RW1092 - NewHaven Display

RW1092
Dot Matrix Type LCD Controller
FEATURES
Direct display of RAM data through the display data
RAM.
RAM capacity：192 x 97 = 18624bits
Display duty selectable by hardware
1/97 duty： 97common x 160segment
1/65 duty： 65common x 192segment
1/33 duty： 33common x 192segment
1/17 duty： 17common x 192segment
1/9 duty： 9 common x 192segment
1/5 duty： 5 common x 192segment
Static
： 1 common x 192segment
Both 6800 and 8080 series MPU can directly
connected by 8-bit parallel interface, also 4 line / 3
line serial interface and IIC interface are
supportable.
Abundant command functions
Low-power liquid crystal display power supply circuit
equipped internally.
Bias set 1/2 1/3 1/4 1/5 1/6 1/7 1/8 1/9 1/10 by
software
Booster circuit (with Boost ratios of
2X/3X/4X/5X/6X/7X,
where the step-up voltage reference power supply
can be input externally).
V0 voltage regulator resistors equipped internally,
V1 to VSS voltage divider resistors equipped
internally, electronic volume function equipped
internally, voltage follower
CR oscillator circuit equipped internally (external
clock can also be input)
Low power consumption.
Logic power supply VDD – VSS = 1.8V to 3.6 V
Boost reference voltage: VDD2 – VSS = 2.4V to
3.6V
Booster maximum voltage limited VOUT=18.0V
Liquid crystal drive power supply:
V0 – VSS = 5.0V to 14.0 V
Wide range of operating temperatures: –40 to 85°C
CMOS process
Shipping forms include bare chip and COG.
Software compatible to
SED1065/SED1565/SED1575
Static Display function support
GENERAL DESCRIPTION
The RW1092 is a single-chip dot matrix LCD driver that can
be connected directly to a microprocessor bus. 8-bit parallel
or serial display data sent from the microprocessor is stored
in the internal display data RAM and the chip generates a
LCD drive signal independent of the microprocessor.
Because the chips in the RW1092 contain 97x192 bits of
display data RAM and there is a 1-to-1 correspondence
between the LCD panel pixels and the internal RAM bits,
these chips enable displays with a high degree of freedom.
PART NO.
RW1092
The chips are able to minimize power consumption
because no external operating clock is necessary for
the display data RAM read/write operation.
Furthermore, because each chip is equipped
internally with a low-power LCD driver power supply,
and a display clock CR oscillator circuit, the
RW1092 can be used to create the lowest power
display system with the fewest components for
High-performance portable devices.
VRS temperature gradient
-0.05%/°C
1
VRS range
2.1V ±0.03V
Rev1.4-13 Sep 2010
RW1092
Dot Matrix Type LCD Controller
RW1092 Revision History
Version
Date
1.0
2010/01/04
1.1
2010/05/18
1.2
2010/07/12
Description
Add static on Function 、Add 3SPI data length command、N-line
Reversal Function valid for all mode
Add application circuit and static application note, modify the
chip thickness to 500um
Add external RA、RB use command and Frame frequency
adjustment command
Make correction for numbers of duty.
1.3
2010/08/12 P.1, P.4 ~P.9, P.10 ~ P.15, P.16 ~ P.21, P.22~ P.27,
P.28 ~ P.33, P.34 ~ P.39, P.43, P.44, P.48, P.49
1.4
2010/9/13
Modify Power of sequence
2
Rev1.4-13 Sep 2010
RW1092
Dot Matrix Type LCD Controller
PAD ARRANGEMENT
Chip Size:
6,294μm x 1,074 μm
Min. Bump Pitch: 30μm(Min.)
Bump Size:
PAD No. 001～009
PAD No. 010～104
PAD No. 105～113
PAD No. 114～138
PAD No. 139～328
PAD No. 329～353
22.4μm x 81μm
35μm x 52μm
22.4μm x 81μm
81μm x 22.4μm
15μm x 124μm
81μm x 22.4μm
Bump Height:
15μm(Typ)
Chip Thickness: 500 μm
1
9
10
104
105
113
114
353
( 0, 0 )
138
329
328
139
(-2468.73,296.79)
60μm
60μm
15μm
30μm
15μm
30μm
15μm
15μm
15μm
15μm
28μm
30μm
45μm
(2870.19, 166.47)
3
Rev1.4-13 Sep 2010
RW1092
Dot Matrix Type LCD Controller
PAD Coordinate(1/97 Duty, SHL=0,3-1)
Pad No. Pad Name
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
32
33
34
35
36
37
38
39
40
COM[88]
COM[89]
COM[90]
COM[91]
COM[92]
COM[93]
COM[94]
COM[95]
COMS1
STACOM
VSS
CS1B
CS2
VDD
RSTP
A0
VSS
X
2843.23
2805.83
2768.43
2731.03
2693.63
2656.23
2618.83
2581.43
2544.03
2424.72
2370.61
2318.55
2268.55
2214.47
2162.38
2112.38
2058.3
RW(XWR) 2006.21
E(XRD) 1956.21
VDD
1902.13
D0
1850.04
D1
1800.04
D2
1750.04
D3
1700.04
D4
1650.04
D5
1600.04
D6
1550.04
D7
1500.04
VDD
1450.04
VDD
1400.04
VDD
1350.04
VDD
1300.04
VDD2 1250.04
VDD2 1200.04
VDD2 1150.04
VDD2 1100.04
VSS
1050.04
VSS
1000.04
VSS
950.04
VSS
900.04
Y
Pad No.
445
445
445
445
445
445
445
445
445
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
41
42
43
44
45
46
47
48
49
50
51
52
53
54
55
56
57
58
59
60
61
62
63
64
65
66
67
68
69
70
71
72
73
74
75
76
77
78
79
80
Pad
Name
VOUT
VOUT
VOUT
VOUT
CAP5P
CAP5P
CAP1N
CAP1N
CAP3P
CAP3P
CAP1N
CAP1N
CAP1P
CAP1P
CAP2P
CAP2P
CAP2N
CAP2N
CAP4P
CAP4P
CAP2N
CAP2N
CAP6P
CAP6P
VSS
VRS
VDD
V4
V4
V3
V3
V2
V2
V1
V1
V0
V0
VRAB
VDD
T[8]
X
Y
843.94
793.94
743.94
693.94
637.84
587.84
537.84
487.84
437.84
387.84
337.84
287.84
237.84
187.84
137.84
87.84
37.84
-12.16
-62.16
-112.16
-162.16
-212.16
-262.16
-312.16
-371.7
-424.72
-477.72
-535.04
-585.04
-635.04
-685.04
-735.04
-785.04
-835.04
-885.04
-935.04
-985.04
-1035.04
-1097.58
-1147.58
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
4
Pad No. Pad Name
81
82
83
84
85
86
87
88
89
90
91
92
93
94
95
96
97
98
99
100
101
102
103
104
105
106
107
108
109
110
111
112
113
114
115
116
117
118
119
120
T[7]
T[6]
T[5]
T[4]
T[3]
T[2]
T[1]
T[0]
VDD
CLS
VSS
C86
VDD
PSB
VSS
IRS
VDD
SEL1
VSS
SEL2
VDD
SEL3
VSS
V0
COM[47]
COM[46]
COM[45]
COM[44]
COM[43]
COM[42]
COM[41]
COM[40]
COM[39]
COM[38]
COM[37]
COM[36]
COM[35]
COM[34]
COM[33]
COM[32]
X
Y
-1197.58
-1247.58
-1297.58
-1347.58
-1397.58
-1447.58
-1497.58
-1547.58
-1599.67
-1653.75
-1705.84
-1759.92
-1812.01
-1866.09
-1918.18
-1972.26
-2024.35
-2078.43
-2130.52
-2184.6
-2236.69
-2290.77
-2340.77
-2396.87
-2544.03
-2581.43
-2618.83
-2656.23
-2693.63
-2731.03
-2768.43
-2805.83
-2843.23
-3055
-3055
-3055
-3055
-3055
-3055
-3055
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
445
445
445
445
445
445
445
445
445
449.1
411.7
374.3
336.9
299.5
262.1
224.7
Rev1.4-13 Sep 2010
RW1092
Dot Matrix Type LCD Controller
PAD Coordinate(1/97 Duty, SHL=0,3-2)
Pad No. Pad Name
121
122
123
124
125
126
127
128
129
130
131
132
133
134
135
136
137
138
139
140
141
142
143
144
145
146
147
148
149
150
151
152
153
154
155
156
157
158
159
160
COM[31]
COM[30]
COM[29]
COM[28]
COM[27]
COM[26]
COM[25]
COM[24]
COM[23]
COM[22]
COM[21]
COM[20]
COM[19]
COM[18]
COM[17]
COM[16]
COM[15]
COM[14]
COM[13]
COM[12]
COM[11]
COM[10]
COM[9]
COM[8]
COM[7]
COM[6]
COM[5]
COM[4]
COM[3]
COM[2]
COM[1]
COM[0]
COMS2
SEG[0]
SEG[1]
SEG[2]
SEG[3]
SEG[4]
SEG[5]
SEG[6]
X
Y
Pad No.
-3055
-3055
-3055
-3055
-3055
-3055
-3055
-3055
-3055
-3055
-3055
-3055
-3055
-3055
-3055
-3055
-3055
-3055
-2835.3
-2805.3
-2775.3
-2745.3
-2715.3
-2685.3
-2655.3
-2625.3
-2595.3
-2565.3
-2535.3
-2505.3
-2475.3
-2445.3
-2415.3
-2385.3
-2355.3
-2325.3
-2295.3
-2265.3
-2235.3
-2205.3
187.3
149.9
112.5
75.1
37.7
0.3
-37.1
-74.5
-111.9
-149.3
-186.7
-224.1
-261.5
-298.9
-336.3
-373.7
-411.1
-448.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
161
162
163
164
165
166
167
168
169
170
171
172
173
174
175
176
177
178
179
180
181
182
183
184
185
186
187
188
189
190
191
192
193
194
195
196
197
198
199
200
Pad
Name
SEG[7]
SEG[8]
SEG[9]
SEG[10]
SEG[11]
SEG[12]
SEG[13]
SEG[14]
SEG[15]
SEG[16]
SEG[17]
SEG[18]
SEG[19]
SEG[20]
SEG[21]
SEG[22]
SEG[23]
SEG[24]
SEG[25]
SEG[26]
SEG[27]
SEG[28]
SEG[29]
SEG[30]
SEG[31]
SEG[32]
SEG[33]
SEG[34]
SEG[35]
SEG[36]
SEG[37]
SEG[38]
SEG[39]
SEG[40]
SEG[41]
SEG[42]
SEG[43]
SEG[44]
SEG[45]
SEG[46]
X
Y
Pad No.
-2175.3
-2145.3
-2115.3
-2085.3
-2055.3
-2025.3
-1995.3
-1965.3
-1935.3
-1905.3
-1875.3
-1845.3
-1815.3
-1785.3
-1755.3
-1725.3
-1695.3
-1665.3
-1635.3
-1605.3
-1575.3
-1545.3
-1515.3
-1485.3
-1455.3
-1425.3
-1395.3
-1365.3
-1335.3
-1305.3
-1275.3
-1245.3
-1215.3
-1185.3
-1155.3
-1125.3
-1095.3
-1065.3
-1035.3
-1005.3
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
201
202
203
204
205
206
207
208
209
210
211
212
213
214
215
216
217
218
219
220
221
222
223
224
225
226
227
228
229
230
231
232
233
234
235
236
237
238
239
240
5
Pad
Name
SEG[47]
SEG[48]
SEG[49]
SEG[50]
SEG[51]
SEG[52]
SEG[53]
SEG[54]
SEG[55]
SEG[56]
SEG[57]
SEG[58]
SEG[59]
SEG[60]
SEG[61]
SEG[62]
SEG[63]
SEG[64]
SEG[65]
SEG[66]
SEG[67]
SEG[68]
SEG[69]
SEG[70]
SEG[71]
SEG[72]
SEG[73]
SEG[74]
SEG[75]
SEG[76]
SEG[77]
SEG[78]
SEG[79]
SEG[80]
SEG[81]
SEG[82]
SEG[83]
SEG[84]
SEG[85]
SEG[86]
X
Y
-975.3
-945.3
-915.3
-885.3
-855.3
-825.3
-795.3
-765.3
-735.3
-705.3
-675.3
-645.3
-615.3
-585.3
-555.3
-525.3
-495.3
-465.3
-435.3
-405.3
-375.3
-345.3
-315.3
-285.3
-255.3
-225.3
-195.3
-165.3
-135.3
-105.3
-75.3
-45.3
-15.3
14.7
44.7
74.7
104.7
134.7
164.7
194.7
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
Rev1.4-13 Sep 2010
RW1092
Dot Matrix Type LCD Controller
PAD Coordinate(1/97 Duty, SHL=0,3-3)
Pad No.
241
242
243
244
245
246
247
248
249
250
251
252
253
254
255
256
257
258
259
260
261
262
263
264
265
266
267
268
269
270
271
272
273
274
275
276
277
278
279
280
Pad Name
SEG[87]
SEG[88]
SEG[89]
SEG[90]
SEG[91]
SEG[92]
SEG[93]
SEG[94]
SEG[95]
SEG[96]
SEG[97]
SEG[98]
SEG[99]
SEG[100]
SEG[101]
SEG[102]
SEG[103]
SEG[104]
SEG[105]
SEG[106]
SEG[107]
SEG[108]
SEG[109]
SEG[110]
SEG[111]
SEG[112]
SEG[113]
SEG[114]
SEG[115]
SEG[116]
SEG[117]
SEG[118]
SEG[119]
SEG[120]
SEG[121]
SEG[122]
SEG[123]
SEG[124]
SEG[125]
SEG[126]
X
224.7
254.7
284.7
314.7
344.7
374.7
404.7
434.7
464.7
494.7
524.7
554.7
584.7
614.7
644.7
674.7
704.7
734.7
764.7
794.7
824.7
854.7
884.7
914.7
944.7
974.7
1004.7
1034.7
1064.7
1094.7
1124.7
1154.7
1184.7
1214.7
1244.7
1274.7
1304.7
1334.7
1364.7
1394.7
Y
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
Pad No.
281
282
283
284
285
286
287
288
289
290
291
292
293
294
295
296
297
298
299
300
301
302
303
304
305
306
307
308
309
310
311
312
313
314
315
316
317
318
319
320
Pad Name
SEG[127]
SEG[128]
SEG[129]
SEG[130]
SEG[131]
SEG[132]
SEG[133]
SEG[134]
SEG[135]
SEG[136]
SEG[137]
SEG[138]
SEG[139]
SEG[140]
SEG[141]
SEG[142]
SEG[143]
SEG[144]
SEG[145]
SEG[146]
SEG[147]
SEG[148]
SEG[149]
SEG[150]
SEG[151]
SEG[152]
SEG[153]
SEG[154]
SEG[155]
SEG[156]
SEG[157]
SEG[158]
SEG[159]
COM[48]
COM[49]
COM[50]
COM[51]
COM[52]
COM[53]
COM[54]
X
1424.7
1454.7
1484.7
1514.7
1544.7
1574.7
1604.7
1634.7
1664.7
1694.7
1724.7
1754.7
1784.7
1814.7
1844.7
1874.7
1904.7
1934.7
1964.7
1994.7
2024.7
2054.7
2084.7
2114.7
2144.7
2174.7
2204.7
2234.7
2264.7
2294.7
2324.7
2354.7
2384.7
2414.7
2444.7
2474.7
2504.7
2534.7
2564.7
2594.7
6
Y
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
Pad No.
321
322
323
324
325
326
327
328
329
330
331
332
333
334
335
336
337
338
339
340
341
342
343
344
345
346
347
348
349
350
351
352
353
Pad Name
COM[55]
COM[56]
COM[57]
COM[58]
COM[59]
COM[60]
COM[61]
COM[62]
COM[63]
COM[64]
COM[65]
COM[66]
COM[67]
COM[68]
COM[69]
COM[70]
COM[71]
COM[72]
COM[73]
COM[74]
COM[75]
COM[76]
COM[77]
COM[78]
COM[79]
COM[80]
COM[81]
COM[82]
COM[83]
COM[84]
COM[85]
COM[86]
COM[87]
X
2624.7
2654.7
2684.7
2714.7
2744.7
2774.7
2804.7
2834.7
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
Y
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-448.5
-411.1
-373.7
-336.3
-298.9
-261.5
-224.1
-186.7
-149.3
-111.9
-74.5
-37.1
0.3
37.7
75.1
112.5
149.9
187.3
224.7
262.1
299.5
336.9
374.3
411.7
449.1
Rev1.4-13 Sep 2010
RW1092
Dot Matrix Type LCD Controller
PAD Coordinate(1/97 Duty, SHL=1,3-1)
Pad No. Pad Name
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
32
33
34
35
36
37
38
39
40
COM[7]
COM[6]
COM[5]
COM[4]
COM[3]
COM[2]
COM[1]
COM[0]
COMS1
STACOM
VSS
CS1B
CS2
VDD
RSTP
A0
VSS
RW(XWR)
E(XRD)
VDD
D0
D1
D2
D3
D4
D5
D6
D7
VDD
VDD
VDD
VDD
VDD2
VDD2
VDD2
VDD2
VSS
VSS
VSS
VSS
X
Y
Pad No.
2843.23
2805.83
2768.43
2731.03
2693.63
2656.23
2618.83
2581.43
2544.03
2424.72
2370.61
2318.55
2268.55
2214.47
2162.38
2112.38
2058.3
2006.21
1956.21
1902.13
1850.04
1800.04
1750.04
1700.04
1650.04
1600.04
1550.04
1500.04
1450.04
1400.04
1350.04
1300.04
1250.04
1200.04
1150.04
1100.04
1050.04
1000.04
950.04
900.04
445
445
445
445
445
445
445
445
445
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
41
42
43
44
45
46
47
48
49
50
51
52
53
54
55
56
57
58
59
60
61
62
63
64
65
66
67
68
69
70
71
72
73
74
75
76
77
78
79
80
Pad
Name
VOUT
VOUT
VOUT
VOUT
CAP5P
CAP5P
CAP1N
CAP1N
CAP3P
CAP3P
CAP1N
CAP1N
CAP1P
CAP1P
CAP2P
CAP2P
CAP2N
CAP2N
CAP4P
CAP4P
CAP2N
CAP2N
CAP6P
CAP6P
VSS
VRS
VDD
V4
V4
V3
V3
V2
V2
V1
V1
V0
V0
VRAB
VDD
T[8]
X
Y
843.94
793.94
743.94
693.94
637.84
587.84
537.84
487.84
437.84
387.84
337.84
287.84
237.84
187.84
137.84
87.84
37.84
-12.16
-62.16
-112.16
-162.16
-212.16
-262.16
-312.16
-371.7
-424.72
-477.72
-535.04
-585.04
-635.04
-685.04
-735.04
-785.04
-835.04
-885.04
-935.04
-985.04
-1035.04
-1097.58
-1147.58
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
7
Pad No. Pad Name
81
82
83
84
85
86
87
88
89
90
91
92
93
94
95
96
97
98
99
100
101
102
103
104
105
106
107
108
109
110
111
112
113
114
115
116
117
118
119
120
T[7]
T[6]
T[5]
T[4]
T[3]
T[2]
T[1]
T[0]
VDD
CLS
VSS
C86
VDD
PSB
VSS
IRS
VDD
SEL1
VSS
SEL2
VDD
SEL3
VSS
V0
COM[48]
COM[49]
COM[50]
COM[51]
COM[52]
COM[53]
COM[54]
COM[55]
COM[56]
COM[57]
COM[58]
COM[59]
COM[60]
COM[61]
COM[62]
COM[63]
X
Y
-1197.58
-1247.58
-1297.58
-1347.58
-1397.58
-1447.58
-1497.58
-1547.58
-1599.67
-1653.75
-1705.84
-1759.92
-1812.01
-1866.09
-1918.18
-1972.26
-2024.35
-2078.43
-2130.52
-2184.6
-2236.69
-2290.77
-2340.77
-2396.87
-2544.03
-2581.43
-2618.83
-2656.23
-2693.63
-2731.03
-2768.43
-2805.83
-2843.23
-3055
-3055
-3055
-3055
-3055
-3055
-3055
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
445
445
445
445
445
445
445
445
445
449.1
411.7
374.3
336.9
299.5
262.1
224.7
Rev1.4-13 Sep 2010
RW1092
Dot Matrix Type LCD Controller
PAD Coordinate(1/97 Duty, SHL=1,3-2)
Pad No. Pad Name
121
122
123
124
125
126
127
128
129
130
131
132
133
134
135
136
137
138
139
140
141
142
143
144
145
146
147
148
149
150
151
152
153
154
155
156
157
158
159
160
COM[64]
COM[65]
COM[66]
COM[67]
COM[68]
COM[69]
COM[70]
COM[71]
COM[72]
COM[73]
COM[74]
COM[75]
COM[76]
COM[77]
COM[78]
COM[79]
COM[80]
COM[81]
COM[82]
COM[83]
COM[84]
COM[85]
COM[86]
COM[87]
COM[88]
COM[89]
COM[90]
COM[91]
COM[92]
COM[93]
COM[94]
COM[95]
COMS2
SEG[0]
SEG[1]
SEG[2]
SEG[3]
SEG[4]
SEG[5]
SEG[6]
X
Y
Pad No.
-3055
-3055
-3055
-3055
-3055
-3055
-3055
-3055
-3055
-3055
-3055
-3055
-3055
-3055
-3055
-3055
-3055
-3055
-2835.3
-2805.3
-2775.3
-2745.3
-2715.3
-2685.3
-2655.3
-2625.3
-2595.3
-2565.3
-2535.3
-2505.3
-2475.3
-2445.3
-2415.3
-2385.3
-2355.3
-2325.3
-2295.3
-2265.3
-2235.3
-2205.3
187.3
149.9
112.5
75.1
37.7
0.3
-37.1
-74.5
-111.9
-149.3
-186.7
-224.1
-261.5
-298.9
-336.3
-373.7
-411.1
-448.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
161
162
163
164
165
166
167
168
169
170
171
172
173
174
175
176
177
178
179
180
181
182
183
184
185
186
187
188
189
190
191
192
193
194
195
196
197
198
199
200
Pad
Name
SEG[7]
SEG[8]
SEG[9]
SEG[10]
SEG[11]
SEG[12]
SEG[13]
SEG[14]
SEG[15]
SEG[16]
SEG[17]
SEG[18]
SEG[19]
SEG[20]
SEG[21]
SEG[22]
SEG[23]
SEG[24]
SEG[25]
SEG[26]
SEG[27]
SEG[28]
SEG[29]
SEG[30]
SEG[31]
SEG[32]
SEG[33]
SEG[34]
SEG[35]
SEG[36]
SEG[37]
SEG[38]
SEG[39]
SEG[40]
SEG[41]
SEG[42]
SEG[43]
SEG[44]
SEG[45]
SEG[46]
X
Y
Pad No.
-2175.3
-2145.3
-2115.3
-2085.3
-2055.3
-2025.3
-1995.3
-1965.3
-1935.3
-1905.3
-1875.3
-1845.3
-1815.3
-1785.3
-1755.3
-1725.3
-1695.3
-1665.3
-1635.3
-1605.3
-1575.3
-1545.3
-1515.3
-1485.3
-1455.3
-1425.3
-1395.3
-1365.3
-1335.3
-1305.3
-1275.3
-1245.3
-1215.3
-1185.3
-1155.3
-1125.3
-1095.3
-1065.3
-1035.3
-1005.3
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
201
202
203
204
205
206
207
208
209
210
211
212
213
214
215
216
217
218
219
220
221
222
223
224
225
226
227
228
229
230
231
232
233
234
235
236
237
238
239
240
8
Pad
Name
SEG[47]
SEG[48]
SEG[49]
SEG[50]
SEG[51]
SEG[52]
SEG[53]
SEG[54]
SEG[55]
SEG[56]
SEG[57]
SEG[58]
SEG[59]
SEG[60]
SEG[61]
SEG[62]
SEG[63]
SEG[64]
SEG[65]
SEG[66]
SEG[67]
SEG[68]
SEG[69]
SEG[70]
SEG[71]
SEG[72]
SEG[73]
SEG[74]
SEG[75]
SEG[76]
SEG[77]
SEG[78]
SEG[79]
SEG[80]
SEG[81]
SEG[82]
SEG[83]
SEG[84]
SEG[85]
SEG[86]
X
Y
-975.3
-945.3
-915.3
-885.3
-855.3
-825.3
-795.3
-765.3
-735.3
-705.3
-675.3
-645.3
-615.3
-585.3
-555.3
-525.3
-495.3
-465.3
-435.3
-405.3
-375.3
-345.3
-315.3
-285.3
-255.3
-225.3
-195.3
-165.3
-135.3
-105.3
-75.3
-45.3
-15.3
14.7
44.7
74.7
104.7
134.7
164.7
194.7
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
Rev1.4-13 Sep 2010
RW1092
Dot Matrix Type LCD Controller
PAD Coordinate(1/97 Duty, SHL=1,3-3)
Pad No. Pad Name
241
242
243
244
245
246
247
248
249
250
251
252
253
254
255
256
257
258
259
260
261
262
263
264
265
266
267
268
269
270
271
272
273
274
275
276
277
278
279
280
SEG[87]
SEG[88]
SEG[89]
SEG[90]
SEG[91]
SEG[92]
SEG[93]
SEG[94]
SEG[95]
SEG[96]
SEG[97]
SEG[98]
SEG[99]
SEG[100]
SEG[101]
SEG[102]
SEG[103]
SEG[104]
SEG[105]
SEG[106]
SEG[107]
SEG[108]
SEG[109]
SEG[110]
SEG[111]
SEG[112]
SEG[113]
SEG[114]
SEG[115]
SEG[116]
SEG[117]
SEG[118]
SEG[119]
SEG[120]
SEG[121]
SEG[122]
SEG[123]
SEG[124]
SEG[125]
SEG[126]
X
Y
224.7
254.7
284.7
314.7
344.7
374.7
404.7
434.7
464.7
494.7
524.7
554.7
584.7
614.7
644.7
674.7
704.7
734.7
764.7
794.7
824.7
854.7
884.7
914.7
944.7
974.7
1004.7
1034.7
1064.7
1094.7
1124.7
1154.7
1184.7
1214.7
1244.7
1274.7
1304.7
1334.7
1364.7
1394.7
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
Pad No. Pad Name
281
282
283
284
285
286
287
288
289
290
291
292
293
294
295
296
297
298
299
300
301
302
303
304
305
306
307
308
309
310
311
312
313
314
315
316
317
318
319
320
SEG[127]
SEG[128]
SEG[129]
SEG[130]
SEG[131]
SEG[132]
SEG[133]
SEG[134]
SEG[135]
SEG[136]
SEG[137]
SEG[138]
SEG[139]
SEG[140]
SEG[141]
SEG[142]
SEG[143]
SEG[144]
SEG[145]
SEG[146]
SEG[147]
SEG[148]
SEG[149]
SEG[150]
SEG[151]
SEG[152]
SEG[153]
SEG[154]
SEG[155]
SEG[156]
SEG[157]
SEG[158]
SEG[159]
COM[47]
COM[46]
COM[45]
COM[44]
COM[43]
COM[42]
COM[41]
9
X
Y
Pad No.
