctmp;
2453 // Adjust WB_242 to WB_242_1 TxVga scale
2454 if( pHwData->phy_type == RF_WB_242 )
2456 for( i=0; i<4; i++ ) // Only 2412 2437 2462 2484 case must be modified
2458 for( j=0; j<(sizeof(w89rf242_txvga_old_mapping)/sizeof(w89rf242_txvga_old_mapping[0])); j++ )
2460 if( pctmp[i] < (u8)w89rf242_txvga_old_mapping[j][1] )
2462 pctmp[i] = (u8)w89rf242_txvga_old_mapping[j][0];
2463 break;
2467 if( j == (sizeof(w89rf242_txvga_old_mapping)/sizeof(w89rf242_txvga_old_mapping[0])) )
2468 pctmp[i] = (u8)w89rf242_txvga_old_mapping[j-1][0];
2472 // 20060621 Add
2473 memcpy( pHwData->TxVgaSettingInEEPROM, pctmp, MAX_TXVGA_EEPROM*2 ); //MAX_TXVGA_EEPROM is u16 count
2474 EEPROMTxVgaAdjust( pHwData );
2477 // This function will affect the TxVga parameter in HAL. If hal_set_current_channel
2478 // or RFSynthesizer_SetPowerIndex be called, new TxVga will take effect.
2479 // TxVgaSettingInEEPROM of sHwData is an u8 array point to EEPROM contain for IS89C35
2480 // This function will use default TxVgaSettingInEEPROM data to calculate new TxVga.
2481 void EEPROMTxVgaAdjust( struct hw_data * pHwData ) // 20060619.5 Add
2483 u8 * pTxVga = pHwData->TxVgaSettingInEEPROM;
2484 s16 i, stmp;
2486 //-- 2.4G -- 20060704.2 Request from Tiger
2487 //channel 1 ~ 5
2488 stmp = pTxVga[1] - pTxVga[0];
2489 for( i=0; i<5; i++ )
2490 pHwData->TxVgaFor24[i] = pTxVga[0] + stmp*i/4;
2491 //channel 6 ~ 10
2492 stmp = pTxVga[2] - pTxVga[1];
2493 for( i=5; i<10; i++ )
2494 pHwData->TxVgaFor24[i] = pTxVga[1] + stmp*(i-5)/4;
2495 //channel 11 ~ 13
2496 stmp = pTxVga[3] - pTxVga[2];
2497 for( i=10; i<13; i++ )
2498 pHwData->TxVgaFor24[i] = pTxVga[2] + stmp*(i-10)/2;
2499 //channel 14
2500 pHwData->TxVgaFor24[13] = pTxVga[3];
2502 //-- 5G --
2503 if( pHwData->phy_type == RF_AIROHA_7230 )
2505 //channel 184
2506 pHwData->TxVgaFor50[0].ChanNo = 184;
2507 pHwData->TxVgaFor50[0].TxVgaValue = pTxVga[4];
2508 //channel 196
2509 pHwData->TxVgaFor50[3].ChanNo = 196;
2510 pHwData->TxVgaFor50[3].TxVgaValue = pTxVga[5];
2511 //interpolate
2512 pHwData->TxVgaFor50[1].ChanNo = 188;
2513 pHwData->TxVgaFor50[2].ChanNo = 192;
2514 stmp = pTxVga[5] - pTxVga[4];
2515 pHwData->TxVgaFor50[2].TxVgaValue = pTxVga[5] - stmp/3;
2516 pHwData->TxVgaFor50[1].TxVgaValue = pTxVga[5] - stmp*2/3;
2518 //channel 16
2519 pHwData->TxVgaFor50[6].ChanNo = 16;
2520 pHwData->TxVgaFor50[6].TxVgaValue = pTxVga[6];
2521 pHwData->TxVgaFor50[4].ChanNo = 8;
2522 pHwData->TxVgaFor50[4].TxVgaValue = pTxVga[6];
2523 pHwData->TxVgaFor50[5].ChanNo = 12;
2524 pHwData->TxVgaFor50[5].TxVgaValue = pTxVga[6];