1424.7
1454.7
1484.7
1514.7
1544.7
1574.7
1604.7
1634.7
1664.7
1694.7
1724.7
1754.7
1784.7
1814.7
1844.7
1874.7
1904.7
1934.7
1964.7
1994.7
2024.7
2054.7
2084.7
2114.7
2144.7
2174.7
2204.7
2234.7
2264.7
2294.7
2324.7
2354.7
2384.7
2414.7
2444.7
2474.7
2504.7
2534.7
2564.7
2594.7
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
321
322
323
324
325
326
327
328
329
330
331
332
333
334
335
336
337
338
339
340
341
342
343
344
345
346
347
348
349
350
351
352
353
Pad
Name
COM[40]
COM[39]
COM[38]
COM[37]
COM[36]
COM[35]
COM[34]
COM[33]
COM[32]
COM[31]
COM[30]
COM[29]
COM[28]
COM[27]
COM[26]
COM[25]
COM[24]
COM[23]
COM[22]
COM[21]
COM[20]
COM[19]
COM[18]
COM[17]
COM[16]
COM[15]
COM[14]
COM[13]
COM[12]
COM[11]
COM[10]
COM[9]
COM[8]
X
Y
2624.7
2654.7
2684.7
2714.7
2744.7
2774.7
2804.7
2834.7
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-448.5
-411.1
-373.7
-336.3
-298.9
-261.5
-224.1
-186.7
-149.3
-111.9
-74.5
-37.1
0.3
37.7
75.1
112.5
149.9
187.3
224.7
262.1
299.5
336.9
374.3
411.7
449.1
Rev1.4-13 Sep 2010
RW1092
Dot Matrix Type LCD Controller
PAD Coordinate(1/65 Duty, SHL=0, 3-1)
Pad No. Pad Name
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
32
33
34
35
36
37
38
39
40
COM[56]
COM[57]
COM[58]
COM[59]
COM[60]
COM[61]
COM[62]
COM[63]
COMS1
STACOM
VSS
CS1B
CS2
VDD
RSTP
A0
VSS
X
2843.23
2805.83
2768.43
2731.03
2693.63
2656.23
2618.83
2581.43
2544.03
2424.72
2370.61
2318.55
2268.55
2214.47
2162.38
2112.38
2058.3
RW(XWR) 2006.21
E(XRD) 1956.21
VDD
1902.13
D0
1850.04
D1
1800.04
D2
1750.04
D3
1700.04
D4
1650.04
D5
1600.04
D6
1550.04
D7
1500.04
VDD
1450.04
VDD
1400.04
VDD
1350.04
VDD
1300.04
VDD2 1250.04
VDD2 1200.04
VDD2 1150.04
VDD2 1100.04
VSS
1050.04
VSS
1000.04
VSS
950.04
VSS
900.04
Y
Pad No.
445
445
445
445
445
445
445
445
445
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
41
42
43
44
45
46
47
48
49
50
51
52
53
54
55
56
57
58
59
60
61
62
63
64
65
66
67
68
69
70
71
72
73
74
75
76
77
78
79
80
Pad
Name
VOUT
VOUT
VOUT
VOUT
CAP5P
CAP5P
CAP1N
CAP1N
CAP3P
CAP3P
CAP1N
CAP1N
CAP1P
CAP1P
CAP2P
CAP2P
CAP2N
CAP2N
CAP4P
CAP4P
CAP2N
CAP2N
CAP6P
CAP6P
VSS
VRS
VDD
V4
V4
V3
V3
V2
V2
V1
V1
V0
V0
VRAB
VDD
T[8]
X
Y
843.94
793.94
743.94
693.94
637.84
587.84
537.84
487.84
437.84
387.84
337.84
287.84
237.84
187.84
137.84
87.84
37.84
-12.16
-62.16
-112.16
-162.16
-212.16
-262.16
-312.16
-371.7
-424.72
-477.72
-535.04
-585.04
-635.04
-685.04
-735.04
-785.04
-835.04
-885.04
-935.04
-985.04
-1035.04
-1097.58
-1147.58
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
10
Pad No. Pad Name
81
82
83
84
85
86
87
88
89
90
91
92
93
94
95
96
97
98
99
100
101
102
103
104
105
106
107
108
109
110
111
112
113
114
115
116
117
118
119
120
T[7]
T[6]
T[5]
T[4]
T[3]
T[2]
T[1]
T[0]
VDD
CLS
VSS
C86
VDD
PSB
VSS
IRS
VDD
SEL1
VSS
SEL2
VDD
SEL3
VSS
V0
COM[31]
COM[30]
COM[29]
COM[28]
COM[27]
COM[26]
COM[25]
COM[24]
COM[23]
COM[22]
COM[21]
COM[20]
COM[19]
COM[18]
COM[17]
COM[16]
X
Y
-1197.58
-1247.58
-1297.58
-1347.58
-1397.58
-1447.58
-1497.58
-1547.58
-1599.67
-1653.75
-1705.84
-1759.92
-1812.01
-1866.09
-1918.18
-1972.26
-2024.35
-2078.43
-2130.52
-2184.6
-2236.69
-2290.77
-2340.77
-2396.87
-2544.03
-2581.43
-2618.83
-2656.23
-2693.63
-2731.03
-2768.43
-2805.83
-2843.23
-3055
-3055
-3055
-3055
-3055
-3055
-3055
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
445
445
445
445
445
445
445
445
445
449.1
411.7
374.3
336.9
299.5
262.1
224.7
Rev1.4-13 Sep 2010
RW1092
Dot Matrix Type LCD Controller
PAD Coordinate(1/65 Duty, SHL=0, 3-2)
Pad No. Pad Name
121
122
123
124
125
126
127
128
129
130
131
132
133
134
135
136
137
138
139
140
141
142
143
144
145
146
147
148
149
150
151
152
153
154
155
156
157
158
159
160
COM[15]
COM[14]
COM[13]
COM[12]
COM[11]
COM[10]
COM[9]
COM[8]
COM[7]
COM[6]
COM[5]
COM[4]
COM[3]
COM[2]
COM[1]
COM[0]
COMS2
SEG[0]
SEG[1]
SEG[2]
SEG[3]
SEG[4]
SEG[5]
SEG[6]
SEG[7]
SEG[8]
SEG[9]
SEG[10]
SEG[11]
SEG[12]
SEG[13]
SEG[14]
SEG[15]
SEG[16]
SEG[17]
SEG[18]
SEG[19]
SEG[20]
SEG[21]
SEG[22]
X
Y
Pad No.
-3055
-3055
-3055
-3055
-3055
-3055
-3055
-3055
-3055
-3055
-3055
-3055
-3055
-3055
-3055
-3055
-3055
-3055
-2835.3
-2805.3
-2775.3
-2745.3
-2715.3
-2685.3
-2655.3
-2625.3
-2595.3
-2565.3
-2535.3
-2505.3
-2475.3
-2445.3
-2415.3
-2385.3
-2355.3
-2325.3
-2295.3
-2265.3
-2235.3
-2205.3
187.3
149.9
112.5
75.1
37.7
0.3
-37.1
-74.5
-111.9
-149.3
-186.7
-224.1
-261.5
-298.9
-336.3
-373.7
-411.1
-448.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
161
162
163
164
165
166
167
168
169
170
171
172
173
174
175
176
177
178
179
180
181
182
183
184
185
186
187
188
189
190
191
192
193
194
195
196
197
198
199
200
Pad
Name
SEG[23]
SEG[24]
SEG[25]
SEG[26]
SEG[27]
SEG[28]
SEG[29]
SEG[30]
SEG[31]
SEG[32]
SEG[33]
SEG[34]
SEG[35]
SEG[36]
SEG[37]
SEG[38]
SEG[39]
SEG[40]
SEG[41]
SEG[42]
SEG[43]
SEG[44]
SEG[45]
SEG[46]
SEG[47]
SEG[48]
SEG[49]
SEG[50]
SEG[51]
SEG[52]
SEG[53]
SEG[54]
SEG[55]
SEG[56]
SEG[57]
SEG[58]
SEG[59]
SEG[60]
SEG[61]
SEG[62]
X
Y
-2175.3
-2145.3
-2115.3
-2085.3
-2055.3
-2025.3
-1995.3
-1965.3
-1935.3
-1905.3
-1875.3
-1845.3
-1815.3
-1785.3
-1755.3
-1725.3
-1695.3
-1665.3
-1635.3
-1605.3
-1575.3
-1545.3
-1515.3
-1485.3
-1455.3
-1425.3
-1395.3
-1365.3
-1335.3
-1305.3
-1275.3
-1245.3
-1215.3
-1185.3
-1155.3
-1125.3
-1095.3
-1065.3
-1035.3
-1005.3
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
11
Pad No. Pad Name
201
202
203
204
205
206
207
208
209
210
211
212
213
214
215
216
217
218
219
220
221
222
223
224
225
226
227
228
229
230
231
232
233
234
235
236
237
238
239
240
SEG[63]
SEG[64]
SEG[65]
SEG[66]
SEG[67]
SEG[68]
SEG[69]
SEG[70]
SEG[71]
SEG[72]
SEG[73]
SEG[74]
SEG[75]
SEG[76]
SEG[77]
SEG[78]
SEG[79]
SEG[80]
SEG[81]
SEG[82]
SEG[83]
SEG[84]
SEG[85]
SEG[86]
SEG[87]
SEG[88]
SEG[89]
SEG[90]
SEG[91]
SEG[92]
SEG[93]
SEG[94]
SEG[95]
SEG[96]
SEG[97]
SEG[98]
SEG[99]
SEG[100]
SEG[101]
SEG[102]
X
Y
-975.3
-945.3
-915.3
-885.3
-855.3
-825.3
-795.3
-765.3
-735.3
-705.3
-675.3
-645.3
-615.3
-585.3
-555.3
-525.3
-495.3
-465.3
-435.3
-405.3
-375.3
-345.3
-315.3
-285.3
-255.3
-225.3
-195.3
-165.3
-135.3
-105.3
-75.3
-45.3
-15.3
14.7
44.7
74.7
104.7
134.7
164.7
194.7
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
Rev1.4-13 Sep 2010
RW1092
Dot Matrix Type LCD Controller
PAD Coordinate(1/65 Duty, SHL=0, 3-3)
Pad No. Pad Name
241
242
243
244
245
246
247
248
249
250
251
252
253
254
255
256
257
258
259
260
261
262
263
264
265
266
267
268
269
270
271
272
273
274
275
276
277
278
279
280
SEG[103]
SEG[104]
SEG[105]
SEG[106]
SEG[107]
SEG[108]
SEG[109]
SEG[110]
SEG[111]
SEG[112]
SEG[113]
SEG[114]
SEG[115]
SEG[116]
SEG[117]
SEG[118]
SEG[119]
SEG[120]
SEG[121]
SEG[122]
SEG[123]
SEG[124]
SEG[125]
SEG[126]
SEG[127]
SEG[128]
SEG[129]
SEG[130]
SEG[131]
SEG[132]
SEG[133]
SEG[134]
SEG[135]
SEG[136]
SEG[137]
SEG[138]
SEG[139]
SEG[140]
SEG[141]
SEG[142]
X
Y
224.7
254.7
284.7
314.7
344.7
374.7
404.7
434.7
464.7
494.7
524.7
554.7
584.7
614.7
644.7
674.7
704.7
734.7
764.7
794.7
824.7
854.7
884.7
914.7
944.7
974.7
1004.7
1034.7
1064.7
1094.7
1124.7
1154.7
1184.7
1214.7
1244.7
1274.7
1304.7
1334.7
1364.7
1394.7
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
Pad No. Pad Name
281
282
283
284
285
286
287
288
289
290
291
292
293
294
295
296
297
298
299
300
301
302
303
304
305
306
307
308
309
310
311
312
313
314
315
316
317
318
319
320
SEG[143]
SEG[144]
SEG[145]
SEG[146]
SEG[147]
SEG[148]
SEG[149]
SEG[150]
SEG[151]
SEG[152]
SEG[153]
SEG[154]
SEG[155]
SEG[156]
SEG[157]
SEG[158]
SEG[159]
SEG[160]
SEG[161]
SEG[162]
SEG[163]
SEG[164]
SEG[165]
SEG[166]
SEG[167]
SEG[168]
SEG[169]
SEG[170]
SEG[171]
SEG[172]
SEG[173]
SEG[174]
SEG[175]
SEG[176]
SEG[177]
SEG[178]
SEG[179]
SEG[180]
SEG[181]
SEG[182]
12
X
Y
Pad No.
1424.7
1454.7
1484.7
1514.7
1544.7
1574.7
1604.7
1634.7
1664.7
1694.7
1724.7
1754.7
1784.7
1814.7
1844.7
1874.7
1904.7
1934.7
1964.7
1994.7
2024.7
2054.7
2084.7
2114.7
2144.7
2174.7
2204.7
2234.7
2264.7
2294.7
2324.7
2354.7
2384.7
2414.7
2444.7
2474.7
2504.7
2534.7
2564.7
2594.7
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
321
322
323
324
325
326
327
328
329
330
331
332
333
334
335
336
337
338
339
340
341
342
343
344
345
346
347
348
349
350
351
352
353
Pad
Name
SEG[183]
SEG[184]
SEG[185]
SEG[186]
SEG[187]
SEG[188]
SEG[189]
SEG[190]
SEG[191]
COM[32]
COM[33]
COM[34]
COM[35]
COM[36]
COM[37]
COM[38]
COM[39]
COM[40]
COM[41]
COM[42]
COM[43]
COM[44]
COM[45]
COM[46]
COM[47]
COM[48]
COM[49]
COM[50]
COM[51]
COM[52]
COM[53]
COM[54]
COM[55]
X
Y
2624.7
2654.7
2684.7
2714.7
2744.7
2774.7
2804.7
2834.7
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-448.5
-411.1
-373.7
-336.3
-298.9
-261.5
-224.1
-186.7
-149.3
-111.9
-74.5
-37.1
0.3
37.7
75.1
112.5
149.9
187.3
224.7
262.1
299.5
336.9
374.3
411.7
449.1
Rev1.4-13 Sep 2010
RW1092
Dot Matrix Type LCD Controller
PAD Coordinate(1/65 Duty, SHL=1, 3-1)
Pad No. Pad Name
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
32
33
34
35
36
37
38
39
40
COM[7]
COM[6]
COM[5]
COM[4]
COM[3]
COM[2]
COM[1]
COM[0]
COMS1
STACOM
VSS
CS1B
CS2
VDD
RST
A0
VSS
X
2843.23
2805.83
2768.43
2731.03
2693.63
2656.23
2618.83
2581.43
2544.03
2424.72
2370.61
2318.55
2268.55
2214.47
2162.38
2112.38
2058.3
RW(XWR) 2006.21
E(XRD) 1956.21
VDD 1902.13
D0
1850.04
D1
1800.04
D2
1750.04
D3
1700.04
D4
1650.04
D5
1600.04
D6
1550.04
D7
1500.04
VDD 1450.04
VDD 1400.04
VDD 1350.04
VDD 1300.04
VDD2 1250.04
VDD2 1200.04
VDD2 1150.04
VDD2 1100.04
VSS
1050.04
VSS
1000.04
VSS
950.04
VSS
900.04
Y
Pad No.
445
445
445
445
445
445
445
445
445
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
41
42
43
44
45
46
47
48
49
50
51
52
53
54
55
56
57
58
59
60
61
62
63
64
65
66
67
68
69
70
71
72
73
74
75
76
77
78
79
80
Pad
Name
VOUT
VOUT
VOUT
VOUT
CAP5P
CAP5P
CAP1N
CAP1N
CAP3P
CAP3P
CAP1N
CAP1N
CAP1P
CAP1P
CAP2P
CAP2P
CAP2N
CAP2N
CAP4P
CAP4P
CAP2N
CAP2N
CAP6P
CAP6P
VSS
VRS
VDD
V4
V4
V3
V3
V2
V2
V1
V1
V0
V0
VRAB
VDD
T[8]
X
Y
843.94
793.94
743.94
693.94
637.84
587.84
537.84
487.84
437.84
387.84
337.84
287.84
237.84
187.84
137.84
87.84
37.84
-12.16
-62.16
-112.16
-162.16
-212.16
-262.16
-312.16
-371.7
-424.72
-477.72
-535.04
-585.04
-635.04
-685.04
-735.04
-785.04
-835.04
-885.04
-935.04
-985.04
-1035.04
-1097.58
-1147.58
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
13
Pad No. Pad Name
81
82
83
84
85
86
87
88
89
90
91
92
93
94
95
96
97
98
99
100
101
102
103
104
105
106
107
108
109
110
111
112
113
114
115
116
117
118
119
120
T[7]
T[6]
T[5]
T[4]
T[3]
T[2]
T[1]
T[0]
VDD
CLS
VSS
C86
VDD
PSB
VSS
IRS
VDD
SEL1
VSS
SEL2
VDD
SEL3
VSS
V0
COM[32]
COM[33]
COM[34]
COM[35]
COM[36]
COM[37]
COM[38]
COM[39]
COM[40]
COM[41]
COM[42]
COM[43]
COM[44]
COM[45]
COM[46]
COM[47]
X
Y
-1197.58
-1247.58
-1297.58
-1347.58
-1397.58
-1447.58
-1497.58
-1547.58
-1599.67
-1653.75
-1705.84
-1759.92
-1812.01
-1866.09
-1918.18
-1972.26
-2024.35
-2078.43
-2130.52
-2184.6
-2236.69
-2290.77
-2340.77
-2396.87
-2544.03
-2581.43
-2618.83
-2656.23
-2693.63
-2731.03
-2768.43
-2805.83
-2843.23
-3055
-3055
-3055
-3055
-3055
-3055
-3055
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
445
445
445
445
445
445
445
445
445
449.1
411.7
374.3
336.9
299.5
262.1
224.7
Rev1.4-13 Sep 2010
RW1092
Dot Matrix Type LCD Controller
PAD Coordinate(1/65 Duty, SHL=1, 3-2)
Pad No. Pad Name
121
122
123
124
125
126
127
128
129
130
131
132
133
134
135
136
137
138
139
140
141
142
143
144
145
146
147
148
149
150
151
152
153
154
155
156
157
158
159
160
COM[48]
COM[49]
COM[50]
COM[51]
COM[52]
COM[53]
COM[54]
COM[55]
COM[56]
COM[57]
COM[58]
COM[59]
COM[60]
COM[61]
COM[62]
COM[63]
COMS2
SEG[0]
SEG[1]
SEG[2]
SEG[3]
SEG[4]
SEG[5]
SEG[6]
SEG[7]
SEG[8]
SEG[9]
SEG[10]
SEG[11]
SEG[12]
SEG[13]
SEG[14]
SEG[15]
SEG[16]
SEG[17]
SEG[18]
SEG[19]
SEG[20]
SEG[21]
SEG[22]
X
Y
Pad No.
-3055
-3055
-3055
-3055
-3055
-3055
-3055
-3055
-3055
-3055
-3055
-3055
-3055
-3055
-3055
-3055
-3055
-3055
-2835.3
-2805.3
-2775.3
-2745.3
-2715.3
-2685.3
-2655.3
-2625.3
-2595.3
-2565.3
-2535.3
-2505.3
-2475.3
-2445.3
-2415.3
-2385.3
-2355.3
-2325.3
-2295.3
-2265.3
-2235.3
-2205.3
187.3
149.9
112.5
75.1
37.7
0.3
-37.1
-74.5
-111.9
-149.3
-186.7
-224.1
-261.5
-298.9
-336.3
-373.7
-411.1
-448.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
161
162
163
164
165
166
167
168
169
170
171
172
173
174
175
176
177
178
179
180
181
182
183
184
185
186
187
188
189
190
191
192
193
194
195
196
197
198
199
200
Pad
Name
SEG[23]
SEG[24]
SEG[25]
SEG[26]
SEG[27]
SEG[28]
SEG[29]
SEG[30]
SEG[31]
SEG[32]
SEG[33]
SEG[34]
SEG[35]
SEG[36]
SEG[37]
SEG[38]
SEG[39]
SEG[40]
SEG[41]
SEG[42]
SEG[43]
SEG[44]
SEG[45]
SEG[46]
SEG[47]
SEG[48]
SEG[49]
SEG[50]
SEG[51]
SEG[52]
SEG[53]
SEG[54]
SEG[55]
SEG[56]
SEG[57]
SEG[58]
SEG[59]
SEG[60]
SEG[61]
SEG[62]
X
Y
-2175.3
-2145.3
-2115.3
-2085.3
-2055.3
-2025.3
-1995.3
-1965.3
-1935.3
-1905.3
-1875.3
-1845.3
-1815.3
-1785.3
-1755.3
-1725.3
-1695.3
-1665.3
-1635.3
-1605.3
-1575.3
-1545.3
-1515.3
-1485.3
-1455.3
-1425.3
-1395.3
-1365.3
-1335.3
-1305.3
-1275.3
-1245.3
-1215.3
-1185.3
-1155.3
-1125.3
-1095.3
-1065.3
-1035.3
-1005.3
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
14
Pad No. Pad Name
201
202
203
204
205
206
207
208
209
210
211
212
213
214
215
216
217
218
219
220
221
222
223
224
225
226
227
228
229
230
231
232
233
234
235
236
237
238
239
240
SEG[63]
SEG[64]
SEG[65]
SEG[66]
SEG[67]
SEG[68]
SEG[69]
SEG[70]
SEG[71]
SEG[72]
SEG[73]
SEG[74]
SEG[75]
SEG[76]
SEG[77]
SEG[78]
SEG[79]
SEG[80]
SEG[81]
SEG[82]
SEG[83]
SEG[84]
SEG[85]
SEG[86]
SEG[87]
SEG[88]
SEG[89]
SEG[90]
SEG[91]
SEG[92]
SEG[93]
SEG[94]
SEG[95]
SEG[96]
SEG[97]
SEG[98]
SEG[99]
SEG[100]
SEG[101]
SEG[102]
X
Y
-975.3
-945.3
-915.3
-885.3
-855.3
-825.3
-795.3
-765.3
-735.3
-705.3
-675.3
-645.3
-615.3
-585.3
-555.3
-525.3
-495.3
-465.3
-435.3
-405.3
-375.3
-345.3
-315.3
-285.3
-255.3
-225.3
-195.3
-165.3
-135.3
-105.3
-75.3
-45.3
-15.3
14.7
44.7
74.7
104.7
134.7
164.7
194.7
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
Rev1.4-13 Sep 2010
RW1092
Dot Matrix Type LCD Controller
PAD Coordinate(1/65 Duty, SHL=1, 3-3)
Pad No. Pad Name
241
242
243
244
245
246
247
248
249
250
251
252
253
254
255
256
257
258
259
260
261
262
263
264
265
266
267
268
269
270
271
272
273
274
275
276
277
278
279
280
SEG[103]
SEG[104]
SEG[105]
SEG[106]
SEG[107]
SEG[108]
SEG[109]
SEG[110]
SEG[111]
SEG[112]
SEG[113]
SEG[114]
SEG[115]
SEG[116]
SEG[117]
SEG[118]
SEG[119]
SEG[120]
SEG[121]
SEG[122]
SEG[123]
SEG[124]
SEG[125]
SEG[126]
SEG[127]
SEG[128]
SEG[129]
SEG[130]
SEG[131]
SEG[132]
SEG[133]
SEG[134]
SEG[135]
SEG[136]
SEG[137]
SEG[138]
SEG[139]
SEG[140]
SEG[141]
SEG[142]
X
Y
224.7
254.7
284.7
314.7
344.7
374.7
404.7
434.7
464.7
494.7
524.7
554.7
584.7
614.7
644.7
674.7
704.7
734.7
764.7
794.7
824.7
854.7
884.7
914.7
944.7
974.7
1004.7
1034.7
1064.7
1094.7
1124.7
1154.7
1184.7
1214.7
1244.7
1274.7
1304.7
1334.7
1364.7
1394.7
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
Pad No. Pad Name
281
282
283
284
285
286
287
288
289
290
291
292
293
294
295
296
297
298
299
300
301
302
303
304
305
306
307
308
309
310
311
312
313
314
315
316
317
318
319
320
SEG[143]
SEG[144]
SEG[145]
SEG[146]
SEG[147]
SEG[148]
SEG[149]
SEG[150]
SEG[151]
SEG[152]
SEG[153]
SEG[154]
SEG[155]
SEG[156]
SEG[157]
SEG[158]
SEG[159]
SEG[160]
SEG[161]
SEG[162]
SEG[163]
SEG[164]
SEG[165]
SEG[166]
SEG[167]
SEG[168]
SEG[169]
SEG[170]
SEG[171]
SEG[172]
SEG[173]
SEG[174]
SEG[175]
SEG[176]
SEG[177]
SEG[178]
SEG[179]
SEG[180]
SEG[181]
SEG[182]
15
X
Y
Pad No.