2526 //channel 36
2527 pHwData->TxVgaFor50[8].ChanNo = 36;
2528 pHwData->TxVgaFor50[8].TxVgaValue = pTxVga[7];
2529 pHwData->TxVgaFor50[7].ChanNo = 34;
2530 pHwData->TxVgaFor50[7].TxVgaValue = pTxVga[7];
2531 pHwData->TxVgaFor50[9].ChanNo = 38;
2532 pHwData->TxVgaFor50[9].TxVgaValue = pTxVga[7];
2534 //channel 40
2535 pHwData->TxVgaFor50[10].ChanNo = 40;
2536 pHwData->TxVgaFor50[10].TxVgaValue = pTxVga[8];
2537 //channel 48
2538 pHwData->TxVgaFor50[14].ChanNo = 48;
2539 pHwData->TxVgaFor50[14].TxVgaValue = pTxVga[9];
2540 //interpolate
2541 pHwData->TxVgaFor50[11].ChanNo = 42;
2542 pHwData->TxVgaFor50[12].ChanNo = 44;
2543 pHwData->TxVgaFor50[13].ChanNo = 46;
2544 stmp = pTxVga[9] - pTxVga[8];
2545 pHwData->TxVgaFor50[13].TxVgaValue = pTxVga[9] - stmp/4;
2546 pHwData->TxVgaFor50[12].TxVgaValue = pTxVga[9] - stmp*2/4;
2547 pHwData->TxVgaFor50[11].TxVgaValue = pTxVga[9] - stmp*3/4;
2549 //channel 52
2550 pHwData->TxVgaFor50[15].ChanNo = 52;
2551 pHwData->TxVgaFor50[15].TxVgaValue = pTxVga[10];
2552 //channel 64
2553 pHwData->TxVgaFor50[18].ChanNo = 64;
2554 pHwData->TxVgaFor50[18].TxVgaValue = pTxVga[11];
2555 //interpolate
2556 pHwData->TxVgaFor50[16].ChanNo = 56;
2557 pHwData->TxVgaFor50[17].ChanNo = 60;
2558 stmp = pTxVga[11] - pTxVga[10];
2559 pHwData->TxVgaFor50[17].TxVgaValue = pTxVga[11] - stmp/3;
2560 pHwData->TxVgaFor50[16].TxVgaValue = pTxVga[11] - stmp*2/3;
2562 //channel 100
2563 pHwData->TxVgaFor50[19].ChanNo = 100;
2564 pHwData->TxVgaFor50[19].TxVgaValue = pTxVga[12];
2565 //channel 112
2566 pHwData->TxVgaFor50[22].ChanNo = 112;
2567 pHwData->TxVgaFor50[22].TxVgaValue = pTxVga[13];
2568 //interpolate
2569 pHwData->TxVgaFor50[20].ChanNo = 104;
2570 pHwData->TxVgaFor50[21].ChanNo = 108;
2571 stmp = pTxVga[13] - pTxVga[12];
2572 pHwData->TxVgaFor50[21].TxVgaValue = pTxVga[13] - stmp/3;
2573 pHwData->TxVgaFor50[20].TxVgaValue = pTxVga[13] - stmp*2/3;
2575 //channel 128
2576 pHwData->TxVgaFor50[26].ChanNo = 128;
2577 pHwData->TxVgaFor50[26].TxVgaValue = pTxVga[14];
2578 //interpolate
2579 pHwData->TxVgaFor50[23].ChanNo = 116;
2580 pHwData->TxVgaFor50[24].ChanNo = 120;
2581 pHwData->TxVgaFor50[25].ChanNo = 124;
2582 stmp = pTxVga[14] - pTxVga[13];
2583 pHwData->TxVgaFor50[25].TxVgaValue = pTxVga[14] - stmp/4;
2584 pHwData->TxVgaFor50[24].TxVgaValue = pTxVga[14] - stmp*2/4;
2585 pHwData->TxVgaFor50[23].TxVgaValue = pTxVga[14] - stmp*3/4;
2587 //channel 140
2588 pHwData->TxVgaFor50[29].ChanNo = 140;
2589 pHwData->TxVgaFor50[29].TxVgaValue = pTxVga[15];
2590 //interpolate
2591 pHwData->TxVgaFor50[27].ChanNo = 132;