1424.7
1454.7
1484.7
1514.7
1544.7
1574.7
1604.7
1634.7
1664.7
1694.7
1724.7
1754.7
1784.7
1814.7
1844.7
1874.7
1904.7
1934.7
1964.7
1994.7
2024.7
2054.7
2084.7
2114.7
2144.7
2174.7
2204.7
2234.7
2264.7
2294.7
2324.7
2354.7
2384.7
2414.7
2444.7
2474.7
2504.7
2534.7
2564.7
2594.7
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
321
322
323
324
325
326
327
328
329
330
331
332
333
334
335
336
337
338
339
340
341
342
343
344
345
346
347
348
349
350
351
352
353
Pad
Name
SEG[183]
SEG[184]
SEG[185]
SEG[186]
SEG[187]
SEG[188]
SEG[189]
SEG[190]
SEG[191]
COM[31]
COM[30]
COM[29]
COM[28]
COM[27]
COM[26]
COM[25]
COM[24]
COM[23]
COM[22]
COM[21]
COM[20]
COM[19]
COM[18]
COM[17]
COM[16]
COM[15]
COM[14]
COM[13]
COM[12]
COM[11]
COM[10]
COM[9]
COM[8]
X
Y
2624.7
2654.7
2684.7
2714.7
2744.7
2774.7
2804.7
2834.7
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-448.5
-411.1
-373.7
-336.3
-298.9
-261.5
-224.1
-186.7
-149.3
-111.9
-74.5
-37.1
0.3
37.7
75.1
112.5
149.9
187.3
224.7
262.1
299.5
336.9
374.3
411.7
449.1
Rev1.4-13 Sep 2010
RW1092
Dot Matrix Type LCD Controller
PAD Coordinate(1/33 Duty, SHL=0, 3-1)
Pad No. Pad Name
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
32
33
34
35
36
37
38
39
40
COM[24]
COM[25]
COM[26]
COM[27]
COM[28]
COM[29]
COM[30]
COM[31]
COMS1
STACOM
VSS
CS1B
CS2
VDD
RSTP
A0
VSS
X
2843.23
2805.83
2768.43
2731.03
2693.63
2656.23
2618.83
2581.43
2544.03
2424.72
2370.61
2318.55
2268.55
2214.47
2162.38
2112.38
2058.3
RW(XWR) 2006.21
E(XRD) 1956.21
VDD
1902.13
D0
1850.04
D1
1800.04
D2
1750.04
D3
1700.04
D4
1650.04
D5
1600.04
D6
1550.04
D7
1500.04
VDD
1450.04
VDD
1400.04
VDD
1350.04
VDD
1300.04
VDD2 1250.04
VDD2 1200.04
VDD2 1150.04
VDD2 1100.04
VSS
1050.04
VSS
1000.04
VSS
950.04
VSS
900.04
Y
Pad No.
445
445
445
445
445
445
445
445
445
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
41
42
43
44
45
46
47
48
49
50
51
52
53
54
55
56
57
58
59
60
61
62
63
64
65
66
67
68
69
70
71
72
73
74
75
76
77
78
79
80
Pad
Name
VOUT
VOUT
VOUT
VOUT
CAP5P
CAP5P
CAP1N
CAP1N
CAP3P
CAP3P
CAP1N
CAP1N
CAP1P
CAP1P
CAP2P
CAP2P
CAP2N
CAP2N
CAP4P
CAP4P
CAP2N
CAP2N
CAP6P
CAP6P
VSS
VRS
VDD
V4
V4
V3
V3
V2
V2
V1
V1
V0
V0
VRAB
VDD
T[8]
X
Y
843.94
793.94
743.94
693.94
637.84
587.84
537.84
487.84
437.84
387.84
337.84
287.84
237.84
187.84
137.84
87.84
37.84
-12.16
-62.16
-112.16
-162.16
-212.16
-262.16
-312.16
-371.7
-424.72
-477.72
-535.04
-585.04
-635.04
-685.04
-735.04
-785.04
-835.04
-885.04
-935.04
-985.04
-1035.04
-1097.58
-1147.58
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
16
Pad No. Pad Name
81
82
83
84
85
86
87
88
89
90
91
92
93
94
95
96
97
98
99
100
101
102
103
104
105
106
107
108
109
110
111
112
113
114
115
116
117
118
119
120
T[7]
T[6]
T[5]
T[4]
T[3]
T[2]
T[1]
T[0]
VDD
CLS
VSS
C86
VDD
PSB
VSS
IRS
VDD
SEL1
VSS
SEL2
VDD
SEL3
VSS
V0
COM[31]
COM[30]
COM[29]
COM[28]
COM[27]
COM[26]
COM[25]
COM[24]
COM[23]
COM[22]
COM[21]
COM[20]
COM[19]
COM[18]
COM[17]
COM[16]
X
Y
-1197.58
-1247.58
-1297.58
-1347.58
-1397.58
-1447.58
-1497.58
-1547.58
-1599.67
-1653.75
-1705.84
-1759.92
-1812.01
-1866.09
-1918.18
-1972.26
-2024.35
-2078.43
-2130.52
-2184.6
-2236.69
-2290.77
-2340.77
-2396.87
-2544.03
-2581.43
-2618.83
-2656.23
-2693.63
-2731.03
-2768.43
-2805.83
-2843.23
-3055
-3055
-3055
-3055
-3055
-3055
-3055
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
445
445
445
445
445
445
445
445
445
449.1
411.7
374.3
336.9
299.5
262.1
224.7
Rev1.4-13 Sep 2010
RW1092
Dot Matrix Type LCD Controller
PAD Coordinate(1/33 Duty, SHL=0, 3-2)
Pad No. Pad Name
121
122
123
124
125
126
127
128
129
130
131
132
133
134
135
136
137
138
139
140
141
142
143
144
145
146
147
148
149
150
151
152
153
154
155
156
157
158
159
160
COM[15]
COM[14]
COM[13]
COM[12]
COM[11]
COM[10]
COM[9]
COM[8]
COM[7]
COM[6]
COM[5]
COM[4]
COM[3]
COM[2]
COM[1]
COM[0]
COMS2
SEG[0]
SEG[1]
SEG[2]
SEG[3]
SEG[4]
SEG[5]
SEG[6]
SEG[7]
SEG[8]
SEG[9]
SEG[10]
SEG[11]
SEG[12]
SEG[13]
SEG[14]
SEG[15]
SEG[16]
SEG[17]
SEG[18]
SEG[19]
SEG[20]
SEG[21]
SEG[22]
X
Y
Pad No.
-3055
-3055
-3055
-3055
-3055
-3055
-3055
-3055
-3055
-3055
-3055
-3055
-3055
-3055
-3055
-3055
-3055
-3055
-2835.3
-2805.3
-2775.3
-2745.3
-2715.3
-2685.3
-2655.3
-2625.3
-2595.3
-2565.3
-2535.3
-2505.3
-2475.3
-2445.3
-2415.3
-2385.3
-2355.3
-2325.3
-2295.3
-2265.3
-2235.3
-2205.3
187.3
149.9
112.5
75.1
37.7
0.3
-37.1
-74.5
-111.9
-149.3
-186.7
-224.1
-261.5
-298.9
-336.3
-373.7
-411.1
-448.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
161
162
163
164
165
166
167
168
169
170
171
172
173
174
175
176
177
178
179
180
181
182
183
184
185
186
187
188
189
190
191
192
193
194
195
196
197
198
199
200
Pad
Name
SEG[23]
SEG[24]
SEG[25]
SEG[26]
SEG[27]
SEG[28]
SEG[29]
SEG[30]
SEG[31]
SEG[32]
SEG[33]
SEG[34]
SEG[35]
SEG[36]
SEG[37]
SEG[38]
SEG[39]
SEG[40]
SEG[41]
SEG[42]
SEG[43]
SEG[44]
SEG[45]
SEG[46]
SEG[47]
SEG[48]
SEG[49]
SEG[50]
SEG[51]
SEG[52]
SEG[53]
SEG[54]
SEG[55]
SEG[56]
SEG[57]
SEG[58]
SEG[59]
SEG[60]
SEG[61]
SEG[62]
X
Y
-2175.3
-2145.3
-2115.3
-2085.3
-2055.3
-2025.3
-1995.3
-1965.3
-1935.3
-1905.3
-1875.3
-1845.3
-1815.3
-1785.3
-1755.3
-1725.3
-1695.3
-1665.3
-1635.3
-1605.3
-1575.3
-1545.3
-1515.3
-1485.3
-1455.3
-1425.3
-1395.3
-1365.3
-1335.3
-1305.3
-1275.3
-1245.3
-1215.3
-1185.3
-1155.3
-1125.3
-1095.3
-1065.3
-1035.3
-1005.3
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
17
Pad No. Pad Name
201
202
203
204
205
206
207
208
209
210
211
212
213
214
215
216
217
218
219
220
221
222
223
224
225
226
227
228
229
230
231
232
233
234
235
236
237
238
239
240
SEG[63]
SEG[64]
SEG[65]
SEG[66]
SEG[67]
SEG[68]
SEG[69]
SEG[70]
SEG[71]
SEG[72]
SEG[73]
SEG[74]
SEG[75]
SEG[76]
SEG[77]
SEG[78]
SEG[79]
SEG[80]
SEG[81]
SEG[82]
SEG[83]
SEG[84]
SEG[85]
SEG[86]
SEG[87]
SEG[88]
SEG[89]
SEG[90]
SEG[91]
SEG[92]
SEG[93]
SEG[94]
SEG[95]
SEG[96]
SEG[97]
SEG[98]
SEG[99]
SEG[100]
SEG[101]
SEG[102]
X
Y
-975.3
-945.3
-915.3
-885.3
-855.3
-825.3
-795.3
-765.3
-735.3
-705.3
-675.3
-645.3
-615.3
-585.3
-555.3
-525.3
-495.3
-465.3
-435.3
-405.3
-375.3
-345.3
-315.3
-285.3
-255.3
-225.3
-195.3
-165.3
-135.3
-105.3
-75.3
-45.3
-15.3
14.7
44.7
74.7
104.7
134.7
164.7
194.7
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
Rev1.4-13 Sep 2010
RW1092
Dot Matrix Type LCD Controller
PAD Coordinate(1/33 Duty, SHL=0, 3-3)
Pad No. Pad Name
241
242
243
244
245
246
247
248
249
250
251
252
253
254
255
256
257
258
259
260
261
262
263
264
265
266
267
268
269
270
271
272
273
274
275
276
277
278
279
280
SEG[103]
SEG[104]
SEG[105]
SEG[106]
SEG[107]
SEG[108]
SEG[109]
SEG[110]
SEG[111]
SEG[112]
SEG[113]
SEG[114]
SEG[115]
SEG[116]
SEG[117]
SEG[118]
SEG[119]
SEG[120]
SEG[121]
SEG[122]
SEG[123]
SEG[124]
SEG[125]
SEG[126]
SEG[127]
SEG[128]
SEG[129]
SEG[130]
SEG[131]
SEG[132]
SEG[133]
SEG[134]
SEG[135]
SEG[136]
SEG[137]
SEG[138]
SEG[139]
SEG[140]
SEG[141]
SEG[142]
X
Y
224.7
254.7
284.7
314.7
344.7
374.7
404.7
434.7
464.7
494.7
524.7
554.7
584.7
614.7
644.7
674.7
704.7
734.7
764.7
794.7
824.7
854.7
884.7
914.7
944.7
974.7
1004.7
1034.7
1064.7
1094.7
1124.7
1154.7
1184.7
1214.7
1244.7
1274.7
1304.7
1334.7
1364.7
1394.7
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
Pad No. Pad Name
281
282
283
284
285
286
287
288
289
290
291
292
293
294
295
296
297
298
299
300
301
302
303
304
305
306
307
308
309
310
311
312
313
314
315
316
317
318
319
320
SEG[143]
SEG[144]
SEG[145]
SEG[146]
SEG[147]
SEG[148]
SEG[149]
SEG[150]
SEG[151]
SEG[152]
SEG[153]
SEG[154]
SEG[155]
SEG[156]
SEG[157]
SEG[158]
SEG[159]
SEG[160]
SEG[161]
SEG[162]
SEG[163]
SEG[164]
SEG[165]
SEG[166]
SEG[167]
SEG[168]
SEG[169]
SEG[170]
SEG[171]
SEG[172]
SEG[173]
SEG[174]
SEG[175]
SEG[176]
SEG[177]
SEG[178]
SEG[179]
SEG[180]
SEG[181]
SEG[182]
18
X
Y
Pad No.
1424.7
1454.7
1484.7
1514.7
1544.7
1574.7
1604.7
1634.7
1664.7
1694.7
1724.7
1754.7
1784.7
1814.7
1844.7
1874.7
1904.7
1934.7
1964.7
1994.7
2024.7
2054.7
2084.7
2114.7
2144.7
2174.7
2204.7
2234.7
2264.7
2294.7
2324.7
2354.7
2384.7
2414.7
2444.7
2474.7
2504.7
2534.7
2564.7
2594.7
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
321
322
323
324
325
326
327
328
329
330
331
332
333
334
335
336
337
338
339
340
341
342
343
344
345
346
347
348
349
350
351
352
353
Pad
Name
SEG[183]
SEG[184]
SEG[185]
SEG[186]
SEG[187]
SEG[188]
SEG[189]
SEG[190]
SEG[191]
COM[0]
COM[1]
COM[2]
COM[3]
COM[4]
COM[5]
COM[6]
COM[7]
COM[8]
COM[9]
COM[10]
COM[11]
COM[12]
COM[13]
COM[14]
COM[15]
COM[16]
COM[17]
COM[18]
COM[19]
COM[20]
COM[21]
COM[22]
COM[23]
X
Y
2624.7
2654.7
2684.7
2714.7
2744.7
2774.7
2804.7
2834.7
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-448.5
-411.1
-373.7
-336.3
-298.9
-261.5
-224.1
-186.7
-149.3
-111.9
-74.5
-37.1
0.3
37.7
75.1
112.5
149.9
187.3
224.7
262.1
299.5
336.9
374.3
411.7
449.1
Rev1.4-13 Sep 2010
RW1092
Dot Matrix Type LCD Controller
PAD Coordinate(1/33 Duty, SHL=1, 3-1)
Pad No. Pad Name
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
32
33
34
35
36
37
38
39
40
COM[7]
COM[6]
COM[5]
COM[4]
COM[3]
COM[2]
COM[1]
COM[0]
COMS1
STACOM
VSS
CS1B
CS2
VDD
RSTP
A0
VSS
X
2843.23
2805.83
2768.43
2731.03
2693.63
2656.23
2618.83
2581.43
2544.03
2424.72
2370.61
2318.55
2268.55
2214.47
2162.38
2112.38
2058.3
RW(XWR) 2006.21
E(XRD) 1956.21
VDD 1902.13
D0
1850.04
D1
1800.04
D2
1750.04
D3
1700.04
D4
1650.04
D5
1600.04
D6
1550.04
D7
1500.04
VDD 1450.04
VDD 1400.04
VDD 1350.04
VDD 1300.04
VDD2 1250.04
VDD2 1200.04
VDD2 1150.04
VDD2 1100.04
VSS
1050.04
VSS
1000.04
VSS
950.04
VSS
900.04
Y
Pad No.
445
445
445
445
445
445
445
445
445
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
41
42
43
44
45
46
47
48
49
50
51
52
53
54
55
56
57
58
59
60
61
62
63
64
65
66
67
68
69
70
71
72
73
74
75
76
77
78
79
80
Pad
Name
VOUT
VOUT
VOUT
VOUT
CAP5P
CAP5P
CAP1N
CAP1N
CAP3P
CAP3P
CAP1N
CAP1N
CAP1P
CAP1P
CAP2P
CAP2P
CAP2N
CAP2N
CAP4P
CAP4P
CAP2N
CAP2N
CAP6P
CAP6P
VSS
VRS
VDD
V4
V4
V3
V3
V2
V2
V1
V1
V0
V0
VRAB
VDD
T[8]
X
Y
843.94
793.94
743.94
693.94
637.84
587.84
537.84
487.84
437.84
387.84
337.84
287.84
237.84
187.84
137.84
87.84
37.84
-12.16
-62.16
-112.16
-162.16
-212.16
-262.16
-312.16
-371.7
-424.72
-477.72
-535.04
-585.04
-635.04
-685.04
-735.04
-785.04
-835.04
-885.04
-935.04
-985.04
-1035.04
-1097.58
-1147.58
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
19
Pad No. Pad Name
81
82
83
84
85
86
87
88
89
90
91
92
93
94
95
96
97
98
99
100
101
102
103
104
105
106
107
108
109
110
111
112
113
114
115
116
117
118
119
120
T[7]
T[6]
T[5]
T[4]
T[3]
T[2]
T[1]
T[0]
VDD
CLS
VSS
C86
VDD
PSB
VSS
IRS
VDD
SEL1
VSS
SEL2
VDD
SEL3
VSS
V0
COM[0]
COM[1]
COM[2]
COM[3]
COM[4]
COM[5]
COM[6]
COM[7]
COM[8]
COM[9]
COM[10]
COM[11]
COM[12]
COM[13]
COM[14]
COM[15]
X
Y
-1197.58
-1247.58
-1297.58
-1347.58
-1397.58
-1447.58
-1497.58
-1547.58
-1599.67
-1653.75
-1705.84
-1759.92
-1812.01
-1866.09
-1918.18
-1972.26
-2024.35
-2078.43
-2130.52
-2184.6
-2236.69
-2290.77
-2340.77
-2396.87
-2544.03
-2581.43
-2618.83
-2656.23
-2693.63
-2731.03
-2768.43
-2805.83
-2843.23
-3055
-3055
-3055
-3055
-3055
-3055
-3055
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
445
445
445
445
445
445
445
445
445
449.1
411.7
374.3
336.9
299.5
262.1
224.7
Rev1.4-13 Sep 2010
RW1092
Dot Matrix Type LCD Controller
PAD Coordinate(1/33 Duty, SHL=1, 3-2)
Pad No. Pad Name
121
122
123
124
125
126
127
128
129
130
131
132
133
134
135
136
137
138
139
140
141
142
143
144
145
146
147
148
149
150
151
152
153
154
155
156
157
158
159
160
COM[16]
COM[17]
COM[18]
COM[19]
COM[20]
COM[21]
COM[22]
COM[23]
COM[24]
COM[25]
COM[26]
COM[27]
COM[28]
COM[29]
COM[30]
COM[31]
COMS2
SEG[0]
SEG[1]
SEG[2]
SEG[3]
SEG[4]
SEG[5]
SEG[6]
SEG[7]
SEG[8]
SEG[9]
SEG[10]
SEG[11]
SEG[12]
SEG[13]
SEG[14]
SEG[15]
SEG[16]
SEG[17]
SEG[18]
SEG[19]
SEG[20]
SEG[21]
SEG[22]
X
Y
Pad No.
-3055
-3055
-3055
-3055
-3055
-3055
-3055
-3055
-3055
-3055
-3055
-3055
-3055
-3055
-3055
-3055
-3055
-3055
-2835.3
-2805.3
-2775.3
-2745.3
-2715.3
-2685.3
-2655.3
-2625.3
-2595.3
-2565.3
-2535.3
-2505.3
-2475.3
-2445.3
-2415.3
-2385.3
-2355.3
-2325.3
-2295.3
-2265.3
-2235.3
-2205.3
187.3
149.9
112.5
75.1
37.7
0.3
-37.1
-74.5
-111.9
-149.3
-186.7
-224.1
-261.5
-298.9
-336.3
-373.7
-411.1
-448.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
161
162
163
164
165
166
167
168
169
170
171
172
173
174
175
176
177
178
179
180
181
182
183
184
185
186
187
188
189
190
191
192
193
194
195
196
197
198
199
200
Pad
Name
SEG[23]
SEG[24]
SEG[25]
SEG[26]
SEG[27]
SEG[28]
SEG[29]
SEG[30]
SEG[31]
SEG[32]
SEG[33]
SEG[34]
SEG[35]
SEG[36]
SEG[37]
SEG[38]
SEG[39]
SEG[40]
SEG[41]
SEG[42]
SEG[43]
SEG[44]
SEG[45]
SEG[46]
SEG[47]
SEG[48]
SEG[49]
SEG[50]
SEG[51]
SEG[52]
SEG[53]
SEG[54]
SEG[55]
SEG[56]
SEG[57]
SEG[58]
SEG[59]
SEG[60]
SEG[61]
SEG[62]
X
Y
-2175.3
-2145.3
-2115.3
-2085.3
-2055.3
-2025.3
-1995.3
-1965.3
-1935.3
-1905.3
-1875.3
-1845.3
-1815.3
-1785.3
-1755.3
-1725.3
-1695.3
-1665.3
-1635.3
-1605.3
-1575.3
-1545.3
-1515.3
-1485.3
-1455.3
-1425.3
-1395.3
-1365.3
-1335.3
-1305.3
-1275.3
-1245.3
-1215.3
-1185.3
-1155.3
-1125.3
-1095.3
-1065.3
-1035.3
-1005.3
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
20
Pad No. Pad Name
201
202
203
204
205
206
207
208
209
210
211
212
213
214
215
216
217
218
219
220
221
222
223
224
225
226
227
228
229
230
231
232
233
234
235
236
237
238
239
240
SEG[63]
SEG[64]
SEG[65]
SEG[66]
SEG[67]
SEG[68]
SEG[69]
SEG[70]
SEG[71]
SEG[72]
SEG[73]
SEG[74]
SEG[75]
SEG[76]
SEG[77]
SEG[78]
SEG[79]
SEG[80]
SEG[81]
SEG[82]
SEG[83]
SEG[84]
SEG[85]
SEG[86]
SEG[87]
SEG[88]
SEG[89]
SEG[90]
SEG[91]
SEG[92]
SEG[93]
SEG[94]
SEG[95]
SEG[96]
SEG[97]
SEG[98]
SEG[99]
SEG[100]
SEG[101]
SEG[102]
X
Y
-975.3
-945.3
-915.3
-885.3
-855.3
-825.3
-795.3
-765.3
-735.3
-705.3
-675.3
-645.3
-615.3
-585.3
-555.3
-525.3
-495.3
-465.3
-435.3
-405.3
-375.3
-345.3
-315.3
-285.3
-255.3
-225.3
-195.3
-165.3
-135.3
-105.3
-75.3
-45.3
-15.3
14.7
44.7
74.7
104.7
134.7
164.7
194.7
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
Rev1.4-13 Sep 2010
RW1092
Dot Matrix Type LCD Controller
PAD Coordinate(1/33 Duty, SHL=1, 3-3)
Pad No. Pad Name
241
242
243
244
245
246
247
248
249
250
251
252
253
254
255
256
257
258
259
260
261
262
263
264
265
266
267
268
269
270
271
272
273
274
275
276
277
278
279
280
SEG[103]
SEG[104]
SEG[105]
SEG[106]
SEG[107]
SEG[108]
SEG[109]
SEG[110]
SEG[111]
SEG[112]
SEG[113]
SEG[114]
SEG[115]
SEG[116]
SEG[117]
SEG[118]
SEG[119]
SEG[120]
SEG[121]
SEG[122]
SEG[123]
SEG[124]
SEG[125]
SEG[126]
SEG[127]
SEG[128]
SEG[129]
SEG[130]
SEG[131]
SEG[132]
SEG[133]
SEG[134]
SEG[135]
SEG[136]
SEG[137]
SEG[138]
SEG[139]
SEG[140]
SEG[141]
SEG[142]
X
Y
224.7
254.7
284.7
314.7
344.7
374.7
404.7
434.7
464.7
494.7
524.7
554.7
584.7
614.7
644.7
674.7
704.7
734.7
764.7
794.7
824.7
854.7
884.7
914.7
944.7
974.7
1004.7
1034.7
1064.7
1094.7
1124.7
1154.7
1184.7
1214.7
1244.7
1274.7
1304.7
1334.7
1364.7
1394.7
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
Pad No. Pad Name
281
282
283
284
285
286
287
288
289
290
291
292
293
294
295
296
297
298
299
300
301
302
303
304
305
306
307
308
309
310
311
312
313
314
315
316
317
318
319
320
SEG[143]
SEG[144]
SEG[145]
SEG[146]
SEG[147]
SEG[148]
SEG[149]
SEG[150]
SEG[151]
SEG[152]
SEG[153]
SEG[154]
SEG[155]
SEG[156]
SEG[157]
SEG[158]
SEG[159]
SEG[160]
SEG[161]
SEG[162]
SEG[163]
SEG[164]
SEG[165]
SEG[166]
SEG[167]
SEG[168]
SEG[169]
SEG[170]
SEG[171]
SEG[172]
SEG[173]
SEG[174]
SEG[175]
SEG[176]
SEG[177]
SEG[178]
SEG[179]
SEG[180]
SEG[181]
SEG[182]
21
X
Y
Pad No.
1424.7
1454.7
1484.7
1514.7
1544.7
1574.7
1604.7
1634.7
1664.7
1694.7
1724.7
1754.7
1784.7
1814.7
1844.7
1874.7
1904.7
1934.7
1964.7
1994.7
2024.7
2054.7
2084.7
2114.7
2144.7
2174.7
2204.7
2234.7
2264.7
2294.7
2324.7
2354.7
2384.7
2414.7
2444.7
2474.7
2504.7
2534.7
2564.7
2594.7
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
321
322
323
324
325
326
327
328
329
330
331
332
333
334
335
336
337
338
339
340
341
342
343
344
345
346
347
348
349
350
351
352
353
Pad
Name
SEG[183]
SEG[184]
SEG[185]
SEG[186]
SEG[187]
SEG[188]
SEG[189]
SEG[190]
SEG[191]
COM[31]
COM[30]
COM[29]
COM[28]
COM[27]
COM[26]
COM[25]
COM[24]
COM[23]
COM[22]
COM[21]
COM[20]
COM[19]
COM[18]
COM[17]
COM[16]
COM[15]
COM[14]
COM[13]
COM[12]
COM[11]
COM[10]
COM[9]
COM[8]
X
Y
2624.7
2654.7
2684.7
2714.7
2744.7
2774.7
2804.7
2834.7
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-448.5
-411.1
-373.7
-336.3
-298.9
-261.5
-224.1
-186.7
-149.3
-111.9
-74.5
-37.1
0.3
37.7
75.1
112.5
149.9
187.3
224.7
262.1
299.5
336.9
374.3
411.7
449.1
Rev1.4-13 Sep 2010
RW1092
Dot Matrix Type LCD Controller
PAD Coordinate(1/17 Duty, SHL=0, 3-1)
Pad No. Pad Name
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
32
33
34
35
36
37
38
39
40
NC
NC
NC
NC
NC
NC
NC
NC
COMS1
STACOM
VSS
CS1B
CS2
VDD
RSTP
A0
VSS
X
2843.23
2805.83
2768.43
2731.03
2693.63
2656.23
2618.83
2581.43
2544.03
2424.72
2370.61
2318.55
2268.55
2214.47
2162.38
2112.38
2058.3
RW(XWR) 2006.21
E(XRD) 1956.21
VDD 1902.13
D0
1850.04
D1
1800.04
D2
1750.04
D3
1700.04
D4
1650.04
D5
1600.04
D6
1550.04
D7
1500.04
VDD 1450.04
VDD 1400.04
VDD 1350.04
VDD 1300.04
VDD2 1250.04
VDD2 1200.04
VDD2 1150.04
VDD2 1100.04
VSS
1050.04
VSS
1000.04
VSS
950.04
VSS
900.04
Y
Pad No.