2592 pHwData->TxVgaFor50[28].ChanNo = 136;
2593 stmp = pTxVga[15] - pTxVga[14];
2594 pHwData->TxVgaFor50[28].TxVgaValue = pTxVga[15] - stmp/3;
2595 pHwData->TxVgaFor50[27].TxVgaValue = pTxVga[15] - stmp*2/3;
2597 //channel 149
2598 pHwData->TxVgaFor50[30].ChanNo = 149;
2599 pHwData->TxVgaFor50[30].TxVgaValue = pTxVga[16];
2600 //channel 165
2601 pHwData->TxVgaFor50[34].ChanNo = 165;
2602 pHwData->TxVgaFor50[34].TxVgaValue = pTxVga[17];
2603 //interpolate
2604 pHwData->TxVgaFor50[31].ChanNo = 153;
2605 pHwData->TxVgaFor50[32].ChanNo = 157;
2606 pHwData->TxVgaFor50[33].ChanNo = 161;
2607 stmp = pTxVga[17] - pTxVga[16];
2608 pHwData->TxVgaFor50[33].TxVgaValue = pTxVga[17] - stmp/4;
2609 pHwData->TxVgaFor50[32].TxVgaValue = pTxVga[17] - stmp*2/4;
2610 pHwData->TxVgaFor50[31].TxVgaValue = pTxVga[17] - stmp*3/4;
2613 #ifdef _PE_STATE_DUMP_
2614 printk(" TxVgaFor24 : \n");
2615 DataDmp((u8 *)pHwData->TxVgaFor24, 14 ,0);
2616 printk(" TxVgaFor50 : \n");
2617 DataDmp((u8 *)pHwData->TxVgaFor50, 70 ,0);
2618 #endif
2621 void BBProcessor_RateChanging( struct hw_data * pHwData, u8 rate ) // 20060613.1
2623 struct wb35_reg *reg = &pHwData->reg;
2624 unsigned char Is11bRate;
2626 Is11bRate = (rate % 6) ? 1 : 0;
2627 switch( pHwData->phy_type )
2629 case RF_AIROHA_2230:
2630 case RF_AIROHA_2230S: // 20060420 Add this
2631 if( Is11bRate )
2633 if( (reg->BB48 != BB48_DEFAULT_AL2230_11B) &&
2634 (reg->BB4C != BB4C_DEFAULT_AL2230_11B) )
2636 Wb35Reg_Write( pHwData, 0x1048, BB48_DEFAULT_AL2230_11B );
2637 Wb35Reg_Write( pHwData, 0x104c, BB4C_DEFAULT_AL2230_11B );
2640 else
2642 if( (reg->BB48 != BB48_DEFAULT_AL2230_11G) &&
2643 (reg->BB4C != BB4C_DEFAULT_AL2230_11G) )
2645 Wb35Reg_Write( pHwData, 0x1048, BB48_DEFAULT_AL2230_11G );
2646 Wb35Reg_Write( pHwData, 0x104c, BB4C_DEFAULT_AL2230_11G );
2649 break;
2651 case RF_WB_242: // 20060623 The fix only for old TxVGA setting
2652 if( Is11bRate )
2654 if( (reg->BB48 != BB48_DEFAULT_WB242_11B) &&
2655 (reg->BB4C != BB4C_DEFAULT_WB242_11B) )
2657 reg->BB48 = BB48_DEFAULT_WB242_11B;
2658 reg->BB4C = BB4C_DEFAULT_WB242_11B;
2659 Wb35Reg_Write( pHwData, 0x1048, BB48_DEFAULT_WB242_11B );
2660 Wb35Reg_Write( pHwData, 0x104c, BB4C_DEFAULT_WB242_11B );
2663 else
2665 if( (reg->BB48 != BB48_DEFAULT_WB242_11G) &&
2666 (reg->BB4C != BB4C_DEFAULT_WB242_11G) )
2668 reg->BB48 = BB48_DEFAULT_WB242_11G;
2669 reg->BB4C = BB4C_DEFAULT_WB242_11G;
2670 Wb35Reg_Write( pHwData, 0x1048, BB48_DEFAULT_WB242_11G );
2671 Wb35Reg_Write( pHwData, 0x104c, BB4C_DEFAULT_WB242_11G );
2674 break;