445
445
445
445
445
445
445
445
445
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
41
42
43
44
45
46
47
48
49
50
51
52
53
54
55
56
57
58
59
60
61
62
63
64
65
66
67
68
69
70
71
72
73
74
75
76
77
78
79
80
Pad
Name
VOUT
VOUT
VOUT
VOUT
CAP5P
CAP5P
CAP1N
CAP1N
CAP3P
CAP3P
CAP1N
CAP1N
CAP1P
CAP1P
CAP2P
CAP2P
CAP2N
CAP2N
CAP4P
CAP4P
CAP2N
CAP2N
CAP6P
CAP6P
VSS
VRS
VDD
V4
V4
V3
V3
V2
V2
V1
V1
V0
V0
VRAB
VDD
T[8]
X
Y
Pad No.
843.94
793.94
743.94
693.94
637.84
587.84
537.84
487.84
437.84
387.84
337.84
287.84
237.84
187.84
137.84
87.84
37.84
-12.16
-62.16
-112.16
-162.16
-212.16
-262.16
-312.16
-371.7
-424.72
-477.72
-535.04
-585.04
-635.04
-685.04
-735.04
-785.04
-835.04
-885.04
-935.04
-985.04
-1035.04
-1097.58
-1147.58
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
81
82
83
84
85
86
87
88
89
90
91
92
93
94
95
96
97
98
99
100
101
102
103
104
105
106
107
108
109
110
111
112
113
114
115
116
117
118
119
120
22
Pad
Name
T[7]
T[6]
T[5]
T[4]
T[3]
T[2]
T[1]
T[0]
VDD
CLS
VSS
C86
VDD
PSB
VSS
IRS
VDD
SEL1
VSS
SEL2
VDD
SEL3
VSS
V0
NC
NC
NC
NC
NC
NC
NC
NC
NC
NC
NC
NC
NC
NC
NC
NC
X
Y
-1197.58
-1247.58
-1297.58
-1347.58
-1397.58
-1447.58
-1497.58
-1547.58
-1599.67
-1653.75
-1705.84
-1759.92
-1812.01
-1866.09
-1918.18
-1972.26
-2024.35
-2078.43
-2130.52
-2184.6
-2236.69
-2290.77
-2340.77
-2396.87
-2544.03
-2581.43
-2618.83
-2656.23
-2693.63
-2731.03
-2768.43
-2805.83
-2843.23
-3055
-3055
-3055
-3055
-3055
-3055
-3055
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
445
445
445
445
445
445
445
445
445
449.1
411.7
374.3
336.9
299.5
262.1
224.7
Rev1.4-13 Sep 2010
RW1092
Dot Matrix Type LCD Controller
PAD Coordinate(1/17 Duty, SHL=0, 3-2)
Pad No. Pad Name
121
122
123
124
125
126
127
128
129
130
131
132
133
134
135
136
137
138
139
140
141
142
143
144
145
146
147
148
149
150
151
152
153
154
155
156
157
158
159
160
COM[15]
COM[14]
COM[13]
COM[12]
COM[11]
COM[10]
COM[9]
COM[8]
COM[7]
COM[6]
COM[5]
COM[4]
COM[3]
COM[2]
COM[1]
COM[0]
COMS2
SEG[0]
SEG[1]
SEG[2]
SEG[3]
SEG[4]
SEG[5]
SEG[6]
SEG[7]
SEG[8]
SEG[9]
SEG[10]
SEG[11]
SEG[12]
SEG[13]
SEG[14]
SEG[15]
SEG[16]
SEG[17]
SEG[18]
SEG[19]
SEG[20]
SEG[21]
SEG[22]
X
Y
Pad No.
-3055
-3055
-3055
-3055
-3055
-3055
-3055
-3055
-3055
-3055
-3055
-3055
-3055
-3055
-3055
-3055
-3055
-3055
-2835.3
-2805.3
-2775.3
-2745.3
-2715.3
-2685.3
-2655.3
-2625.3
-2595.3
-2565.3
-2535.3
-2505.3
-2475.3
-2445.3
-2415.3
-2385.3
-2355.3
-2325.3
-2295.3
-2265.3
-2235.3
-2205.3
187.3
149.9
112.5
75.1
37.7
0.3
-37.1
-74.5
-111.9
-149.3
-186.7
-224.1
-261.5
-298.9
-336.3
-373.7
-411.1
-448.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
161
162
163
164
165
166
167
168
169
170
171
172
173
174
175
176
177
178
179
180
181
182
183
184
185
186
187
188
189
190
191
192
193
194
195
196
197
198
199
200
Pad
Name
SEG[23]
SEG[24]
SEG[25]
SEG[26]
SEG[27]
SEG[28]
SEG[29]
SEG[30]
SEG[31]
SEG[32]
SEG[33]
SEG[34]
SEG[35]
SEG[36]
SEG[37]
SEG[38]
SEG[39]
SEG[40]
SEG[41]
SEG[42]
SEG[43]
SEG[44]
SEG[45]
SEG[46]
SEG[47]
SEG[48]
SEG[49]
SEG[50]
SEG[51]
SEG[52]
SEG[53]
SEG[54]
SEG[55]
SEG[56]
SEG[57]
SEG[58]
SEG[59]
SEG[60]
SEG[61]
SEG[62]
X
Y
-2175.3
-2145.3
-2115.3
-2085.3
-2055.3
-2025.3
-1995.3
-1965.3
-1935.3
-1905.3
-1875.3
-1845.3
-1815.3
-1785.3
-1755.3
-1725.3
-1695.3
-1665.3
-1635.3
-1605.3
-1575.3
-1545.3
-1515.3
-1485.3
-1455.3
-1425.3
-1395.3
-1365.3
-1335.3
-1305.3
-1275.3
-1245.3
-1215.3
-1185.3
-1155.3
-1125.3
-1095.3
-1065.3
-1035.3
-1005.3
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
23
Pad No. Pad Name
201
202
203
204
205
206
207
208
209
210
211
212
213
214
215
216
217
218
219
220
221
222
223
224
225
226
227
228
229
230
231
232
233
234
235
236
237
238
239
240
SEG[63]
SEG[64]
SEG[65]
SEG[66]
SEG[67]
SEG[68]
SEG[69]
SEG[70]
SEG[71]
SEG[72]
SEG[73]
SEG[74]
SEG[75]
SEG[76]
SEG[77]
SEG[78]
SEG[79]
SEG[80]
SEG[81]
SEG[82]
SEG[83]
SEG[84]
SEG[85]
SEG[86]
SEG[87]
SEG[88]
SEG[89]
SEG[90]
SEG[91]
SEG[92]
SEG[93]
SEG[94]
SEG[95]
SEG[96]
SEG[97]
SEG[98]
SEG[99]
SEG[100]
SEG[101]
SEG[102]
X
Y
-975.3
-945.3
-915.3
-885.3
-855.3
-825.3
-795.3
-765.3
-735.3
-705.3
-675.3
-645.3
-615.3
-585.3
-555.3
-525.3
-495.3
-465.3
-435.3
-405.3
-375.3
-345.3
-315.3
-285.3
-255.3
-225.3
-195.3
-165.3
-135.3
-105.3
-75.3
-45.3
-15.3
14.7
44.7
74.7
104.7
134.7
164.7
194.7
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
Rev1.4-13 Sep 2010
RW1092
Dot Matrix Type LCD Controller
PAD Coordinate(1/17 Duty, SHL=0, 3-3)
Pad No. Pad Name
241
242
243
244
245
246
247
248
249
250
251
252
253
254
255
256
257
258
259
260
261
262
263
264
265
266
267
268
269
270
271
272
273
274
275
276
277
278
279
280
SEG[103]
SEG[104]
SEG[105]
SEG[106]
SEG[107]
SEG[108]
SEG[109]
SEG[110]
SEG[111]
SEG[112]
SEG[113]
SEG[114]
SEG[115]
SEG[116]
SEG[117]
SEG[118]
SEG[119]
SEG[120]
SEG[121]
SEG[122]
SEG[123]
SEG[124]
SEG[125]
SEG[126]
SEG[127]
SEG[128]
SEG[129]
SEG[130]
SEG[131]
SEG[132]
SEG[133]
SEG[134]
SEG[135]
SEG[136]
SEG[137]
SEG[138]
SEG[139]
SEG[140]
SEG[141]
SEG[142]
X
Y
224.7
254.7
284.7
314.7
344.7
374.7
404.7
434.7
464.7
494.7
524.7
554.7
584.7
614.7
644.7
674.7
704.7
734.7
764.7
794.7
824.7
854.7
884.7
914.7
944.7
974.7
1004.7
1034.7
1064.7
1094.7
1124.7
1154.7
1184.7
1214.7
1244.7
1274.7
1304.7
1334.7
1364.7
1394.7
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
Pad No. Pad Name
281
282
283
284
285
286
287
288
289
290
291
292
293
294
295
296
297
298
299
300
301
302
303
304
305
306
307
308
309
310
311
312
313
314
315
316
317
318
319
320
SEG[143]
SEG[144]
SEG[145]
SEG[146]
SEG[147]
SEG[148]
SEG[149]
SEG[150]
SEG[151]
SEG[152]
SEG[153]
SEG[154]
SEG[155]
SEG[156]
SEG[157]
SEG[158]
SEG[159]
SEG[160]
SEG[161]
SEG[162]
SEG[163]
SEG[164]
SEG[165]
SEG[166]
SEG[167]
SEG[168]
SEG[169]
SEG[170]
SEG[171]
SEG[172]
SEG[173]
SEG[174]
SEG[175]
SEG[176]
SEG[177]
SEG[178]
SEG[179]
SEG[180]
SEG[181]
SEG[182]
24
X
Y
Pad No.
1424.7
1454.7
1484.7
1514.7
1544.7
1574.7
1604.7
1634.7
1664.7
1694.7
1724.7
1754.7
1784.7
1814.7
1844.7
1874.7
1904.7
1934.7
1964.7
1994.7
2024.7
2054.7
2084.7
2114.7
2144.7
2174.7
2204.7
2234.7
2264.7
2294.7
2324.7
2354.7
2384.7
2414.7
2444.7
2474.7
2504.7
2534.7
2564.7
2594.7
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
321
322
323
324
325
326
327
328
329
330
331
332
333
334
335
336
337
338
339
340
341
342
343
344
345
346
347
348
349
350
351
352
353
Pad
Name
SEG[183]
SEG[184]
SEG[185]
SEG[186]
SEG[187]
SEG[188]
SEG[189]
SEG[190]
SEG[191]
COM[0]
COM[1]
COM[2]
COM[3]
COM[4]
COM[5]
COM[6]
COM[7]
COM[8]
COM[9]
COM[10]
COM[11]
COM[12]
COM[13]
COM[14]
COM[15]
NC
NC
NC
NC
NC
NC
NC
NC
X
Y
2624.7
2654.7
2684.7
2714.7
2744.7
2774.7
2804.7
2834.7
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-448.5
-411.1
-373.7
-336.3
-298.9
-261.5
-224.1
-186.7
-149.3
-111.9
-74.5
-37.1
0.3
37.7
75.1
112.5
149.9
187.3
224.7
262.1
299.5
336.9
374.3
411.7
449.1
Rev1.4-13 Sep 2010
RW1092
Dot Matrix Type LCD Controller
PAD Coordinate(1/17 Duty, SHL=1, 3-1)
Pad No. Pad Name
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
32
33
34
35
36
37
38
39
40
NC
NC
NC
NC
NC
NC
NC
NC
COMS1
STACOM
VSS
CS1B
CS2
VDD
RSTP
A0
VSS
X
2843.23
2805.83
2768.43
2731.03
2693.63
2656.23
2618.83
2581.43
2544.03
2424.72
2370.61
2318.55
2268.55
2214.47
2162.38
2112.38
2058.3
RW(XWR) 2006.21
E(XRD) 1956.21
VDD 1902.13
D0
1850.04
D1
1800.04
D2
1750.04
D3
1700.04
D4
1650.04
D5
1600.04
D6
1550.04
D7
1500.04
VDD 1450.04
VDD 1400.04
VDD 1350.04
VDD 1300.04
VDD2 1250.04
VDD2 1200.04
VDD2 1150.04
VDD2 1100.04
VSS
1050.04
VSS
1000.04
VSS
950.04
VSS
900.04
Y
Pad No.
445
445
445
445
445
445
445
445
445
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
41
42
43
44
45
46
47
48
49
50
51
52
53
54
55
56
57
58
59
60
61
62
63
64
65
66
67
68
69
70
71
72
73
74
75
76
77
78
79
80
Pad
Name
VOUT
VOUT
VOUT
VOUT
CAP5P
CAP5P
CAP1N
CAP1N
CAP3P
CAP3P
CAP1N
CAP1N
CAP1P
CAP1P
CAP2P
CAP2P
CAP2N
CAP2N
CAP4P
CAP4P
CAP2N
CAP2N
CAP6P
CAP6P
VSS
VRS
VDD
V4
V4
V3
V3
V2
V2
V1
V1
V0
V0
VRAB
VDD
T[8]
X
Y
Pad No.
843.94
793.94
743.94
693.94
637.84
587.84
537.84
487.84
437.84
387.84
337.84
287.84
237.84
187.84
137.84
87.84
37.84
-12.16
-62.16
-112.16
-162.16
-212.16
-262.16
-312.16
-371.7
-424.72
-477.72
-535.04
-585.04
-635.04
-685.04
-735.04
-785.04
-835.04
-885.04
-935.04
-985.04
-1035.04
-1097.58
-1147.58
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
81
82
83
84
85
86
87
88
89
90
91
92
93
94
95
96
97
98
99
100
101
102
103
104
105
106
107
108
109
110
111
112
113
114
115
116
117
118
119
120
25
Pad
Name
T[7]
T[6]
T[5]
T[4]
T[3]
T[2]
T[1]
T[0]
VDD
CLS
VSS
C86
VDD
PSB
VSS
IRS
VDD
SEL1
VSS
SEL2
VDD
SEL3
VSS
V0
NC
NC
NC
NC
NC
NC
NC
NC
NC
NC
NC
NC
NC
NC
NC
NC
X
Y
-1197.58
-1247.58
-1297.58
-1347.58
-1397.58
-1447.58
-1497.58
-1547.58
-1599.67
-1653.75
-1705.84
-1759.92
-1812.01
-1866.09
-1918.18
-1972.26
-2024.35
-2078.43
-2130.52
-2184.6
-2236.69
-2290.77
-2340.77
-2396.87
-2544.03
-2581.43
-2618.83
-2656.23
-2693.63
-2731.03
-2768.43
-2805.83
-2843.23
-3055
-3055
-3055
-3055
-3055
-3055
-3055
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
445
445
445
445
445
445
445
445
445
449.1
411.7
374.3
336.9
299.5
262.1
224.7
Rev1.4-13 Sep 2010
RW1092
Dot Matrix Type LCD Controller
PAD Coordinate(1/17 Duty, SHL=1, 3-2)
Pad No.
121
122
123
124
125
126
127
128
129
130
131
132
133
134
135
136
137
138
139
140
141
142
143
144
145
146
147
148
149
150
151
152
153
154
155
156
157
158
159
160
Pad
Name
COM[0]
COM[1]
COM[2]
COM[3]
COM[4]
COM[5]
COM[6]
COM[7]
COM[8]
COM[9]
COM[10]
COM[11]
COM[12]
COM[13]
COM[14]
COM[15]
COMS2
SEG[0]
SEG[1]
SEG[2]
SEG[3]
SEG[4]
SEG[5]
SEG[6]
SEG[7]
SEG[8]
SEG[9]
SEG[10]
SEG[11]
SEG[12]
SEG[13]
SEG[14]
SEG[15]
SEG[16]
SEG[17]
SEG[18]
SEG[19]
SEG[20]
SEG[21]
SEG[22]
X
Y
Pad No.
-3055
-3055
-3055
-3055
-3055
-3055
-3055
-3055
-3055
-3055
-3055
-3055
-3055
-3055
-3055
-3055
-3055
-3055
-2835.3
-2805.3
-2775.3
-2745.3
-2715.3
-2685.3
-2655.3
-2625.3
-2595.3
-2565.3
-2535.3
-2505.3
-2475.3
-2445.3
-2415.3
-2385.3
-2355.3
-2325.3
-2295.3
-2265.3
-2235.3
-2205.3
187.3
149.9
112.5
75.1
37.7
0.3
-37.1
-74.5
-111.9
-149.3
-186.7
-224.1
-261.5
-298.9
-336.3
-373.7
-411.1
-448.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
161
162
163
164
165
166
167
168
169
170
171
172
173
174
175
176
177
178
179
180
181
182
183
184
185
186
187
188
189
190
191
192
193
194
195
196
197
198
199
200
Pad
Name
SEG[23]
SEG[24]
SEG[25]
SEG[26]
SEG[27]
SEG[28]
SEG[29]
SEG[30]
SEG[31]
SEG[32]
SEG[33]
SEG[34]
SEG[35]
SEG[36]
SEG[37]
SEG[38]
SEG[39]
SEG[40]
SEG[41]
SEG[42]
SEG[43]
SEG[44]
SEG[45]
SEG[46]
SEG[47]
SEG[48]
SEG[49]
SEG[50]
SEG[51]
SEG[52]
SEG[53]
SEG[54]
SEG[55]
SEG[56]
SEG[57]
SEG[58]
SEG[59]
SEG[60]
SEG[61]
SEG[62]
X
Y
-2175.3
-2145.3
-2115.3
-2085.3
-2055.3
-2025.3
-1995.3
-1965.3
-1935.3
-1905.3
-1875.3
-1845.3
-1815.3
-1785.3
-1755.3
-1725.3
-1695.3
-1665.3
-1635.3
-1605.3
-1575.3
-1545.3
-1515.3
-1485.3
-1455.3
-1425.3
-1395.3
-1365.3
-1335.3
-1305.3
-1275.3
-1245.3
-1215.3
-1185.3
-1155.3
-1125.3
-1095.3
-1065.3
-1035.3
-1005.3
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
26
Pad No. Pad Name
201
202
203
204
205
206
207
208
209
210
211
212
213
214
215
216
217
218
219
220
221
222
223
224
225
226
227
228
229
230
231
232
233
234
235
236
237
238
239
240
SEG[63]
SEG[64]
SEG[65]
SEG[66]
SEG[67]
SEG[68]
SEG[69]
SEG[70]
SEG[71]
SEG[72]
SEG[73]
SEG[74]
SEG[75]
SEG[76]
SEG[77]
SEG[78]
SEG[79]
SEG[80]
SEG[81]
SEG[82]
SEG[83]
SEG[84]
SEG[85]
SEG[86]
SEG[87]
SEG[88]
SEG[89]
SEG[90]
SEG[91]
SEG[92]
SEG[93]
SEG[94]
SEG[95]
SEG[96]
SEG[97]
SEG[98]
SEG[99]
SEG[100]
SEG[101]
SEG[102]
X
Y
-975.3
-945.3
-915.3
-885.3
-855.3
-825.3
-795.3
-765.3
-735.3
-705.3
-675.3
-645.3
-615.3
-585.3
-555.3
-525.3
-495.3
-465.3
-435.3
-405.3
-375.3
-345.3
-315.3
-285.3
-255.3
-225.3
-195.3
-165.3
-135.3
-105.3
-75.3
-45.3
-15.3
14.7
44.7
74.7
104.7
134.7
164.7
194.7
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
Rev1.4-13 Sep 2010
RW1092
Dot Matrix Type LCD Controller
PAD Coordinate(1/17 Duty, SHL=1, 3-3)
Pad No. Pad Name
241
242
243
244
245
246
247
248
249
250
251
252
253
254
255
256
257
258
259
260
261
262
263
264
265
266
267
268
269
270
271
272
273
274
275
276
277
278
279
280
SEG[103]
SEG[104]
SEG[105]
SEG[106]
SEG[107]
SEG[108]
SEG[109]
SEG[110]
SEG[111]
SEG[112]
SEG[113]
SEG[114]
SEG[115]
SEG[116]
SEG[117]
SEG[118]
SEG[119]
SEG[120]
SEG[121]
SEG[122]
SEG[123]
SEG[124]
SEG[125]
SEG[126]
SEG[127]
SEG[128]
SEG[129]
SEG[130]
SEG[131]
SEG[132]
SEG[133]
SEG[134]
SEG[135]
SEG[136]
SEG[137]
SEG[138]
SEG[139]
SEG[140]
SEG[141]
SEG[142]
X
Y
224.7
254.7
284.7
314.7
344.7
374.7
404.7
434.7
464.7
494.7
524.7
554.7
584.7
614.7
644.7
674.7
704.7
734.7
764.7
794.7
824.7
854.7
884.7
914.7
944.7
974.7
1004.7
1034.7
1064.7
1094.7
1124.7
1154.7
1184.7
1214.7
1244.7
1274.7
1304.7
1334.7
1364.7
1394.7
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
Pad No. Pad Name
281
282
283
284
285
286
287
288
289
290
291
292
293
294
295
296
297
298
299
300
301
302
303
304
305
306
307
308
309
310
311
312
313
314
315
316
317
318
319
320
SEG[143]
SEG[144]
SEG[145]
SEG[146]
SEG[147]
SEG[148]
SEG[149]
SEG[150]
SEG[151]
SEG[152]
SEG[153]
SEG[154]
SEG[155]
SEG[156]
SEG[157]
SEG[158]
SEG[159]
SEG[160]
SEG[161]
SEG[162]
SEG[163]
SEG[164]
SEG[165]
SEG[166]
SEG[167]
SEG[168]
SEG[169]
SEG[170]
SEG[171]
SEG[172]
SEG[173]
SEG[174]
SEG[175]
SEG[176]
SEG[177]
SEG[178]
SEG[179]
SEG[180]
SEG[181]
SEG[182]
27
X
Y
Pad No.
1424.7
1454.7
1484.7
1514.7
1544.7
1574.7
1604.7
1634.7
1664.7
1694.7
1724.7
1754.7
1784.7
1814.7
1844.7
1874.7
1904.7
1934.7
1964.7
1994.7
2024.7
2054.7
2084.7
2114.7
2144.7
2174.7
2204.7
2234.7
2264.7
2294.7
2324.7
2354.7
2384.7
2414.7
2444.7
2474.7
2504.7
2534.7
2564.7
2594.7
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
321
322
323
324
325
326
327
328
329
330
331
332
333
334
335
336
337
338
339
340
341
342
343
344
345
346
347
348
349
350
351
352
353
Pad
Name
SEG[183]
SEG[184]
SEG[185]
SEG[186]
SEG[187]
SEG[188]
SEG[189]
SEG[190]
SEG[191]
COM[15]
COM[14]
COM[13]
COM[12]
COM[11]
COM[10]
COM[9]
COM[8]
COM[7]
COM[6]
COM[5]
COM[4]
COM[3]
COM[2]
COM[1]
COM[0]
NC
NC
NC
NC
NC
NC
NC
NC
X
Y
2624.7
2654.7
2684.7
2714.7
2744.7
2774.7
2804.7
2834.7
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-448.5
-411.1
-373.7
-336.3
-298.9
-261.5
-224.1
-186.7
-149.3
-111.9
-74.5
-37.1
0.3
37.7
75.1
112.5
149.9
187.3
224.7
262.1
299.5
336.9
374.3
411.7
449.1
Rev1.4-13 Sep 2010
RW1092
Dot Matrix Type LCD Controller
PAD Coordinate(1/9 Duty, SHL=0, 3-1)
Pad No. Pad Name
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
32
33
34
35
36
37
38
39
40
NC
NC
NC
NC
NC
NC
NC
NC
COMS1
STACOM
VSS
CS1B
CS2
VDD
RSTP
A0
VSS
X
2843.23
2805.83
2768.43
2731.03
2693.63
2656.23
2618.83
2581.43
2544.03
2424.72
2370.61
2318.55
2268.55
2214.47
2162.38
2112.38
2058.3
RW(XWR) 2006.21
E(XRD) 1956.21
VDD 1902.13
D0
1850.04
D1
1800.04
D2
1750.04
D3
1700.04
D4
1650.04
D5
1600.04
D6
1550.04
D7
1500.04
VDD 1450.04
VDD 1400.04
VDD 1350.04
VDD 1300.04
VDD2 1250.04
VDD2 1200.04
VDD2 1150.04
VDD2 1100.04
VSS
1050.04
VSS
1000.04
VSS
950.04
VSS
900.04
Y
Pad No.
445
445
445
445
445
445
445
445
445
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
41
42
43
44
45
46
47
48
49
50
51
52
53
54
55
56
57
58
59
60
61
62
63
64
65
66
67
68
69
70
71
72
73
74
75
76
77
78
79
80
Pad
Name
VOUT
VOUT
VOUT
VOUT
CAP5P
CAP5P
CAP1N
CAP1N
CAP3P
CAP3P
CAP1N
CAP1N
CAP1P
CAP1P
CAP2P
CAP2P
CAP2N
CAP2N
CAP4P
CAP4P
CAP2N
CAP2N
CAP6P
CAP6P
VSS
VRS
VDD
V4
V4
V3
V3
V2
V2
V1
V1
V0
V0
VRAB
VDD
T[8]
X
Y
Pad No.
843.94
793.94
743.94
693.94
637.84
587.84
537.84
487.84
437.84
387.84
337.84
287.84
237.84
187.84
137.84
87.84
37.84
-12.16
-62.16
-112.16
-162.16
-212.16
-262.16
-312.16
-371.7
-424.72
-477.72
-535.04
-585.04
-635.04
-685.04
-735.04
-785.04
-835.04
-885.04
-935.04
-985.04
-1035.04
-1097.58
-1147.58
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
81
82
83
84
85
86
87
88
89
90
91
92
93
94
95
96
97
98
99
100
101
102
103
104
105
106
107
108
109
110
111
112
113
114
115
116
117
118
119
120
28
Pad
Name
T[7]
T[6]
T[5]
T[4]
T[3]
T[2]
T[1]
T[0]
VDD
CLS
VSS
C86
VDD
PSB
VSS
IRS
VDD
SEL1
VSS
SEL2
VDD
SEL3
VSS
V0
NC
NC
NC
NC
NC
NC
NC
NC
NC
NC
NC
NC
NC
NC
NC
NC
X
Y
-1197.58
-1247.58
-1297.58
-1347.58
-1397.58
-1447.58
-1497.58
-1547.58
-1599.67
-1653.75
-1705.84
-1759.92
-1812.01
-1866.09
-1918.18
-1972.26
-2024.35
-2078.43
-2130.52
-2184.6
-2236.69
-2290.77
-2340.77
-2396.87
-2544.03
-2581.43
-2618.83
-2656.23
-2693.63
-2731.03
-2768.43
-2805.83
-2843.23
-3055
-3055
-3055
-3055
-3055
-3055
-3055
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
445
445
445
445
445
445
445
445
445
449.1
411.7
374.3
336.9
299.5
262.1
224.7
Rev1.4-13 Sep 2010
RW1092
Dot Matrix Type LCD Controller
PAD Coordinate(1/9 Duty, SHL=0, 3-2)
Pad No. Pad Name
121
122
123
124
125
126
127
128
129
130
131
132
133
134
135
136
137
138
139
140
141
142
143
144
145
146
147
148
149
150
151
152
153
154
155
156
157
158
159
160
NC
NC
NC
NC
NC
NC
NC
NC
COM[7]
COM[6]
COM[5]
COM[4]
COM[3]
COM[2]
COM[1]
COM[0]
COMS2
SEG[0]
SEG[1]
SEG[2]
SEG[3]
SEG[4]
SEG[5]
SEG[6]
SEG[7]
SEG[8]
SEG[9]
SEG[10]
SEG[11]
SEG[12]
SEG[13]
SEG[14]
SEG[15]
SEG[16]
SEG[17]
SEG[18]
SEG[19]
SEG[20]
SEG[21]
SEG[22]
X
Y
Pad No.
-3055
-3055
-3055
-3055
-3055
-3055
-3055
-3055
-3055
-3055
-3055
-3055
-3055
-3055
-3055
-3055
-3055
-3055
-2835.3
-2805.3
-2775.3
-2745.3
-2715.3
-2685.3
-2655.3
-2625.3
-2595.3
-2565.3
-2535.3
-2505.3
-2475.3
-2445.3
-2415.3
-2385.3
-2355.3
-2325.3
-2295.3
-2265.3
-2235.3
-2205.3
187.3
149.9
112.5
75.1
37.7
0.3
-37.1
-74.5
-111.9
-149.3
-186.7
-224.1
-261.5
-298.9
-336.3
-373.7
-411.1
-448.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
161
162
163
164
165
166
167
168
169
170
171
172
173
174
175
176
177
178
179
180
181
182
183
184
185
186
187
188
189
190
191
192
193
194
195
196
197
198
199
200
Pad
Name
SEG[23]
SEG[24]
SEG[25]
SEG[26]
SEG[27]
SEG[28]
SEG[29]
SEG[30]
SEG[31]
SEG[32]
SEG[33]
SEG[34]
SEG[35]
SEG[36]
SEG[37]
SEG[38]
SEG[39]
SEG[40]
SEG[41]
SEG[42]
SEG[43]
SEG[44]
SEG[45]
SEG[46]
SEG[47]
SEG[48]
SEG[49]
SEG[50]
SEG[51]
SEG[52]
SEG[53]
SEG[54]
SEG[55]
SEG[56]
SEG[57]
SEG[58]
SEG[59]
SEG[60]
SEG[61]
SEG[62]
X
Y
-2175.3
-2145.3
-2115.3
-2085.3
-2055.3
-2025.3
-1995.3
-1965.3
-1935.3
-1905.3
-1875.3
-1845.3
-1815.3
-1785.3
-1755.3
-1725.3
-1695.3
-1665.3
-1635.3
-1605.3
-1575.3
-1545.3
-1515.3
-1485.3
-1455.3
-1425.3
-1395.3
-1365.3
-1335.3
-1305.3
-1275.3
-1245.3
-1215.3
-1185.3
-1155.3
-1125.3
-1095.3
-1065.3
-1035.3
-1005.3
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
29
Pad No. Pad Name
201
202
203
204
205
206
207
208
209
210
211
212
213
214
215
216
217
218
219
220
221
222
223
224
225
226
227
228
229
230
231
232
233
234
235
236
237
238
239
240
SEG[63]
SEG[64]
SEG[65]
SEG[66]
SEG[67]
SEG[68]
SEG[69]
SEG[70]
SEG[71]
SEG[72]
SEG[73]
SEG[74]
SEG[75]
SEG[76]
SEG[77]
SEG[78]
SEG[79]
SEG[80]
SEG[81]
SEG[82]
SEG[83]
SEG[84]
SEG[85]
SEG[86]
SEG[87]
SEG[88]
SEG[89]
SEG[90]
SEG[91]
SEG[92]
SEG[93]
SEG[94]
SEG[95]
SEG[96]
SEG[97]
SEG[98]
SEG[99]
SEG[100]
SEG[101]
SEG[102]
X
Y
-975.3
-945.3
-915.3
-885.3
-855.3
-825.3
-795.3
-765.3
-735.3
-705.3
-675.3
-645.3
-615.3
-585.3
-555.3
-525.3
-495.3
-465.3
-435.3
-405.3
-375.3
-345.3
-315.3
-285.3
-255.3
-225.3
-195.3
-165.3
-135.3
-105.3
-75.3
-45.3
-15.3
14.7
44.7
74.7
104.7
134.7
164.7
194.7
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
Rev1.4-13 Sep 2010
RW1092
Dot Matrix Type LCD Controller
PAD Coordinate(1/9 Duty, SHL=0, 3-3)
Pad No. Pad Name
241
242
243
244
245
246
247
248
249
250
251
252
253
254
255
256
257
258
259
260
261
262
263
264
265
266
267
268
269
270
271
272
273
274
275
276
277
278
279
280
SEG[103]
SEG[104]
SEG[105]
SEG[106]
SEG[107]
SEG[108]
SEG[109]
SEG[110]
SEG[111]
SEG[112]
SEG[113]
SEG[114]
SEG[115]
SEG[116]
SEG[117]
SEG[118]
SEG[119]
SEG[120]
SEG[121]
SEG[122]
SEG[123]
SEG[124]
SEG[125]
SEG[126]
SEG[127]
SEG[128]
SEG[129]
SEG[130]
SEG[131]
SEG[132]
SEG[133]
SEG[134]
SEG[135]
SEG[136]
SEG[137]
SEG[138]
SEG[139]
SEG[140]
SEG[141]
SEG[142]
X
Y
224.7
254.7
284.7
314.7
344.7
374.7
404.7
434.7
464.7
494.7
524.7
554.7
584.7
614.7
644.7
674.7
704.7
734.7
764.7
794.7
824.7
854.7
884.7
914.7
944.7
974.7
1004.7
1034.7
1064.7
1094.7
1124.7
1154.7
1184.7
1214.7
1244.7
1274.7
1304.7
1334.7
1364.7
1394.7
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
Pad No. Pad Name
281
282
283
284
285
286
287
288
289
290
291
292
293
294
295
296
297
298
299
300
301
302
303
304
305
306
307
308
309
310
311
312
313
314
315
316
317
318
319
320
SEG[143]
SEG[144]
SEG[145]
SEG[146]
SEG[147]
SEG[148]
SEG[149]
SEG[150]
SEG[151]
SEG[152]
SEG[153]
SEG[154]
SEG[155]
SEG[156]
SEG[157]
SEG[158]
SEG[159]
SEG[160]
SEG[161]
SEG[162]
SEG[163]
SEG[164]
SEG[165]
SEG[166]
SEG[167]
SEG[168]
SEG[169]
SEG[170]
SEG[171]
SEG[172]
SEG[173]
SEG[174]
SEG[175]
SEG[176]
SEG[177]
SEG[178]
SEG[179]
SEG[180]
SEG[181]
SEG[182]
30
X
Y
Pad No.
1424.7
1454.7
1484.7
1514.7
1544.7
1574.7
1604.7
1634.7
1664.7
1694.7
1724.7
1754.7
1784.7
1814.7
1844.7
1874.7
1904.7
1934.7
1964.7
1994.7
2024.7
2054.7
2084.7
2114.7
2144.7
2174.7
2204.7
2234.7
2264.7
2294.7
2324.7
2354.7
2384.7
2414.7
2444.7
2474.7
2504.7
2534.7
2564.7
2594.7
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
321
322
323
324
325
326
327
328
329
330
331
332
333
334
335
336
337
338
339
340
341
342
343
344
345
346
347
348
349
350
351
352
353
Pad
Name
SEG[183]
SEG[184]
SEG[185]
SEG[186]
SEG[187]
SEG[188]
SEG[189]
SEG[190]
SEG[191]
COM[0]
COM[1]
COM[2]
COM[3]
COM[4]
COM[5]
COM[6]
COM[7]
NC
NC
NC
NC
NC
NC
NC
NC
NC
NC
NC
NC
NC
NC
NC
NC
X
Y
2624.7
2654.7
2684.7
2714.7
2744.7
2774.7
2804.7
2834.7
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-448.5
-411.1
-373.7
-336.3
-298.9
-261.5
-224.1
-186.7
-149.3
-111.9
-74.5
-37.1
0.3
37.7
75.1
112.5
149.9
187.3
224.7
262.1
299.5
336.9
374.3
411.7
449.1
Rev1.4-13 Sep 2010
RW1092
Dot Matrix Type LCD Controller
PAD Coordinate(1/9 Duty, SHL=1, 3-1)
Pad No. Pad Name
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
32
33
34
35
36
37
38
39
40
NC
NC
NC
NC
NC
NC
NC
NC
COMS1
STACOM
VSS
CS1B
CS2
VDD
RSTP
A0
VSS
X
2843.23
2805.83
2768.43
2731.03
2693.63
2656.23
2618.83
2581.43
2544.03
2424.72
2370.61
2318.55
2268.55
2214.47
2162.38
2112.38
2058.3
RW(XWR) 2006.21
E(XRD) 1956.21
VDD 1902.13
D0
1850.04
D1
1800.04
D2
1750.04
D3
1700.04
D4
1650.04
D5
1600.04
D6
1550.04
D7
1500.04
VDD 1450.04
VDD 1400.04
VDD 1350.04
VDD 1300.04
VDD2 1250.04
VDD2 1200.04
VDD2 1150.04
VDD2 1100.04
VSS
1050.04
VSS
1000.04
VSS
950.04
VSS
900.04
Y
Pad No.
445
445
445
445
445
445
445
445
445
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
41
42
43
44
45
46
47
48
49
50
51
52
53
54
55
56
57
58
59
60
61
62
63
64
65
66
67
68
69
70
71
72
73
74
75
76
77
78
79
80
Pad
Name
VOUT
VOUT
VOUT
VOUT
CAP5P
CAP5P
CAP1N
CAP1N
CAP3P
CAP3P
CAP1N
CAP1N
CAP1P
CAP1P
CAP2P
CAP2P
CAP2N
CAP2N
CAP4P
CAP4P
CAP2N
CAP2N
CAP6P
CAP6P
VSS
VRS
VDD
V4
V4
V3
V3
V2
V2
V1
V1
V0
V0
VRAB
VDD
T[8]
X
Y
Pad No.
843.94
793.94
743.94
693.94
637.84
587.84
537.84
487.84
437.84
387.84
337.84
287.84
237.84
187.84
137.84
87.84
37.84
-12.16
-62.16
-112.16
-162.16
-212.16
-262.16
-312.16
-371.7
-424.72
-477.72
-535.04
-585.04
-635.04
-685.04
-735.04
-785.04
-835.04
-885.04
-935.04
-985.04
-1035.04
-1097.58
-1147.58
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
81
82
83
84
85
86
87
88
89
90
91
92
93
94
95
96
97
98
99
100
101
102
103
104
105
106
107
108
109
110
111
112
113
114
115
116
117
118
119
120
31
Pad
Name
T[7]
T[6]
T[5]
T[4]
T[3]
T[2]
T[1]
T[0]
VDD
CLS
VSS
C86
VDD
PSB
VSS
IRS
VDD
SEL1
VSS
SEL2
VDD
SEL3
VSS
V0
NC
NC
NC
NC
NC
NC
NC
NC
NC
NC
NC
NC
NC
NC
NC
NC
X
Y
-1197.58
-1247.58
-1297.58
-1347.58
-1397.58
-1447.58
-1497.58
-1547.58
-1599.67
-1653.75
-1705.84
-1759.92
-1812.01
-1866.09
-1918.18
-1972.26
-2024.35
-2078.43
-2130.52
-2184.6
-2236.69
-2290.77
-2340.77
-2396.87
-2544.03
-2581.43
-2618.83
-2656.23
-2693.63
-2731.03
-2768.43
-2805.83
-2843.23
-3055
-3055
-3055
-3055
-3055
-3055
-3055
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
445
445
445
445
445
445
445
445
445
449.1
411.7
374.3
336.9
299.5
262.1
224.7
Rev1.4-13 Sep 2010
RW1092
Dot Matrix Type LCD Controller
PAD Coordinate(1/9 Duty, SHL=1, 3-2)
Pad No.
121
122
123
124
125
126
127
128
129
130
131
132
133
134
135
136
137
138
139
140
141
142
143
144
145
146
147
148
149
150
151
152
153
154
155
156
157
158
159
160
Pad
Name
NC
NC
NC
NC
NC
NC
NC
NC
COM[0]
COM[1]
COM[2]
COM[3]
COM[4]
COM[5]
COM[6]
COM[7]
COMS2
SEG[0]
SEG[1]
SEG[2]
SEG[3]
SEG[4]
SEG[5]
SEG[6]
SEG[7]
SEG[8]
SEG[9]
SEG[10]
SEG[11]
SEG[12]
SEG[13]
SEG[14]
SEG[15]
SEG[16]
SEG[17]
SEG[18]
SEG[19]
SEG[20]
SEG[21]
SEG[22]
X
Y
Pad No.
-3055
-3055
-3055
-3055
-3055
-3055
-3055
-3055
-3055
-3055
-3055
-3055
-3055
-3055
-3055
-3055
-3055
-3055
-2835.3
-2805.3
-2775.3
-2745.3
-2715.3
-2685.3
-2655.3
-2625.3
-2595.3
-2565.3
-2535.3
-2505.3
-2475.3
-2445.3
-2415.3
-2385.3
-2355.3
-2325.3
-2295.3
-2265.3
-2235.3
-2205.3
187.3
149.9
112.5
75.1
37.7
0.3
-37.1
-74.5
-111.9
-149.3
-186.7
-224.1
-261.5
-298.9
-336.3
-373.7
-411.1
-448.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
161
162
163
164
165
166
167
168
169
170
171
172
173
174
175
176
177
178
179
180
181
182
183
184
185
186
187
188
189
190
191
192
193
194
195
196
197
198
199
200
Pad
Name
SEG[23]
SEG[24]
SEG[25]
SEG[26]
SEG[27]
SEG[28]
SEG[29]
SEG[30]
SEG[31]
SEG[32]
SEG[33]
SEG[34]
SEG[35]
SEG[36]
SEG[37]
SEG[38]
SEG[39]
SEG[40]
SEG[41]
SEG[42]
SEG[43]
SEG[44]
SEG[45]
SEG[46]
SEG[47]
SEG[48]
SEG[49]
SEG[50]
SEG[51]
SEG[52]
SEG[53]
SEG[54]
SEG[55]
SEG[56]
SEG[57]
SEG[58]
SEG[59]
SEG[60]
SEG[61]
SEG[62]
X
Y
-2175.3
-2145.3
-2115.3
-2085.3
-2055.3
-2025.3
-1995.3
-1965.3
-1935.3
-1905.3
-1875.3
-1845.3
-1815.3
-1785.3
-1755.3
-1725.3
-1695.3
-1665.3
-1635.3
-1605.3
-1575.3
-1545.3
-1515.3
-1485.3
-1455.3
-1425.3
-1395.3
-1365.3
-1335.3
-1305.3
-1275.3
-1245.3
-1215.3
-1185.3
-1155.3
-1125.3
-1095.3
-1065.3
-1035.3
-1005.3
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
32
Pad No. Pad Name
201
202
203
204
205
206
207
208
209
210
211
212
213
214
215
216
217
218
219
220
221
222
223
224
225
226
227
228
229
230
231
232
233
234
235
236
237
238
239
240
SEG[63]
SEG[64]
SEG[65]
SEG[66]
SEG[67]
SEG[68]
SEG[69]
SEG[70]
SEG[71]
SEG[72]
SEG[73]
SEG[74]
SEG[75]
SEG[76]
SEG[77]
SEG[78]
SEG[79]
SEG[80]
SEG[81]
SEG[82]
SEG[83]
SEG[84]
SEG[85]
SEG[86]
SEG[87]
SEG[88]
SEG[89]
SEG[90]
SEG[91]
SEG[92]
SEG[93]
SEG[94]
SEG[95]
SEG[96]
SEG[97]
SEG[98]
SEG[99]
SEG[100]
SEG[101]
SEG[102]
X
Y
-975.3
-945.3
-915.3
-885.3
-855.3
-825.3
-795.3
-765.3
-735.3
-705.3
-675.3
-645.3
-615.3
-585.3
-555.3
-525.3
-495.3
-465.3
-435.3
-405.3
-375.3
-345.3
-315.3
-285.3
-255.3
-225.3
-195.3
-165.3
-135.3
-105.3
-75.3
-45.3
-15.3
14.7
44.7
74.7
104.7
134.7
164.7
194.7
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
Rev1.4-13 Sep 2010
RW1092
Dot Matrix Type LCD Controller
PAD Coordinate(1/9 Duty, SHL=1, 3-3)
Pad No. Pad Name
241
242
243
244
245
246
247
248
249
250
251
252
253
254
255
256
257
258
259
260
261
262
263
264
265
266
267
268
269
270
271
272
273
274
275
276
277
278
279
280
SEG[103]
SEG[104]
SEG[105]
SEG[106]
SEG[107]
SEG[108]
SEG[109]
SEG[110]
SEG[111]
SEG[112]
SEG[113]
SEG[114]
SEG[115]
SEG[116]
SEG[117]
SEG[118]
SEG[119]
SEG[120]
SEG[121]
SEG[122]
SEG[123]
SEG[124]
SEG[125]
SEG[126]
SEG[127]
SEG[128]
SEG[129]
SEG[130]
SEG[131]
SEG[132]
SEG[133]
SEG[134]
SEG[135]
SEG[136]
SEG[137]
SEG[138]
SEG[139]
SEG[140]
SEG[141]
SEG[142]
X
Y
224.7
254.7
284.7
314.7
344.7
374.7
404.7
434.7
464.7
494.7
524.7
554.7
584.7
614.7
644.7
674.7
704.7
734.7
764.7
794.7
824.7
854.7
884.7
914.7
944.7
974.7
1004.7
1034.7
1064.7
1094.7
1124.7
1154.7
1184.7
1214.7
1244.7
1274.7
1304.7
1334.7
1364.7
1394.7
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
Pad No. Pad Name
281
282
283
284
285
286
287
288
289
290
291
292
293
294
295
296
297
298
299
300
301
302
303
304
305
306
307
308
309
310
311
312
313
314
315
316
317
318
319
320
SEG[143]
SEG[144]
SEG[145]
SEG[146]
SEG[147]
SEG[148]
SEG[149]
SEG[150]
SEG[151]
SEG[152]
SEG[153]
SEG[154]
SEG[155]
SEG[156]
SEG[157]
SEG[158]
SEG[159]
SEG[160]
SEG[161]
SEG[162]
SEG[163]
SEG[164]
SEG[165]
SEG[166]
SEG[167]
SEG[168]
SEG[169]
SEG[170]
SEG[171]
SEG[172]
SEG[173]
SEG[174]
SEG[175]
SEG[176]
SEG[177]
SEG[178]
SEG[179]
SEG[180]
SEG[181]
SEG[182]
33
X
Y
Pad No.
1424.7
1454.7
1484.7
1514.7
1544.7
1574.7
1604.7
1634.7
1664.7
1694.7
1724.7
1754.7
1784.7
1814.7
1844.7
1874.7
1904.7
1934.7
1964.7
1994.7
2024.7
2054.7
2084.7
2114.7
2144.7
2174.7
2204.7
2234.7
2264.7
2294.7
2324.7
2354.7
2384.7
2414.7
2444.7
2474.7
2504.7
2534.7
2564.7
2594.7
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
321
322
323
324
325
326
327
328
329
330
331
332
333
334
335
336
337
338
339
340
341
342
343
344
345
346
347
348
349
350
351
352
353
Pad
Name
SEG[183]
SEG[184]
SEG[185]
SEG[186]
SEG[187]
SEG[188]
SEG[189]
SEG[190]
SEG[191]
COM[7]
COM[6]
COM[5]
COM[4]
COM[3]
COM[2]
COM[1]
COM[0]
NC
NC
NC
NC
NC
NC
NC
NC
NC
NC
NC
NC
NC
NC
NC
NC
X
Y
2624.7
2654.7
2684.7
2714.7
2744.7
2774.7
2804.7
2834.7
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-448.5
-411.1
-373.7
-336.3
-298.9
-261.5
-224.1
-186.7
-149.3
-111.9
-74.5
-37.1
0.3
37.7
75.1
112.5
149.9
187.3
224.7
262.1
299.5
336.9
374.3
411.7
449.1
Rev1.4-13 Sep 2010
RW1092
Dot Matrix Type LCD Controller
PAD Coordinate(1/5 Duty, SHL=0, 3-1)
Pad No. Pad Name
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
32
33
34
35
36
37
38
39
40
NC
NC
NC
NC
NC
NC
NC
NC
COMS1
STACOM
VSS
CS1B
CS2
VDD
RSTP
A0
VSS
X
2843.23
2805.83
2768.43
2731.03
2693.63
2656.23
2618.83
2581.43
2544.03
2424.72
2370.61
2318.55
2268.55
2214.47
2162.38
2112.38
2058.3
RW(XWR) 2006.21
E(XRD) 1956.21
VDD 1902.13
D0
1850.04
D1
1800.04
D2
1750.04
D3
1700.04
D4
1650.04
D5
1600.04
D6
1550.04
D7
1500.04
VDD 1450.04
VDD 1400.04
VDD 1350.04
VDD 1300.04
VDD2 1250.04
VDD2 1200.04
VDD2 1150.04
VDD2 1100.04
VSS
1050.04
VSS
1000.04
VSS
950.04
VSS
900.04
Y
Pad No.
445
445
445
445
445
445
445
445
445
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
41
42
43
44
45
46
47
48
49
50
51
52
53
54
55
56
57
58
59
60
61
62
63
64
65
66
67
68
69
70
71
72
73
74
75
76
77
78
79
80
Pad
Name
VOUT
VOUT
VOUT
VOUT
CAP5P
CAP5P
CAP1N
CAP1N
CAP3P
CAP3P
CAP1N
CAP1N
CAP1P
CAP1P
CAP2P
CAP2P
CAP2N
CAP2N
CAP4P
CAP4P
CAP2N
CAP2N
CAP6P
CAP6P
VSS
VRS
VDD
V4
V4
V3
V3
V2
V2
V1
V1
V0
V0
VRAB
VDD
T[8]
X
Y
Pad No.
843.94
793.94
743.94
693.94
637.84
587.84
537.84
487.84
437.84
387.84
337.84
287.84
237.84
187.84
137.84
87.84
37.84
-12.16
-62.16
-112.16
-162.16
-212.16
-262.16
-312.16
-371.7
-424.72
-477.72
-535.04
-585.04
-635.04
-685.04
-735.04
-785.04
-835.04
-885.04
-935.04
-985.04
-1035.04
-1097.58
-1147.58
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
81
82
83
84
85
86
87
88
89
90
91
92
93
94
95
96
97
98
99
100
101
102
103
104
105
106
107
108
109
110
111
112
113
114
115
116
117
118
119
120
34
Pad
Name
T[7]
T[6]
T[5]
T[4]
T[3]
T[2]
T[1]
T[0]
VDD
CLS
VSS
C86
VDD
PSB
VSS
IRS
VDD
SEL1
VSS
SEL2
VDD
SEL3
VSS
V0
NC
NC
NC
NC
NC
NC
NC
NC
NC
NC
NC
NC
NC
NC
NC
NC
X
Y
-1197.58
-1247.58
-1297.58
-1347.58
-1397.58
-1447.58
-1497.58
-1547.58
-1599.67
-1653.75
-1705.84
-1759.92
-1812.01
-1866.09
-1918.18
-1972.26
-2024.35
-2078.43
-2130.52
-2184.6
-2236.69
-2290.77
-2340.77
-2396.87
-2544.03
-2581.43
-2618.83
-2656.23
-2693.63
-2731.03
-2768.43
-2805.83
-2843.23
-3055
-3055
-3055
-3055
-3055
-3055
-3055
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
445
445
445
445
445
445
445
445
445
449.1
411.7
374.3
336.9
299.5
262.1
224.7
Rev1.4-13 Sep 2010
RW1092
Dot Matrix Type LCD Controller
PAD Coordinate(1/5 Duty, SHL=0, 3-2)
Pad No. Pad Name
121
122
123
124
125
126
127
128
129
130
131
132
133
134
135
136
137
138
139
140
141
142
143
144
145
146
147
148
149
150
151
152
153
154
155
156
157
158
159
160
NC
NC
NC
NC
NC
NC
NC
NC
NC
NC
NC
NC
COM[3]
COM[2]
COM[1]
COM[0]
COMS2
SEG[0]
SEG[1]
SEG[2]
SEG[3]
SEG[4]
SEG[5]
SEG[6]
SEG[7]
SEG[8]
SEG[9]
SEG[10]
SEG[11]
SEG[12]
SEG[13]
SEG[14]
SEG[15]
SEG[16]
SEG[17]
SEG[18]
SEG[19]
SEG[20]
SEG[21]
SEG[22]
X
Y
Pad No.
-3055
-3055
-3055
-3055
-3055
-3055
-3055
-3055
-3055
-3055
-3055
-3055
-3055
-3055
-3055
-3055
-3055
-3055
-2835.3
-2805.3
-2775.3
-2745.3
-2715.3
-2685.3
-2655.3
-2625.3
-2595.3
-2565.3
-2535.3
-2505.3
-2475.3
-2445.3
-2415.3
-2385.3
-2355.3
-2325.3
-2295.3
-2265.3
-2235.3
-2205.3
187.3
149.9
112.5
75.1
37.7
0.3
-37.1
-74.5
-111.9
-149.3
-186.7
-224.1
-261.5
-298.9
-336.3
-373.7
-411.1
-448.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
161
162
163
164
165
166
167
168
169
170
171
172
173
174
175
176
177
178
179
180
181
182
183
184
185
186
187
188
189
190
191
192
193
194
195
196
197
198
199
200
Pad
Name
SEG[23]
SEG[24]
SEG[25]
SEG[26]
SEG[27]
SEG[28]
SEG[29]
SEG[30]
SEG[31]
SEG[32]
SEG[33]
SEG[34]
SEG[35]
SEG[36]
SEG[37]
SEG[38]
SEG[39]
SEG[40]
SEG[41]
SEG[42]
SEG[43]
SEG[44]
SEG[45]
SEG[46]
SEG[47]
SEG[48]
SEG[49]
SEG[50]
SEG[51]
SEG[52]
SEG[53]
SEG[54]
SEG[55]
SEG[56]
SEG[57]
SEG[58]
SEG[59]
SEG[60]
SEG[61]
SEG[62]
X
Y
-2175.3
-2145.3
-2115.3
-2085.3
-2055.3
-2025.3
-1995.3
-1965.3
-1935.3
-1905.3
-1875.3
-1845.3
-1815.3
-1785.3
-1755.3
-1725.3
-1695.3
-1665.3
-1635.3
-1605.3
-1575.3
-1545.3
-1515.3
-1485.3
-1455.3
-1425.3
-1395.3
-1365.3
-1335.3
-1305.3
-1275.3
-1245.3
-1215.3
-1185.3
-1155.3
-1125.3
-1095.3
-1065.3
-1035.3
-1005.3
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
35
Pad No. Pad Name
201
202
203
204
205
206
207
208
209
210
211
212
213
214
215
216
217
218
219
220
221
222
223
224
225
226
227
228
229
230
231
232
233
234
235
236
237
238
239
240
SEG[63]
SEG[64]
SEG[65]
SEG[66]
SEG[67]
SEG[68]
SEG[69]
SEG[70]
SEG[71]
SEG[72]
SEG[73]
SEG[74]
SEG[75]
SEG[76]
SEG[77]
SEG[78]
SEG[79]
SEG[80]
SEG[81]
SEG[82]
SEG[83]
SEG[84]
SEG[85]
SEG[86]
SEG[87]
SEG[88]
SEG[89]
SEG[90]
SEG[91]
SEG[92]
SEG[93]
SEG[94]
SEG[95]
SEG[96]
SEG[97]
SEG[98]
SEG[99]
SEG[100]
SEG[101]
SEG[102]
X
Y
-975.3
-945.3
-915.3
-885.3
-855.3
-825.3
-795.3
-765.3
-735.3
-705.3
-675.3
-645.3
-615.3
-585.3
-555.3
-525.3
-495.3
-465.3
-435.3
-405.3
-375.3
-345.3
-315.3
-285.3
-255.3
-225.3
-195.3
-165.3
-135.3
-105.3
-75.3
-45.3
-15.3
14.7
44.7
74.7
104.7
134.7
164.7
194.7
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
Rev1.4-13 Sep 2010
RW1092
Dot Matrix Type LCD Controller
PAD Coordinate(1/5 Duty, SHL=0, 3-3)
Pad No. Pad Name
241
242
243
244
245
246
247
248
249
250
251
252
253
254
255
256
257
258
259
260
261
262
263
264
265
266
267
268
269
270
271
272
273
274
275
276
277
278
279
280
SEG[103]
SEG[104]
SEG[105]
SEG[106]
SEG[107]
SEG[108]
SEG[109]
SEG[110]
SEG[111]
SEG[112]
SEG[113]
SEG[114]
SEG[115]
SEG[116]
SEG[117]
SEG[118]
SEG[119]
SEG[120]
SEG[121]
SEG[122]
SEG[123]
SEG[124]
SEG[125]
SEG[126]
SEG[127]
SEG[128]
SEG[129]
SEG[130]
SEG[131]
SEG[132]
SEG[133]
SEG[134]
SEG[135]
SEG[136]
SEG[137]
SEG[138]
SEG[139]
SEG[140]
SEG[141]
SEG[142]
X
Y
224.7
254.7
284.7
314.7
344.7
374.7
404.7
434.7
464.7
494.7
524.7
554.7
584.7
614.7
644.7
674.7
704.7
734.7
764.7
794.7
824.7
854.7
884.7
914.7
944.7
974.7
1004.7
1034.7
1064.7
1094.7
1124.7
1154.7
1184.7
1214.7
1244.7
1274.7
1304.7
1334.7
1364.7
1394.7
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
Pad No. Pad Name
281
282
283
284
285
286
287
288
289
290
291
292
293
294
295
296
297
298
299
300
301
302
303
304
305
306
307
308
309
310
311
312
313
314
315
316
317
318
319
320
SEG[143]
SEG[144]
SEG[145]
SEG[146]
SEG[147]
SEG[148]
SEG[149]
SEG[150]
SEG[151]
SEG[152]
SEG[153]
SEG[154]
SEG[155]
SEG[156]
SEG[157]
SEG[158]
SEG[159]
SEG[160]
SEG[161]
SEG[162]
SEG[163]
SEG[164]
SEG[165]
SEG[166]
SEG[167]
SEG[168]
SEG[169]
SEG[170]
SEG[171]
SEG[172]
SEG[173]
SEG[174]
SEG[175]
SEG[176]
SEG[177]
SEG[178]
SEG[179]
SEG[180]
SEG[181]
SEG[182]
36
X
Y
Pad No.
1424.7
1454.7
1484.7
1514.7
1544.7
1574.7
1604.7
1634.7
1664.7
1694.7
1724.7
1754.7
1784.7
1814.7
1844.7
1874.7
1904.7
1934.7
1964.7
1994.7
2024.7
2054.7
2084.7
2114.7
2144.7
2174.7
2204.7
2234.7
2264.7
2294.7
2324.7
2354.7
2384.7
2414.7
2444.7
2474.7
2504.7
2534.7
2564.7
2594.7
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
321
322
323
324
325
326
327
328
329
330
331
332
333
334
335
336
337
338
339
340
341
342
343
344
345
346
347
348
349
350
351
352
353
Pad
Name
SEG[183]
SEG[184]
SEG[185]
SEG[186]
SEG[187]
SEG[188]
SEG[189]
SEG[190]
SEG[191]
COM[0]
COM[1]
COM[2]
COM[3]
NC
NC
NC
NC
NC
NC
NC
NC
NC
NC
NC
NC
NC
NC
NC
NC
NC
NC
NC
NC
X
Y
2624.7
2654.7
2684.7
2714.7
2744.7
2774.7
2804.7
2834.7
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-448.5
-411.1
-373.7
-336.3
-298.9
-261.5
-224.1
-186.7
-149.3
-111.9
-74.5
-37.1
0.3
37.7
75.1
112.5
149.9
187.3
224.7
262.1
299.5
336.9
374.3
411.7
449.1
Rev1.4-13 Sep 2010
RW1092
Dot Matrix Type LCD Controller
PAD Coordinate(1/5 Duty, SHL=1, 3-1)
Pad No. Pad Name
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
32
33
34
35
36
37
38
39
40
NC
NC
NC
NC
NC
NC
NC
NC
COMS1
STACOM
VSS
CS1B
CS2
VDD
RSTP
A0
VSS
X
2843.23
2805.83
2768.43
2731.03
2693.63
2656.23
2618.83
2581.43
2544.03
2424.72
2370.61
2318.55
2268.55
2214.47
2162.38
2112.38
2058.3
RW(XWR) 2006.21
E(XRD) 1956.21
VDD 1902.13
D0
1850.04
D1
1800.04
D2
1750.04
D3
1700.04
D4
1650.04
D5
1600.04
D6
1550.04
D7
1500.04
VDD 1450.04
VDD 1400.04
VDD 1350.04
VDD 1300.04
VDD2 1250.04
VDD2 1200.04
VDD2 1150.04
VDD2 1100.04
VSS
1050.04
VSS
1000.04
VSS
950.04
VSS
900.04
Y
Pad No.
445
445
445
445
445
445
445
445
445
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
41
42
43
44
45
46
47
48
49
50
51
52
53
54
55
56
57
58
59
60
61
62
63
64
65
66
67
68
69
70
71
72
73
74
75
76
77
78
79
80
Pad
Name
VOUT
VOUT
VOUT
VOUT
CAP5P
CAP5P
CAP1N
CAP1N
CAP3P
CAP3P
CAP1N
CAP1N
CAP1P
CAP1P
CAP2P
CAP2P
CAP2N
CAP2N
CAP4P
CAP4P
CAP2N
CAP2N
CAP6P
CAP6P
VSS
VRS
VDD
V4
V4
V3
V3
V2
V2
V1
V1
V0
V0
VRAB
VDD
T[8]
X
Y
Pad No.
843.94
793.94
743.94
693.94
637.84
587.84
537.84
487.84
437.84
387.84
337.84
287.84
237.84
187.84
137.84
87.84
37.84
-12.16
-62.16
-112.16
-162.16
-212.16
-262.16
-312.16
-371.7
-424.72
-477.72
-535.04
-585.04
-635.04
-685.04
-735.04
-785.04
-835.04
-885.04
-935.04
-985.04
-1035.04
-1097.58
-1147.58
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
81
82
83
84
85
86
87
88
89
90
91
92
93
94
95
96
97
98
99
100
101
102
103
104
105
106
107
108
109
110
111
112
113
114
115
116
117
118
119
120
37
Pad
Name
T[7]
T[6]
T[5]
T[4]
T[3]
T[2]
T[1]
T[0]
VDD
CLS
VSS
C86
VDD
PSB
VSS
IRS
VDD
SEL1
VSS
SEL2
VDD
SEL3
VSS
V0
NC
NC
NC
NC
NC
NC
NC
NC
NC
NC
NC
NC
NC
NC
NC
NC
X
Y
-1197.58
-1247.58
-1297.58
-1347.58
-1397.58
-1447.58
-1497.58
-1547.58
-1599.67
-1653.75
-1705.84
-1759.92
-1812.01
-1866.09
-1918.18
-1972.26
-2024.35
-2078.43
-2130.52
-2184.6
-2236.69
-2290.77
-2340.77
-2396.87
-2544.03
-2581.43
-2618.83
-2656.23
-2693.63
-2731.03
-2768.43
-2805.83
-2843.23
-3055
-3055
-3055
-3055
-3055
-3055
-3055
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
445
445
445
445
445
445
445
445
445
449.1
411.7
374.3
336.9
299.5
262.1
224.7
Rev1.4-13 Sep 2010
RW1092
Dot Matrix Type LCD Controller
PAD Coordinate(1/5 Duty, SHL=1, 3-2)
Pad No.
121
122
123
124
125
126
127
128
129
130
131
132
133
134
135
136
137
138
139
140
141
142
143
144
145
146
147
148
149
150
151
152
153
154
155
156
157
158
159
160
Pad
Name
NC
NC
NC
NC
NC
NC
NC
NC
NC
NC
NC
NC
COM[0]
COM[1]
COM[2]
COM[3]
COMS2
SEG[0]
SEG[1]
SEG[2]
SEG[3]
SEG[4]
SEG[5]
SEG[6]
SEG[7]
SEG[8]
SEG[9]
SEG[10]
SEG[11]
SEG[12]
SEG[13]
SEG[14]
SEG[15]
SEG[16]
SEG[17]
SEG[18]
SEG[19]
SEG[20]
SEG[21]
SEG[22]
X
Y
Pad No.
-3055
-3055
-3055
-3055
-3055
-3055
-3055
-3055
-3055
-3055
-3055
-3055
-3055
-3055
-3055
-3055
-3055
-3055
-2835.3
-2805.3
-2775.3
-2745.3
-2715.3
-2685.3
-2655.3
-2625.3
-2595.3
-2565.3
-2535.3
-2505.3
-2475.3
-2445.3
-2415.3
-2385.3
-2355.3
-2325.3
-2295.3
-2265.3
-2235.3
-2205.3
187.3
149.9
112.5
75.1
37.7
0.3
-37.1
-74.5
-111.9
-149.3
-186.7
-224.1
-261.5
-298.9
-336.3
-373.7
-411.1
-448.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
161
162
163
164
165
166
167
168
169
170
171
172
173
174
175
176
177
178
179
180
181
182
183
184
185
186
187
188
189
190
191
192
193
194
195
196
197
198
199
200
Pad
Name
SEG[23]
SEG[24]
SEG[25]
SEG[26]
SEG[27]
SEG[28]
SEG[29]
SEG[30]
SEG[31]
SEG[32]
SEG[33]
SEG[34]
SEG[35]
SEG[36]
SEG[37]
SEG[38]
SEG[39]
SEG[40]
SEG[41]
SEG[42]
SEG[43]
SEG[44]
SEG[45]
SEG[46]
SEG[47]
SEG[48]
SEG[49]
SEG[50]
SEG[51]
SEG[52]
SEG[53]
SEG[54]
SEG[55]
SEG[56]
SEG[57]
SEG[58]
SEG[59]
SEG[60]
SEG[61]
SEG[62]
X
Y
-2175.3
-2145.3
-2115.3
-2085.3
-2055.3
-2025.3
-1995.3
-1965.3
-1935.3
-1905.3
-1875.3
-1845.3
-1815.3
-1785.3
-1755.3
-1725.3
-1695.3
-1665.3
-1635.3
-1605.3
-1575.3
-1545.3
-1515.3
-1485.3
-1455.3
-1425.3
-1395.3
-1365.3
-1335.3
-1305.3
-1275.3
-1245.3
-1215.3
-1185.3
-1155.3
-1125.3
-1095.3
-1065.3
-1035.3
-1005.3
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
38
Pad No. Pad Name
201
202
203
204
205
206
207
208
209
210
211
212
213
214
215
216
217
218
219
220
221
222
223
224
225
226
227
228
229
230
231
232
233
234
235
236
237
238
239
240
SEG[63]
SEG[64]
SEG[65]
SEG[66]
SEG[67]
SEG[68]
SEG[69]
SEG[70]
SEG[71]
SEG[72]
SEG[73]
SEG[74]
SEG[75]
SEG[76]
SEG[77]
SEG[78]
SEG[79]
SEG[80]
SEG[81]
SEG[82]
SEG[83]
SEG[84]
SEG[85]
SEG[86]
SEG[87]
SEG[88]
SEG[89]
SEG[90]
SEG[91]
SEG[92]
SEG[93]
SEG[94]
SEG[95]
SEG[96]
SEG[97]
SEG[98]
SEG[99]
SEG[100]
SEG[101]
SEG[102]
X
Y
-975.3
-945.3
-915.3
-885.3
-855.3
-825.3
-795.3
-765.3
-735.3
-705.3
-675.3
-645.3
-615.3
-585.3
-555.3
-525.3
-495.3
-465.3
-435.3
-405.3
-375.3
-345.3
-315.3
-285.3
-255.3
-225.3
-195.3
-165.3
-135.3
-105.3
-75.3
-45.3
-15.3
14.7
44.7
74.7
104.7
134.7
164.7
194.7
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
Rev1.4-13 Sep 2010
RW1092
Dot Matrix Type LCD Controller
PAD Coordinate(1/5 Duty, SHL=1, 3-3)
Pad No. Pad Name
241
242
243
244
245
246
247
248
249
250
251
252
253
254
255
256
257
258
259
260
261
262
263
264
265
266
267
268
269
270
271
272
273
274
275
276
277
278
279
280
SEG[103]
SEG[104]
SEG[105]
SEG[106]
SEG[107]
SEG[108]
SEG[109]
SEG[110]
SEG[111]
SEG[112]
SEG[113]
SEG[114]
SEG[115]
SEG[116]
SEG[117]
SEG[118]
SEG[119]
SEG[120]
SEG[121]
SEG[122]
SEG[123]
SEG[124]
SEG[125]
SEG[126]
SEG[127]
SEG[128]
SEG[129]
SEG[130]
SEG[131]
SEG[132]
SEG[133]
SEG[134]
SEG[135]
SEG[136]
SEG[137]
SEG[138]
SEG[139]
SEG[140]
SEG[141]
SEG[142]
X
Y
224.7
254.7
284.7
314.7
344.7
374.7
404.7
434.7
464.7
494.7
524.7
554.7
584.7
614.7
644.7
674.7
704.7
734.7
764.7
794.7
824.7
854.7
884.7
914.7
944.7
974.7
1004.7
1034.7
1064.7
1094.7
1124.7
1154.7
1184.7
1214.7
1244.7
1274.7
1304.7
1334.7
1364.7
1394.7
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
Pad No. Pad Name
281
282
283
284
285
286
287
288
289
290
291
292
293
294
295
296
297
298
299
300
301
302
303
304
305
306
307
308
309
310
311
312
313
314
315
316
317
318
319
320
SEG[143]
SEG[144]
SEG[145]
SEG[146]
SEG[147]
SEG[148]
SEG[149]
SEG[150]
SEG[151]
SEG[152]
SEG[153]
SEG[154]
SEG[155]
SEG[156]
SEG[157]
SEG[158]
SEG[159]
SEG[160]
SEG[161]
SEG[162]
SEG[163]
SEG[164]
SEG[165]
SEG[166]
SEG[167]
SEG[168]
SEG[169]
SEG[170]
SEG[171]
SEG[172]
SEG[173]
SEG[174]
SEG[175]
SEG[176]
SEG[177]
SEG[178]
SEG[179]
SEG[180]
SEG[181]
SEG[182]
39
X
Y
Pad No.
1424.7
1454.7
1484.7
1514.7
1544.7
1574.7
1604.7
1634.7
1664.7
1694.7
1724.7
1754.7
1784.7
1814.7
1844.7
1874.7
1904.7
1934.7
1964.7
1994.7
2024.7
2054.7
2084.7
2114.7
2144.7
2174.7
2204.7
2234.7
2264.7
2294.7
2324.7
2354.7
2384.7
2414.7
2444.7
2474.7
2504.7
2534.7
2564.7
2594.7
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
321
322
323
324
325
326
327
328
329
330
331
332
333
334
335
336
337
338
339
340
341
342
343
344
345
346
347
348
349
350
351
352
353
Pad
Name
SEG[183]
SEG[184]
SEG[185]
SEG[186]
SEG[187]
SEG[188]
SEG[189]
SEG[190]
SEG[191]
COM[3]
COM[2]
COM[1]
COM[0]
NC
NC
NC
NC
NC
NC
NC
NC
NC
NC
NC
NC
NC
NC
NC
NC
NC
NC
NC
NC
X
Y
2624.7
2654.7
2684.7
2714.7
2744.7
2774.7
2804.7
2834.7
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-448.5
-411.1
-373.7
-336.3
-298.9
-261.5
-224.1
-186.7
-149.3
-111.9
-74.5
-37.1
0.3
37.7
75.1
112.5
149.9
187.3
224.7
262.1
299.5
336.9
374.3
411.7
449.1
Rev1.4-13 Sep 2010
RW1092
Dot Matrix Type LCD Controller
PAD Coordinate(Static, SHL=0, 3-1)
Pad No. Pad Name
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
32
33
34
35
36
37
38
39
40
NC
NC
NC
NC
NC
NC
NC
NC
COMS1
STACOM
VSS
CS1B
CS2
VDD
RSTP
A0
VSS
X
2843.23
2805.83
2768.43
2731.03
2693.63
2656.23
2618.83
2581.43
2544.03
2424.72
2370.61
2318.55
2268.55
2214.47
2162.38
2112.38
2058.3
RW(XWR) 2006.21
E(XRD) 1956.21
VDD 1902.13
D0
1850.04
D1
1800.04
D2
1750.04
D3
1700.04
D4
1650.04
D5
1600.04
D6
1550.04
D7
1500.04
VDD 1450.04
VDD 1400.04
VDD 1350.04
VDD 1300.04
VDD2 1250.04
VDD2 1200.04
VDD2 1150.04
VDD2 1100.04
VSS
1050.04
VSS
1000.04
VSS
950.04
VSS
900.04
Y
Pad No.
445
445
445
445
445
445
445
445
445
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
41
42
43
44
45
46
47
48
49
50
51
52
53
54
55
56
57
58
59
60
61
62
63
64
65
66
67
68
69
70
71
72
73
74
75
76
77
78
79
80
Pad
Name
VOUT
VOUT
VOUT
VOUT
CAP5P
CAP5P
CAP1N
CAP1N
CAP3P
CAP3P
CAP1N
CAP1N
CAP1P
CAP1P
CAP2P
CAP2P
CAP2N
CAP2N
CAP4P
CAP4P
CAP2N
CAP2N
CAP6P
CAP6P
VSS
VRS
VDD
V4
V4
V3
V3
V2
V2
V1
V1
V0
V0
VRAB
VDD
T[8]
X
Y
Pad No.
843.94
793.94
743.94
693.94
637.84
587.84
537.84
487.84
437.84
387.84
337.84
287.84
237.84
187.84
137.84
87.84
37.84
-12.16
-62.16
-112.16
-162.16
-212.16
-262.16
-312.16
-371.7
-424.72
-477.72
-535.04
-585.04
-635.04
-685.04
-735.04
-785.04
-835.04
-885.04
-935.04
-985.04
-1035.04
-1097.58
-1147.58
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
81
82
83
84
85
86
87
88
89
90
91
92
93
94
95
96
97
98
99
100
101
102
103
104
105
106
107
108
109
110
111
112
113
114
115
116
117
118
119
120
40
Pad
Name
T[7]
T[6]
T[5]
T[4]
T[3]
T[2]
T[1]
T[0]
VDD
CLS
VSS
C86
VDD
PSB
VSS
IRS
VDD
SEL1
VSS
SEL2
VDD
SEL3
VSS
V0
NC
NC
NC
NC
NC
NC
NC
NC
NC
NC
NC
NC
NC
NC
NC
NC
X
Y
-1197.58
-1247.58
-1297.58
-1347.58
-1397.58
-1447.58
-1497.58
-1547.58
-1599.67
-1653.75
-1705.84
-1759.92
-1812.01
-1866.09
-1918.18
-1972.26
-2024.35
-2078.43
-2130.52
-2184.6
-2236.69
-2290.77
-2340.77
-2396.87
-2544.03
-2581.43
-2618.83
-2656.23
-2693.63
-2731.03
-2768.43
-2805.83
-2843.23
-3055
-3055
-3055
-3055
-3055
-3055
-3055
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
459.4
445
445
445
445
445
445
445
445
445
449.1
411.7
374.3
336.9
299.5
262.1
224.7
Rev1.4-13 Sep 2010
RW1092
Dot Matrix Type LCD Controller
PAD Coordinate(Static, SHL=0, 3-2)
Pad No. Pad Name
121
122
123
124
125
126
127
128
129
130
131
132
133
134
135
136
137
138
139
140
141
142
143
144
145
146
147
148
149
150
151
152
153
154
155
156
157
158
159
160
NC
NC
NC
NC
NC
NC
NC
NC
NC
NC
NC
NC
NC
NC
NC
NC
COMS2
SEG[0]
SEG[1]
SEG[2]
SEG[3]
SEG[4]
SEG[5]
SEG[6]
SEG[7]
SEG[8]
SEG[9]
SEG[10]
SEG[11]
SEG[12]
SEG[13]
SEG[14]
SEG[15]
SEG[16]
SEG[17]
SEG[18]
SEG[19]
SEG[20]
SEG[21]
SEG[22]
X
Y
Pad No.
-3055
-3055
-3055
-3055
-3055
-3055
-3055
-3055
-3055
-3055
-3055
-3055
-3055
-3055
-3055
-3055
-3055
-3055
-2835.3
-2805.3
-2775.3
-2745.3
-2715.3
-2685.3
-2655.3
-2625.3
-2595.3
-2565.3
-2535.3
-2505.3
-2475.3
-2445.3
-2415.3
-2385.3
-2355.3
-2325.3
-2295.3
-2265.3
-2235.3
-2205.3
187.3
149.9
112.5
75.1
37.7
0.3
-37.1
-74.5
-111.9
-149.3
-186.7
-224.1
-261.5
-298.9
-336.3
-373.7
-411.1
-448.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
161
162
163
164
165
166
167
168
169
170
171
172
173
174
175
176
177
178
179
180
181
182
183
184
185
186
187
188
189
190
191
192
193
194
195
196
197
198
199
200
Pad
Name
SEG[23]
SEG[24]
SEG[25]
SEG[26]
SEG[27]
SEG[28]
SEG[29]
SEG[30]
SEG[31]
SEG[32]
SEG[33]
SEG[34]
SEG[35]
SEG[36]
SEG[37]
SEG[38]
SEG[39]
SEG[40]
SEG[41]
SEG[42]
SEG[43]
SEG[44]
SEG[45]
SEG[46]
SEG[47]
SEG[48]
SEG[49]
SEG[50]
SEG[51]
SEG[52]
SEG[53]
SEG[54]
SEG[55]
SEG[56]
SEG[57]
SEG[58]
SEG[59]
SEG[60]
SEG[61]
SEG[62]
X
Y
-2175.3
-2145.3
-2115.3
-2085.3
-2055.3
-2025.3
-1995.3
-1965.3
-1935.3
-1905.3
-1875.3
-1845.3
-1815.3
-1785.3
-1755.3
-1725.3
-1695.3
-1665.3
-1635.3
-1605.3
-1575.3
-1545.3
-1515.3
-1485.3
-1455.3
-1425.3
-1395.3
-1365.3
-1335.3
-1305.3
-1275.3
-1245.3
-1215.3
-1185.3
-1155.3
-1125.3
-1095.3
-1065.3
-1035.3
-1005.3
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
41
Pad No. Pad Name
201
202
203
204
205
206
207
208
209
210
211
212
213
214
215
216
217
218
219
220
221
222
223
224
225
226
227
228
229
230
231
232
233
234
235
236
237
238
239
240
SEG[63]
SEG[64]
SEG[65]
SEG[66]
SEG[67]
SEG[68]
SEG[69]
SEG[70]
SEG[71]
SEG[72]
SEG[73]
SEG[74]
SEG[75]
SEG[76]
SEG[77]
SEG[78]
SEG[79]
SEG[80]
SEG[81]
SEG[82]
SEG[83]
SEG[84]
SEG[85]
SEG[86]
SEG[87]
SEG[88]
SEG[89]
SEG[90]
SEG[91]
SEG[92]
SEG[93]
SEG[94]
SEG[95]
SEG[96]
SEG[97]
SEG[98]
SEG[99]
SEG[100]
SEG[101]
SEG[102]
X
Y
-975.3
-945.3
-915.3
-885.3
-855.3
-825.3
-795.3
-765.3
-735.3
-705.3
-675.3
-645.3
-615.3
-585.3
-555.3
-525.3
-495.3
-465.3
-435.3
-405.3
-375.3
-345.3
-315.3
-285.3
-255.3
-225.3
-195.3
-165.3
-135.3
-105.3
-75.3
-45.3
-15.3
14.7
44.7
74.7
104.7
134.7
164.7
194.7
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
Rev1.4-13 Sep 2010
RW1092
Dot Matrix Type LCD Controller
PAD Coordinate(Static, SHL=0, 3-3)
Pad No. Pad Name
241
242
243
244
245
246
247
248
249
250
251
252
253
254
255
256
257
258
259
260
261
262
263
264
265
266
267
268
269
270
271
272
273
274
275
276
277
278
279
280
SEG[103]
SEG[104]
SEG[105]
SEG[106]
SEG[107]
SEG[108]
SEG[109]
SEG[110]
SEG[111]
SEG[112]
SEG[113]
SEG[114]
SEG[115]
SEG[116]
SEG[117]
SEG[118]
SEG[119]
SEG[120]
SEG[121]
SEG[122]
SEG[123]
SEG[124]
SEG[125]
SEG[126]
SEG[127]
SEG[128]
SEG[129]
SEG[130]
SEG[131]
SEG[132]
SEG[133]
SEG[134]
SEG[135]
SEG[136]
SEG[137]
SEG[138]
SEG[139]
SEG[140]
SEG[141]
SEG[142]
X
Y
224.7
254.7
284.7
314.7
344.7
374.7
404.7
434.7
464.7
494.7
524.7
554.7
584.7
614.7
644.7
674.7
704.7
734.7
764.7
794.7
824.7
854.7
884.7
914.7
944.7
974.7
1004.7
1034.7
1064.7
1094.7
1124.7
1154.7
1184.7
1214.7
1244.7
1274.7
1304.7
1334.7
1364.7
1394.7
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
Pad No. Pad Name
281
282
283
284
285
286
287
288
289
290
291
292
293
294
295
296
297
298
299
300
301
302
303
304
305
306
307
308
309
310
311
312
313
314
315
316
317
318
319
320
SEG[143]
SEG[144]
SEG[145]
SEG[146]
SEG[147]
SEG[148]
SEG[149]
SEG[150]
SEG[151]
SEG[152]
SEG[153]
SEG[154]
SEG[155]
SEG[156]
SEG[157]
SEG[158]
SEG[159]
SEG[160]
SEG[161]
SEG[162]
SEG[163]
SEG[164]
SEG[165]
SEG[166]
SEG[167]
SEG[168]
SEG[169]
SEG[170]
SEG[171]
SEG[172]
SEG[173]
SEG[174]
SEG[175]
SEG[176]
SEG[177]
SEG[178]
SEG[179]
SEG[180]
SEG[181]
SEG[182]
42
X
Y
Pad No.
1424.7
1454.7
1484.7
1514.7
1544.7
1574.7
1604.7
1634.7
1664.7
1694.7
1724.7
1754.7
1784.7
1814.7
1844.7
1874.7
1904.7
1934.7
1964.7
1994.7
2024.7
2054.7
2084.7
2114.7
2144.7
2174.7
2204.7
2234.7
2264.7
2294.7
2324.7
2354.7
2384.7
2414.7
2444.7
2474.7
2504.7
2534.7
2564.7
2594.7
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
321
322
323
324
325
326
327
328
329
330
331
332
333
334
335
336
337
338
339
340
341
342
343
344
345
346
347
348
349
350
351
352
353
Pad
Name
SEG[183]
SEG[184]
SEG[185]
SEG[186]
SEG[187]
SEG[188]
SEG[189]
SEG[190]
SEG[191]
NC
NC
NC
NC
NC
NC
NC
NC
NC
NC
NC
NC
NC
NC
NC
NC
NC
NC
NC
NC
NC
NC
NC
NC
X
Y
2624.7
2654.7
2684.7
2714.7
2744.7
2774.7
2804.7
2834.7
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
3055
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-423.5
-448.5
-411.1
-373.7
-336.3
-298.9
-261.5
-224.1
-186.7
-149.3
-111.9
-74.5
-37.1
0.3
37.7
75.1
112.5
149.9
187.3
224.7
262.1
299.5
336.9
374.3
411.7
449.1
Rev1.4-13 Sep 2010
RW1092
Dot Matrix Type LCD Controller
BLOCK DIAGRAM (DUTY=1/97)
43
Rev1.4-13 Sep 2010
RW1092
Dot Matrix Type LCD Controller
BLOCK DIAGRAM (DUTY=1/65,1/33,1/17,1/9,1/5)
COMMON=64,32,16,8,4 for different duty selection
44
Rev1.4-13 Sep 2010
RW1092
Dot Matrix Type LCD Controller
BLOCK DIAGRAM (Static)
45
Rev1.4-13 Sep 2010
RW1092
Dot Matrix Type LCD Controller
PIN DESCRIPITON
Power Supply Pin
Pin Name
I/O
Function
No. of Pins
VDD
Power
Supply
Power supply
4
VDD2
Power
Supply
Power supply for DC-DC Converter
4
VSS
Power
Supply
Ground
4
VRS
Power
Supply
V0, V1,
V2, V3,
V4
Power
Supply
This is the internal-output VREG power supply for the LCD power supply
voltage regulator.
1
This is a multi-level power supply for the liquid crystal drive. The voltage Supply
applied is determined by the liquid crystal cell, and is changed through the use
of a resistive voltage divided or through changing the impedance using an op.
amp. Voltage levels are determined based on VSS, and must maintain the
relative magnitudes shown below.
11
V0 ≧V1 ≧V2 ≧V3 ≧V4 ≧VSS
When the power supply turns ON, the internal power supply circuits produce the
V1 to V4 voltages shown below. The voltage settings are selected using the
LCD bias set command.
LCD Power Supply Pin
Pin Name
I/O
Function
No. of Pins
CAP1P
O
DC/DC voltage converter. Connect a capacitor between this terminal and
the CAP1N terminal.
2
CAP1N
O
DC/DC voltage converter. Connect a capacitor between this terminal and
the CAP1P terminal.
4
CAP2P
O
DC/DC voltage converter. Connect a capacitor between this terminal and
the CAP2N terminal.
2
CAP2N
O
DC/DC voltage converter. Connect a capacitor between this terminal and
the CAP2P terminal.
4
CAP3P
O
DC/DC voltage converter. Connect a capacitor between this terminal and
the CAP1N terminal.
2
CAP4P
O
DC/DC voltage converter. Connect a capacitor between this terminal and
the CAP2N terminal.
2
CAP5P
O
DC/DC voltage converter. Connect a capacitor between this terminal and
the CAP1N terminal.
2
CAP6P
O
DC/DC voltage converter. Connect a capacitor between this terminal and
the CAP2N terminal.
2
VOUT
O
VRAB
I
DC/DC voltage converter. Connect a capacitor between this terminal and
VSS or VDD
Output voltage regulator terminal. Provides the voltage between VSS and
V0 through a resistive voltage divider.
IRS = “L” : the V0 voltage regulator internal resistors are not used .
IRS = “H” : the V0 voltage regulator internal resistors are used .
46
2
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Rev1.4-13 Sep 2010
RW1092
Dot Matrix Type LCD Controller
System Bus Connection Pin
Pin Name
D0 to D7
I/O
I/O
A0
I
RSTP
I
CS1B
CS2
I
E(XRD)
I
RW(XWR)
I
Function
No. of Pins
This is an 8-bit bi-directional data bus that connects to an 8-bit
standard MPU data bus.
----------------------------------------------------------------------------------------------------When the 4/3 line serial interface is selected (PSB= “L”,C86=”H”) :
D7: serial data input (SI) ; D6 : the serial clock input (SCL).
D0 to D5 are set to high impedance.
When the chip select is not active, D0 to D7 are set to high impedance.
----------------------------------------------------------------------------------------------------When the IIC serial interface selected (PSB=”L”, C86=”L”);
D7: serial clock input (SCL)
D6 , D5 , D4: serial input data (SDA_IN)
D3, D2: (SDA_OUT) serial data acknowledge for the IIC interface. By
connecting SDA_OUT to SDA_IN externally, the SDA line becomes fully IIC
interface compatible. Having the acknowledge output separated from the
serial data line is advantageous in chip on glass (COG) applications. In COG
application where the track resistance from the SDA_OUT pad to the system
SDA line can be significant, a potential divider is generated by the bus pull-up
resistor and the ITO track resistance. It is possible during the acknowledge
cycle the RW1092 will not be able to create a valid logic 0 level. By splitting
the SDA_IN input from the SDA_OUT output the device could be used in a
mode that ignores the acknowledge bit. In COG applications where the
acknowledge cycle is required, it is necessary to minimize the track
resistance from the SDA_OUT pad to the system SDA line to guarantee a
valid low level.
D6, D5, ….D2 must be connected together (SDA)
D1, D0: Is slave address (SA) bit1, 0, must connect to VDD or VSS.
When chip select is not active, D0 to D7 is high impedance.
This is connect to the least significant bit of the normal MPU address bus,
and it determines whether the data bits are data or a command.
A0 = “H”: Indicates that D0 to D7 are display data.
A0 = “L”: Indicates that D0 to D7 are control data.
When RSTP is set to “L,” the settings are initialized.
The reset operation is performed by the RSTP signal level.
This is the chip select signal. When CS1B = “L” and CS2 = “H,” then the
chip select becomes active, and data/command I/O is enabled.
• When connected to an 8080 MPU, this is active LOW.
(E) This pin is connected to the XRD signal of the 8080 MPU, and the
RW1092 series data bus is in an output status when this signal is “L”.
• When connected to a 6800 Series MPU, this is active HIGH.
This is the 6800 Series MPU enable clock input terminal.
• When connected to an 8080 MPU, this is active LOW.
RW This terminal connects to the 8080 MPU XWR signal. The signals on
the data bus are latched at the rising edge of the XWR signal.
• When connected to a 6800 Series MPU:
This is the read/write control signal input terminal.
When RW = “H”: Read.
When RW = “L”: Write.
47
8
1
1
2
1
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Rev1.4-13 Sep 2010
RW1092
Dot Matrix Type LCD Controller
Pin Name
I/O
Function
No. of Pins
Interface selection pins
PSB,C86
CLS
I
STACOM
I/O
IRS
I
PSB , C86
Interface
0,0
IIC
0,1
SPI4/SPI3
1,0
8-bit parallel 8080 series MPU
1,1
8-bit parallel 6800series MPU
Terminal to select whether or enable or disable the display clock internal
oscillator circuit.
CLS = “H” : used Internal oscillator circuit , STACOM output mode enable
CLS = “L” : used external clock input .(internal oscillator is disable)
When CLS = “L”, input the display clock through the STACOM terminal.
This is the Static display Common Output or clock input terminal.( selected
by software)
CLS
STACOM
“H”
“L”
Output
Input
SEL3
SEL2
SEL1
TEST0 ~ 8
I
I
1
This terminal selects the resistors for the V0 voltage level adjustment.
IRS = “H”: Use the internal resistors
IRS = “L”: Do not use the internal resistors. The V0 voltage level is
regulated by an external resistive voltage divider attached to the VRAB
terminal
These pins are DUTY selection.
BE=0
BE=1
SEL 3 , 2 , 1
DUTY
BIAS=(0,1)
BIAS=(0,1)
0,0,0
static
1/2
0,0,0
1
1/5
1/3, 1/2
-
0,0,1
1/9
1/5, 1/4
1/3, 1/2
0,1,0
1/17
1/5, 1/4
1/3, 1/2
0,1,1
1/33
1/6, 1/4
1/5 , 1/3
1,0,0
1/65(S1065)
1/9, 1/7
1/8, 1/6
1,0,1
1/65(S1575)
1/9, 1/7
1/8, 1/6
1,1,0
1/65
1/9, 1/7
1/8, 1/6
1, 1 , 1
1/97
1/10, 1/8
1/9, 1/7
These are terminals for IC testing.
They are set to open.
48
1
3
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Rev1.4-13 Sep 2010
RW1092
Dot Matrix Type LCD Controller
LCD Driver Pin
Pin Name
I/O
Function
No. of Pins
These are the LCD segment drive outputs. Through a combination of the
contents of the display RAM and with the FR signal, a single level is selected
from VSS, V3, V2, and V0.
n=191 for Duty 1/65,1/33, 1/17, 1/9, 1/5
n=159 for Duty 1/97
SEG0
to
SEGn
Output Voltage
RAM DATA
FR
Normal Display
Reverse Display
H
H
V0
V2
H
L
VSS
V3
L
H
V2
V0
L
L
V3
VSS
Power save
L
O
192
VSS
Through a combination of the contents of the scan data and with the FR
signal, a single level is selected from VSS, V4, V1, and V0.
n=63, 31, 15, 7, 4 for Duty 1/65,1/33, 1/17, 1/9, 1/5
n=95 for Duty 1/97
COM0
to
COMn
COMS
O
O
Scan Data
FR
Output Voltage
H
H
VSS
H
L
V0
L
H
V1
L
L
V4
Power save
L
VSS
67
These are the COM output terminals for the indicator. Both terminals output
the same signal.
Leave these open if they are not used.
2
RW1092 I/O PIN ITO Resister Limitation
PIN Name
ITO Resister
C86 , PSB ,SEL1,SEL2,SEL3 , CLS ,IRS
No Limitation
TEST0…8
Floating
VDD, VDD2,VSS, VRS, VOUT ,V0, VRAB
<100Ω
CS1B ,CS2 ,STACOM, E(XRD) , RW(XWR) , A0 , D0 …D7
<1KΩ
V1 , V2 , V3 , V4 , CAP1P , CAP1N , CAP2P , CAP2N , CAP3P , CAP4P ,
<500Ω
CAP5P,CAP6P
RSTP
<10KΩ
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Rev1.4-13 Sep 2010
RW1092
Dot Matrix Type LCD Controller
DESCRIPTION OF FUNCTION
The MPU Interface
Selecting the Interface Type
With the RW1092 chips, data transfers are done
through an 8-bit parallel data bus (D7 to D0) or
through a serial data input (SI). Through selecting the
PSB/ C86 terminal polarity to the “H” or “L” it is
possible to select either parallel data input or serial data
input as shown in Table 1.
Table 1
Interface PSB
C86
CS1B
CS2
A0
H
L
H
H
CS1B
CS2
A0
E
CS1B
CS2
A0
CS1B
H
A0
3SPI
H
H
L
L
CS1B
H
IIC
L
L
—
—
6800
8080
4SPI
E(XRD) RW(XWR)
D7
D6
D5~D0
RW
D7
D6
D5~D0
XRD
XWR
D7
D6
D5~ D0
—
—
SI
SCL
(HZ)
L
—
—
SI
—
—
—
SCL
SCL
(HZ)
SDA_IN:D6~D5
SDA_OUT: D3~D2
SA[1:0]: D1~ D0
“—” indicates fixed to either “H” or to “L”
The Parallel Interface
When the parallel interface has been selected (PSB=“H”), then it is possible to connect directly to either an
8080-system MPU or a 6800 Series MPU (shown in Table 2) by selecting the C86 terminal to either “H” or to “L”.
Table 2
C86 (PSB=H)
CS1B
CS2
A0
E(XRD) RW(XWR) D7~D0
H: 6800 Series
CS1B
CS2
A0
E
RW
D7~D0
L: 8080 Series
CS1B
CS2
A0
XRD
XWR
D7~D0
Moreover, data bus signals are recognized by a combination of A0, XRD (E), XWR (RW) signals, as shown in
Table 3.
Table 3
Shared
6800 Series
8080 Series
A0
RW
XRD
XWR
1
1
0
1
Reads the display data
1
0
1
0
Writes the display data
0
1
0
1
Status read
0
0
1
0
Write control data (command)
Function
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Rev1.4-13 Sep 2010
RW1092
Dot Matrix Type LCD Controller
The 4-SPI Serial Interface (PSB=”L”, C86=”H”)
When the 4-SPI serial interface has been selected
then when the chip is in active state (CS1B = “L” and
CS2 = “H”) the serial data input SI(DB7) and the serial
clock input SCL(DB6) can be received. The serial data
is read from the serial data input pin in the rising edge
of the serial clocks D7, D6 through D0, in this order.
This data is converted to 8 bits parallel data in the rising
edge of the eighth serial clock for the processing.
The A0 input is used to determine whether or the serial
data input is display data or command data; when A0 =
“H”, the data is display data, and when A0 = “L” then the
data is command data. The A0 input is read and used
for detection every 8th rising edge of the serial clock
after the chip becomes active. Figure 1 is a serial
interface signal chart.
Figure 1
The 3-SPI Serial Interface (PSB=”L”, C86=”H”)
If 3-Pin SPI mode is selected then when the chip is in
active state (CS1B = “L” and CS2 = “H”) , SI (DB7),
and SCLK (DB6) are used. they are serial input data,
and serial clock input, relatively. 3-Pin SPI mode does
not use A0 for data/instruction selection.
Data length instruction should be used to realize
data/instruction and data length instruction also
indicates length of data. The example of timing
sequence is shown below, data length instruction is
followed by data set.
Figure 2
* When the chip is not active, the shift registers and the counter are reset to their initial states.
* Reading is not possible while in serial interface mode.
* Caution is required on the SCL signal when it comes to line-end reflections and external noise. We recommend that operation
be rechecked on the actual equipment.
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Rev1.4-13 Sep 2010
RW1092
Dot Matrix Type LCD Controller
IIC Interface(PSB=”L”, C86=”L”)
The IIC interface receives and executes the
commands sent via the IIC Interface. It also receives
RAM data and sends it to the RAM.
The IIC Interface is for bi-directional, two-line
communication between different ICs or modules.
BIT Transfer
One data bit is transferred during each clock pulse. The
data on the SDA(DB6) line must remain stable during
the HIGH period of the clock pulse because changes in
A LOW-to-HIGH transition of the data line while the
clock is HIGH is defined as the STOP condition (P).
The START and STOP conditions are illustrated in
Figure 2
SYSTEM CONFIGURATION
The system configuration is illustrated in Figure 3.
· Transmitter: the device, which sends the data to the
bus.
· Receiver: the device, which receives the data from the
bus.
· Master: the device, which initiates a transfer,
generates clock signals and terminates a transfer.
· Slave: the device addressed by a master.
the data line at this time will be interpreted as a control
signal. Bit transfer is illustrated in Figure 1.
START AND STOP CONDITIONS
Both data and clock lines remain HIGH when the bus is
not busy. A HIGH-to-LOW transition of the data line,
while the clock is HIGH is defined as the START
condition (S).
The two lines are a Serial Data line SDA and a Serial
Clock line SCL. Both lines must be connected to a
positive supply via a pull-up resistor. Data transfer may
be initiated only when the bus is not busy.
· Multi-Master: more than one master can attempt to
control the bus at the same time without corrupting the
message.
· Arbitration: procedure to ensure that, if more than one
master simultaneously tries to control the bus, only one
is allowed to do so and the message is not corrupted.
· Synchronization: procedure to synchronize the clock
signals of two or more devices.
ACKNOWLEDGE
Each byte of eight bits is followed by an acknowledge
bit. The acknowledge bit is a HIGH signal put on the
bus by the transmitter during which time the master
generates an extra acknowledge related clock pulse. A
slave receiver which is addressed must generate an
acknowledge after the reception of each byte. A master
receiver must also generate an acknowledge after the
reception of each byte that has been clocked out of the
slave transmitter. The device that acknowledges must
pull-down the SDA line during the acknowledge clock
pulse, so that the SDA line is stable LOW during the
HIGH period of the acknowledge related clock pulse
(set-up and hold times must be taken into
consideration). A master receiver must signal an
end-of-data to the transmitter by not generating an
acknowledge on the last byte that has been clocked out
of the slave. In this event the transmitter must leave the
data line HIGH to enable the master to generate a
STOP condition. Acknowledgement on the IIC
Interface is illustrated in Figure 4.
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Rev1.4-13 Sep 2010
RW1092
Dot Matrix Type LCD Controller
SDA
SCL
data line
stable;
data valid
change
of data
allowed
Figure 1 Bit transfer
SDA
SCL
S
P
START con dition
STOP con dition
Figure 2 Definition of START and STOP conditions
MASTER
TRANSMITTER/
RECEIVER
SLAVE
RECEIVER (1)
0111100
SLAVE
RECEIVER (2)
0111101
SLAVE
RECEIVER (3)
0111110
SLAVE
RECEIVER (4)
0111111
SDA
SCL
Figure 3 System configuration
DATA OUTPUT
BY TRANSMITTER
not acknowledge
DATA OUTPUT
BY RECEIVER
acknowledge
SCL FROM
MASTER
2
1
S
8
9
clock pulse for
acknowledge ment
START
condition
Figure 4 Acknowledgement on the 2-line Interface
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Rev1.4-13 Sep 2010
RW1092
Dot Matrix Type LCD Controller
IIC Interface Protocol
The RW1092 supports command, data write
addressed slaves on the bus.
Before any data is transmitted on the IIC Interface, the
device, which should respond, is addressed first. Four
7-bit slave addresses (0111100, 0111101, 0111110
and 0111111) are reserved for the RW1092. The least
significant bit of the slave address is set by connecting
the input SA0 and SA1 to either logic 0 (VSS) or logic 1
(VDD).
The IIC Interface protocol is illustrated in Figure 5.
The sequence is initiated with a START condition (S) from the IIC Interface master, which is followed by the slave
address. All slaves with the corresponding address acknowledge in parallel, all the others will ignore the IIC
Interface transfer. After acknowledgement, one or more command words follow which define the status of the
addressed slaves.
A command word consists of a control byte, which defines Co and A0, plus a data byte.
The last control byte is tagged with a cleared most significant bit (i.e. the continuation bit Co). After a control byte
with a cleared Co bit, only data bytes will follow. The state of the A0 bit defines whether the data byte is interpreted
as a command or as RAM data. All addressed slaves on the bus also acknowledge the control and data bytes.
After the last control byte, depending on the A0 bit setting; either a series of display data bytes or command
data bytes may follow. If the A0 bit is set to logic 1, these display bytes are stored in the display RAM at the
address specified by the data pointer. The data pointer is automatically updated and the data is directed to the
intended RW1092 device. If the A0 bit of the last control byte is set to logic 0, these command bytes will be
decoded and the setting of the device will be changed according to the received commands. Only the addressed
slave makes the acknowledgement after each byte. At the end of the transmission the IIC INTERFACE-bus
master issues a STOP condition (P).If the R/W bit is set to logic 1 the chip will output data immediately after the
slave address if the A0 bit, which was sent during the last write access, is set to logic 0. If no acknowledge is
generated by the master after a byte, the driver stops transferring data to the master.
Figure 5 2-line Interface protocol
Co
0
1
Last control byte to be sent. Only a stream of data bytes is allowed to follow.
This stream may only be terminated by s STOP or RE-START condition.
Another control byte will follow the data byte unless a STOP or RE-START condition is received.
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Rev1.4-13 Sep 2010
RW1092
Dot Matrix Type LCD Controller
The Chip Select
The RW1092 have two chip select terminals: CS1B
and CS2. The MPU interface or the serial interface is
enabled only when CS1B = “L” and CS2 = “H”.
The Accessing the Display Data RAM and the Internal Registers
Data transfer at a higher speed is ensured since the
MPU is required to satisfy the cycle time (tCYC)
requirement alone in accessing the RW1092. Wait time
may not be considered.
And, in the RW1092, each time data is sent from the
MPU, a type of pipeline process between LSIs is
performed through the bus holder attached to the
internal data bus. Internal data bus.
For example, when the MPU writes data to the display
data RAM, once the data is stored in the bus holder,
then it is written to the display data RAM before the next
data write cycle. Moreover, when the MPU reads the
When the chip select is inactive, D0 to D7 enter a high
impedance state, and the A0, XRD, and XWR inputs
are inactive. When the serial interface is selected, the
shift register and the counter are reset.
display data RAM, the first data read cycle (dummy)
stores the read data in the bus holder, and then the
data is read from the bus holder to the system bus at
the next data read cycle.
There is a certain restriction in the read sequence of
the display data RAM. Please be advised that data of
the specified address is not generated by the read
instruction issued immediately after the address setup.
This data is generated in data read of the second time.
Thus, a dummy read is required whenever the address
setup or write cycle operation is conducted.
This relationship is shown in Figure 8.
The Busy Flag
When the busy flag is “1” it indicates that the RW1092
is running internal processes, and at this time no
command aside from a status read will be received.
The busy flag is outputted to D7 pin with the read
instruction. If the cycle time (tCYC) is maintained, it is
not necessary to check for this flag before each
command. This makes vast improvements in MPU
processing capabilities possible.
Figure 8.1 WRITE timing
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Rev1.4-13 Sep 2010
RW1092
Dot Matrix Type LCD Controller
Figure 8.2 READ timing
Display Data RAM
The display data RAM stores the dot data for the LCD.
It has a 97 (12 page x 8 bit +1) x 192 bit structure.
As is shown in Figure 9, the D7 to D0 display data from
the MPU corresponds to the LCD display common
direction; there are few constraints at the time of
display data transfer when multiple RW1092 are used,
thus and display structures can be created easily and
with a high degree of Moreover, reading from and
writing to the display RAM from the MPU side is
performed through the I/O buffer, which is an
independent operation from signal reading for the liquid
crystal driver. Consequently, even if the display data
RAM is accessed asynchronously during liquid crystal
display, it will not cause adverse effects on the display
(such as flickering).
D0
0
1
1
1
0
COM0
D1
1
0
0
0
0
COM1
D2
0
0
0
0
0
COM2
D3
0
1
1
1
0
COM3
D4
1
0
0
0
0
COM4
-
-
Display data RAM
Liquid crystal display
Figure 9
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Rev1.4-13 Sep 2010
RW1092
Dot Matrix Type LCD Controller
The Page Address Circuit
Page address of the display data RAM is specified
through the Page Address Set Command. The page
address must be specified again when changing pages
to perform access.
Page address 8(D3, D2, D1, D0 = 1, 0, 0, 0) is a special
RAM for icons for S1065/S1575 Mode
(SEL3,SEL2,SEL1=1, 0, X),and page address 15(D3,
D2, D1, D0= 1, 1, 1, 1) is the icon RAM for all the other
modes except S1065 and S1075, and only display data
D0 is used for icon RAM.
(see Figure 10)
The Column Address
The display data RAM column address is specified by
the Column Address Set command. The specified
column address is incremented (+1) with each display
data read/write command. This allows the MPU display
data to be accessed continuously. Moreover, the
incrementing of column addresses stops with
83H(S1065),A7H(S1575), or BFH(all the other mode
except S1065 and S1575). Because the column
address is independent of the page address, when
moving, for example, from page 0 column 83H(S1065)
to page 1 column 00H, it is necessary to respective
both the page address and the column address.
Furthermore, as is shown in Table 4, the ADC
command (segment driver direction select command)
can be used to reverse the relationship between the
display data RAM column address and the segment
output. Because of this, the constraints on the IC layout
when the LCD module is assembled can be minimized.
As is shown in Figure 4.
Table 4
Mode
Selection
Duty
1, 1, 1
1/97
1, 1, 0
1/65
1, 0, 1(S1575)
1/65
1, 0, 0(S1065)
1/65
0, 1, 1
1/33
0, 1, 0
1/17
0, 0, 1
1/9
0, 0, 0
1/5
0, 0, 0
static
SEG
Output
ADC
(D0) “0”
(D0) “1”
(D0) “0”
(D0) “1”
(D0) “0”
(D0) “1”
(D0) “0”
(D0) “1”
(D0) “0”
(D0) “1”
(D0) “0”
(D0) “1”
(D0) “0”
(D0) “1”
(D0) “0”
(D0) “1”
(D0) “0”
(D0) “1”
SEG0
0 (H)
BF (H)
0 (H)
BF (H)
0 (H)
A7 (H)
0 (H)
83 (H)
0 (H)
BF (H)
0 (H)
BF (H)
0 (H)
BF (H)
0 (H)
BF (H)
0 (H)
BF (H)
SEG N
→ Column Address →
← Column Address ←
→ Column Address →
← Column Address ←
→ Column Address→
←Column Address←
→ Column Address →
← Column Address←
→Column Address→
←Column Address←
→ Column Address →
← Column Address ←
→ Column Address →
← Column Address ←
→ Column Address →
← Column Address ←
→ Column Address →
← Column Address ←
BF (H)
0 (H)
BF (H)
0 (H)
A7 (H)
0 (H)
83 (H)
0 (H)
BF (H)
0 (H)
BF (H)
0 (H)
BF (H)
0 (H)
BF (H)
0 (H)
BF (H)
0 (H)
The Line Address Circuit
The line address circuit, as shown in Figure 10.1~10.3,
specifies the line address relating to the COM output
when the contents of the display data RAM are
displayed. Using the display start line address set
command, what is normally the top line of the display
can be specified (this is the COM0 output when the
common output mode is normal, and the
COMN ( N is depend on duty selection) output for
RW1092 , the detail is shown page 51 . The display
area is a 97 line area for the RW1092( 65 lines for
S1065 and S1075).
If the line addresses are changed dynamically using the
display start line address set command, screen
scrolling, page swapping, etc. can be performed.
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Rev1.4-13 Sep 2010
RW1092
Dot Matrix Type LCD Controller
80
81
82
83
0
3
2
1
0
1
S128
S129
S130
S131
Column
address
7F
4
S127
LCD D0 D0
Out
ADC
7E
5
Page 8
S126
0
7D
0
6
0
S125
1
Page 7
7C
1
COM55
COM56
COM57
COM58
COM59
COM60
COM61
COM62
COM63
COMS
7
1
COM54
37H
38H
39H
3AH
3BH
3CH
3DH
3EH
3FH
S124
1
36H
D7
D0
D1
D2
D3
D4
D5
D6
D7
D0
7B
0
D6
Page 6
8
0
S123
1
8
1
7B
0
Page 5
S8
1
7
0
6
1
7C
0
Page 4
7D
0
S7
0
S6
1
5
0
Page 3
7E
1
S5
1
4
0
7F
0
Page 2
S4
0
3
1
Page 1
2
0
COM7
COM8
COM9
COM10
COM11
COM12
COM13
COM14
COM15
COM16
COM17
COM18
COM19
COM20
COM21
COM22
COM23
COM24
COM25
COM26
COM27
COM28
COM29
COM30
COM31
COM32
COM33
COM34
COM35
COM36
COM37
COM38
COM39
COM40
COM41
COM42
COM43
COM44
COM45
COM46
COM47
COM48
COM49
COM50
COM51
COM52
COM53
80
0
COM6
07H
08H
09H
0AH
0BH
0CH
0DH
0EH
0FH
10H
11H
12H
13H
14H
15H
16H
17H
18H
19H
1AH
1BH
1CH
1DH
1EH
1FH
20H
21H
22H
23H
24H
25H
26H
27H
28H
29H
2AH
2BH
2CH
2DH
2EH
2FH
30H
31H
32H
33H
34H
35H
81
1
06H
D7
D0
D1
D2
D3
D4
D5
D6
D7
D0
D1
D2
D3
D4
D5
D6
D7
D0
D1
D2
D3
D4
D5
D6
D7
D0
D1
D2
D3
D4
D5
D6
D7
D0
D1
D2
D3
D4
D5
D6
D7
D0
D1
D2
D3
D4
D5
S3
0
D6
Page 0
1
0
COM0
COM1
COM2
COM3
COM4
COM5
82
0
00H
01H
02H
03H
04H
05H
S2
0
D0
D1
D2
D3
D4
D5
S1
0
COM
Output
0
0
Line Address
83
0
Data
S0
Page Address
D3 D2 D1 D0
Figure 10.1 line address circuit for S1065 (SEL3,2,1=1,0,0)
58
Rev1.4-13 Sep 2010
RW1092
Dot Matrix Type LCD Controller
Page Address
Data
D3 D2 D1 D0
D0
D1
D2
D3
0
0
0
0
D4
D5
Column
address
ADC
0
D0
1
0
S167
D0
1
S166
LCD
Out
2
S165
A7
3
S164
A6
A3
4
S163
A5
A2
5
S162
A4
A1
6
S161
A0
Page 8
7
0
S160
0
9F
0
8
1
Page 7
S159
1
COM55
COM56
COM57
COM58
COM59
COM60
COM61
COM62
COM63
COMS
8
1
COM54
37H
38H
39H
3AH
3BH
3CH
3DH
3EH
3FH
9F
1
36H
D7
D0
D1
D2
D3
D4
D5
D6
D7
D0
S8
0
D6
Page 6
7
0
A0
1
S7
1
6
0
Page 5
5
1
A1
0
A2
1
S6
0
Page 4
S5
0
4
0
A3
1
S4
0
Page 3
3
1
2
1
A4
0
A5
0
Page 2
S3
0
Page 1
S2
1
COM7
COM8
COM9
COM10
COM11
COM12
COM13
COM14
COM15
COM16
COM17
COM18
COM19
COM20
COM21
COM22
COM23
COM24
COM25
COM26
COM27
COM28
COM29
COM30
COM31
COM32
COM33
COM34
COM35
COM36
COM37
COM38
COM39
COM40
COM41
COM42
COM43
COM44
COM45
COM46
COM47
COM48
COM49
COM50
COM51
COM52
COM53
1
0
COM6
07H
08H
09H
0AH
0BH
0CH
0DH
0EH
0FH
10H
11H
12H
13H
14H
15H
16H
17H
18H
19H
1AH
1BH
1CH
1DH
1EH
1FH
20H
21H
22H
23H
24H
25H
26H
27H
28H
29H
2AH
2BH
2CH
2DH
2EH
2FH
30H
31H
32H
33H
34H
35H
A6
0
06H
D7
D0
D1
D2
D3
D4
D5
D6
D7
D0
D1
D2
D3
D4
D5
D6
D7
D0
D1
D2
D3
D4
D5
D6
D7
D0
D1
D2
D3
D4
D5
D6
D7
D0
D1
D2
D3
D4
D5
D6
D7
D0
D1
D2
D3
D4
D5
S1
1
D6
Page 0
0
0
COM0
COM1
COM2
COM3
COM4
COM5
A7
0
00H
01H
02H
03H
04H
05H
S0
0
COM
Output
Line Address
Figure 10.2 line address circuit for S1575 (SEL3,2,1=1,0,1)
59
Rev1.4-13 Sep 2010
RW1092
Dot Matrix Type LCD Controller
COM95
COMS
Column
address
D0
ADC
D0
0
1
LCD
Out
BF
0
S191
BE
1
S190
BD
2
S189
BB
3
S188
BC
4
S187
B9
5
S186
B8
6
BA
Page 15
7
1
COM94
5FH
S185
1
5EH
D7
D0
S184
1
D6
0
1
Page 11
B7
1
8
1
S183
0
Page 10
8
1
COM79
COM80
COM81
COM82
COM83
COM84
COM85
COM86
COM87
COM88
COM89
COM90
COM91
COM92
COM93
7
0
COM78
4FH
50H
51H
52H
53H
54H
55H
56H
57H
58H
59H
5AH
5BH
5CH
5DH
B7
1
4EH
D7
D0
D1
D2
D3
D4
D5
D6
D7
D0
D1
D2
D3
D4
D5
S8
0
D6
6
1
Page 9
B8
1
B9
0
S7
0
COM72
COM73
COM74
COM75
COM76
COM77
D0
D1
D2
D3
D4
D5
S6
1
48H
49H
4AH
4BH
4CH
4DH
Page 3
5
1
4
1
BA
0
BB
0
Page 2
S5
0
S4
1
3
0
Page 1
2
0
COM7
COM8
COM9
COM10
COM11
COM12
COM13
COM14
COM15
COM16
COM17
COM18
COM19
COM20
COM21
COM22
COM23
COM24
COM25
COM26
COM27
COM28
COM29
COM30
COM31
BC
1
COM6
07H
08H
09H
0AH
0BH
0CH
0DH
0EH
0FH
10H
11H
12H
13H
14H
15H
16H
17H
18H
19H
1AH
1BH
1CH
1DH
1EH
1FH
S3
0
06H
D7
D0
D1
D2
D3
D4
D5
D6
D7
D0
D1
D2
D3
D4
D5
D6
D7
D0
D1
D2
D3
D4
D5
D6
D7
1
0
D6
Page 0
BE
0
COM0
COM1
COM2
COM3
COM4
COM5
BD
0
COM Output
00H
01H
02H
03H
04H
05H
S2
0
Line Address
D0
D1
D2
D3
D4
D5
S1
0
Data
BF
0
Page Address
D2 D1 D0
S0
D3
Figure 10.3 line address circuit for RW1092(all the other modes except S1065 and S1575)
60
Rev1.4-13 Sep 2010
RW1092
Dot Matrix Type LCD Controller
The Display Data Latch Circuit
The display data latch circuit is a latch that temporarily
stores the display data that is output to the liquid crystal
driver circuit from the display data RAM.
Because the display normal/reverse status, display
The Oscillator Circuit
This is a CR-type oscillator that produces the display
clock. The oscillator circuit is only enabled when
CLS = “H”.
When CLS = “L” the oscillation stops, and the external
clock is input through the STACOM terminal.
Display Timing Generator Circuit
The display timing generator circuit generates the
timing signal to the line address circuit and the display
data latch circuit using the display clock. The display
data is latched into the display data latch circuit
synchronized with the display clock, and is output to the
data driver output terminal. Reading to the display data
liquid crystal driver circuits is completely independent
of accesses to the display data RAM by the MPU.
Consequently, even if the display data RAM is
ON/OFF status, and display all points ON/OFF
commands control only the data within the latch, they
do not change the data within the display data RAM
itself.
accessed asynchronously during liquid crystal display,
there is absolutely no adverse effect (such as
flickering) on the display.
Moreover, the display timing generator circuit
generates the common timing and the liquid crystal
alternating current signal (FR) from the display clock. It
generates a drive wave form using a 2 frame
alternating current drive method, as is shown in Figure
11, for the liquid crystal drive circuit.
Two- frame alternating current drive waveform
N=98 for duty 1/97 (Dummy COM, COM0~COM95,COMS)
N=66 for duty 1/65 (Dummy COM, COM0~COM63,COMS)
N=34 for duty 1/33 (Dummy COM, COM0~COM31,COMS)
N=18 for duty 1/17 (Dummy COM, COM0~COM15,COMS)
N=9* for duty 1/9 (COM0~COM7,COMS)
N=5* for duty1/5 ( COM0~COM3,COMS)
st
* Note: Duty 1/96+1, 1/64+1, 1/32+1, 1/16+1 have dummy COM scan line as 1 COM, but Duty 1/8+1 and 1/4+1having no
dummy scan line.
Figure 11
61
Rev1.4-13 Sep 2010
RW1092
Dot Matrix Type LCD Controller
Table 5 Shows the status of STACOM
Table 5
Operation Mode
STACOM
CLS= “H”
Output
CLS= “L”
Input
The Common Output Status Select Circuit
In the RW1092 chips, the COM output scan direction
can be selected by the common output status select
command.
(See Table 6.) Consequently, the constraints in IC
layout at the time of LCD module assembly can be
minimized.
Table 6
Status
Mode Select
Normal
Reverse
COM Scan Direction
SEL3,2,1=1,1,0
SEL3,2,1=1,1,1 SEL3,2,1=1,0,1 SEL3,2,1=0,1,1
SEL3,2,1=0,1,0 SEL3,2,1=0,0,1 SEL3,2,1=0,0,0
SEL3,2,1=1,0,0
COM0 → COM95 COM0 → COM63 COM0 → COM31 COM0 → COM15 COM0→ COM7 COM0→COM3
COM95 → COM0 COM63 → COM0 COM31 → COM0 COM15 → COM0 COM7→ COM0 COM3→ COM0
*Please refer to Page 3 ~ Page38 for the details
62
Rev1.4-13 Sep 2010
RW1092
Dot Matrix Type LCD Controller
The LCD Driver Circuit
These are a 257-channel that generates four voltage
levels for driving the LCD . The combination of the
display data, the COM scan signal, and the FR signal
produces the liquid crystal drive voltage output.
Figure 12 shows examples of the SEG and COM
output waveform.
V DD
V SS
M
COM0
V0
COM1
V1
V2
COM0
COM2
V3
V4
VSS
COM3
COM4
V0
COM5
V1
COM6
V2
COM1
V3
COM7
V4
VSS
COM8
V0
COM9
V1
V2
COM2
COM10
V3
COM11
V4
VSS
COM12
V0
COM13
V1
COM14
V2
SEG0
SEG 0
1
2
3
V3
V4
VSS
4
V0
V1
V2
SEG1
V3
V4
VSS
V0
V1
V2
V3
V4
VSS
COM0 to SEG0
-V4
-V3
-V2
-V1
-V0
V0
V1
V2
V3
V4
VSS
COM0 to SEG1
-V4
-V3
-V2
-V1
-V0
Figure 12
63
Rev1.4-13 Sep 2010
RW1092
Dot Matrix Type LCD Controller
The Power Supply Circuits
The power supply circuits are low-power consumption
power supply circuits that generate the voltage levels
required for the LCD drivers. They are Booster circuits,
voltage regulator circuits, and voltage follower circuits.
They are only enabled in master operation. The power
supply circuits can turn the Booster circuits, the voltage
regulator circuits, and the voltage follower circuits ON
or OFF independently through the use of the Power
Control Set command. Consequently, it is possible to
make an external power supply and the internal power
supply function somewhat in parallel. Table 7 shows
the Power Control Set Command 3-bit data control
function, and Table 8 shows reference combinations.
Table 7
bit
D2
D1
D0
Status
“1”
“0”
function
Booster circuit control bit
Voltage regulator circuit control bit (V/R circuit)
Voltage follower circuit control bit (V/F circuit)
ON
ON
ON
OFF
OFF
OFF
Table 8
Use Settings
D2
D1 D0
Voltage Voltage Voltage
booster regulator follower
External
voltage
input
Step-up
voltage
VDD2
Used
Only the internal power supply is used
1
1
1
ON
ON
ON
Only the voltage regulator circuit and the
voltage follower circuit are used
0
1
1
OFF
ON
ON
VOUT, VDD2
Open
Only the V/F circuit is used
0
0
1
OFF
OFF
ON
V0, VDD2
Open
Only the external power supply is used
0
0
0
OFF
OFF
OFF
V0 to V4
Open
Reference Combinations
* The “step-up system terminals” refer CAP1N, CAP1P, CAP2N, CAP2P, and CAP3P,CAP4P,CAP5P,CAP6P.
* While other combinations, not shown above, are also possible, these combinations are not recommended
because they have no practical use.
64
Rev1.4-13 Sep 2010
RW1092
Dot Matrix Type LCD Controller
The Set-up Voltage Circuits
Using the step-up voltage circuits equipped within the RW1092 chips it is possible to product a 2X,3X,4X,5X,6X or
7X step-up of the VSS – VDD2 voltage levels.
7X step-up: Connect capacitor C1 between CAP1N and
CAP1P, between CAP2N and CAP2P, between
CAP1N and CAP3P, between CAP2N and
CAP4P,between CAP1N and CAP5P, between
CAP2N and CAP6P and between VDD2 and VOUT,
to produce a voltage level in the positive direction at
the VOUT terminal that is 6 times the voltage level
between VSS and VDD2.
4X step-up: Connect capacitor C1 between CAP1N and
CAP1P, between CAP2N and CAP2P,
between CAP1N and CAP3P, and between
VDD2 and VOUT, to produce a voltage level
in the positive direction at the VOUT terminal
that is 4 times the voltage level between VSS
and VDD2.
6X step-up: Connect capacitor C1 between CAP1N and
CAP1P, between CAP2N and CAP2P, between
CAP1N and CAP3P, between CAP2N and
CAP4P,between CAP1N and CAP5P, and
between VDD2 and VOUT, to produce a voltage
level in the positive direction at the VOUT
terminal that is 6 times the voltage level
between VSS and VDD2.
3X step-up: Connect capacitor C1 between CAP1N and
CAP1P, between CAP2N and CAP2P and between
VDD2 and VOUT, and short between CAP3P and
VOUT to produce voltages level in the positive
at the VOUT terminal that is 3 times the voltage difference
between VSS and VDD2.
5X step-up: Connect capacitor C1 between CAP1N and
CAP1P, between CAP2N and CAP2P, between
CAP1N and CAP3P, between CAP2N and
CAP4P,and between VDD2 and VOUT, to
produce a voltage level in the positive direction
at the VOUT terminal that is 5 times the voltage
level between VSS and VDD2.
2X step-up: Connect capacitor C1 between CAP1N and
CAP1P, and between VDD2 and VOUT,
leave CAP2N open, and short between
CAP2P, CAP3P and VOUT to produce a
voltage in the positive direction at the VOUT
terminal that Is twice the voltage between
VSS and VDD2.The step-up voltage
relationships are shown in Figure 13.
Figure 13
* The VDD2 voltage range must be set so that the VOUT terminal voltage does not exceed the absolute maximum rated value.
65
Rev1.4-13 Sep 2010
RW1092
Dot Matrix Type LCD Controller
The Voltage Regulator Circuit
The step-up voltage generated at VOUT outputs the
LCD driver voltage V0 through the voltage regulator
circuit. Because the RW1092 chips have an internal
high-accuracy fixed voltage power supply with a
64-level electronic volume function and internal
resistors for the V0 voltage regulator, systems can be
constructed without having to include high-accuracy
voltage regulator circuit components.
(VREG thermal gradients approximate -0.05%/°C)
(A) When the V0 Voltage Regulator Internal resistors Are Used
Through the use of the V0 voltage regulator internal
resistors and the electronic volume function the liquid
crystal power supply voltage V0 can be controlled by
commands alone (without adding any external
resistors), making it possible to adjust the liquid crystal
display brightness. The V0 voltage can be calculated
using equation A-1 over the range where| V0 | < | VOUT
|.
V
( Rb
Ra )
α
Rb
=(1 +
1V
)
(
162 )
Ra
α
[∵ V = ( 1 - 162
) V ]
V0 = 1 +
EV
REG
EV
REG
VSS
VEV(constant voltage supply+electronic volume)
Internal Ra
V0
Internal Rb
Figure 14
66
Rev1.4-13 Sep 2010
RW1092
Dot Matrix Type LCD Controller
VREG is the IC-internal fixed voltage supply, and its voltage at Ta = 25°C is as shown in Table 9.
Table 9
Part no.
RW1092
Equipment Type
Thermal Gradient
VREG
–0.05 %/°C
2.1V
Internal Power Supply
α is set to 1 level of 64 possible levels by the electronic volume function depending on the data set in the 6-bit
electronic volume registers. Table 10 shows the value for α depending on the electronic volume register settings.
Rb/Ra is the V0 voltage regulator internal resistor ratio, and can be set to 8 different levels through the V0 voltage
regulator internal resistor ratio set command. The (1 + Rb/Ra) ratio assumes the values shown in Table 11
depending on the 3-bit data settings in the V0 voltage regulator internal resistor ratio register.
Table 10
D5
D4
D3
D2
D1
D0
α
0
0
0
0
0
0
0
0
0
0
0
1
0
1
0
1
1
1
0
1
1
1
0
1
63
62
61
:
:
2
1
0
0
0
0
:
:
1
1
1
1
1
1
1
1
1
V0 voltage regulator internal resistance ratio register value and (1 + Rb/Ra) ratio (Reference value)
Table 11
Register
RW1092
D2 D1 D0
0
0
0
0
1
1
1
1
0
0
1
1
0
0
1
1
(1) –0.05 %/°C
0
1
0
1
0
1
0
1
3.0
3.5
4.0
4.5
5.0
5.5
6.0
6.5
Figures 15 show V0 voltage measured by values of the internal resistance ratio resistor for V0 voltage adjustment
and electric volume resister for each temperature grade model.
67
Rev1.4-13 Sep 2010
RW1092
Dot Matrix Type LCD Controller
V0
UNIT:V
Ta = 25 °C and booster off ,regulator,follower on VDD=3V
15
14
13
12
11
10
9
8
7
6
5
4
3
2
1
0
00H
111
110
101
100
011
010
001
000
V0 voltage regulator
internal resistor ratio set
D2,D1,D0
Electronic volume registered
D5 ~ D0
1FH
3FH
Figure 15 : (1) For RW1092 the Thermal Gradient = -0.05%/°C
The V0 voltage as a function of the V0 voltage regulator internal resistor ratio register and the electronic volume
register.
Setup example: When selecting Ta = 25°C and V0 = 7V for an RW1092 on which Temperature gradient
= –0.05%/°C.Using Figure 15 and the equation A-1, t he following setup is enabled.
At this time, the variable range and the notch width of the V0 voltage is, as shown Table 13, as dependent on the
electronic volume.
Table 12
Register
D5 D4 D3 D2 D1 D0
Contents
For V0 voltage regulator
Electronic Volume
— — — 0
1
0
1
0
1
0
0
1
Table 13
V0
Variable Range
Notch width
Min
5.1 (63 levels)
Typ
7.0 (central value)
51
68
Max
Units
8.4 (0 level)
[V]
[mV]
Rev1.4-13 Sep 2010
RW1092
Dot Matrix Type LCD Controller
(B) When an External Resistance is Used (The V0 Voltage Regulator Internal
Resistors Are Not Used(1)
The liquid crystal power supply voltage V0 can also be
set without using the V0 voltage regulator internal
resistors (IRS terminal = “L”) by adding resistors Ra’
and Rb’ between VDD and VR, and between VR and
V0, respectively. When this is done, the use of the
electronic volume function makes it possible to adjust
the brightness of the liquid crystal display by controlling
the liquid crystal power supply voltage V0 through
commands.
In the range where | V0 | < | VOUT |, the V0 voltage can
be calculated using equation B-1 based on the external
resistances Ra’ and Rb’.
V
( Rb'
Ra' )
α
Rb'
=(1 +
1V
)
(
162 )
Ra'
α
[∵ V = ( 1 - 162
) V ]
V0 = 1 +
EV
REG
EV
REG
VSS
VEV(fixed voltage power supply+electronic volume)
External
resistor Ra'
V0
External
resistor Rb'
Figure 16
Setup example: When selecting Ta = 25°C and V0 = 7
V for RW1092 the temperature gradient = –0.05%/°C.
When the central value of the electron volume register
is (D5, D4, D3, D2, D1, D0) = (1, 0, 0, 0, 0, 0), then α =
31 and VREG = 2.1V so, according to equation B-1,
Rb'
V0 = 1 +
Ra'
Rb'
7V = 1 +
Ra'
(
(
) (
) (
α
1162
31
1162
)
)
Consequently, by equations B-2 and B-3
Rb'
= 3.12
Ra'
Ra' = 340kΩ
VREG
(2.1)
Moreover, when the value of the current running
through Ra’ and Rb’ is set to 5 uA,
Rb' = 1060kΩ
At this time, the V0 voltage variable range and notch
width, based on the electron volume function, is as
given in Table 14.
.
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Dot Matrix Type LCD Controller
When External Resistors are Used (The V0 Voltage Regulator Internal Resistor Are
Not Used) (2)
When the external resistor described above are used,
adding a variable resistor as well makes it possible to
perform fine adjustments on Ra’ and Rb’, to set the
liquid crystal drive voltage V0. In this case, the use of
the electronic volume function makes it possible to
control the liquid crystal power supply voltage V0 by
Setup example: When selecting Ta = 25°C and V0= 5
to 9 V (using R2) for an RW1092 the temperature
gradient = –0.05%/°C.
When the central value for the electronic volume
register is set at (D5, D4, D3, D2, D1, D0) = (1, 0, 0, 0,
0, 0), then α = 31 and VREG = 2.1 V so, according to
equation C-1, when ΔR2 = 0 Ω, in order to make V0 =
9 V,
(
9V = 1 +
R3+R2
R1
) (
1-
31
162
)
(2.1)
When ΔR2 = R2, in order to make V = –5 V,
(
5V = 1 +
R3
R1+R2
31
) ( 1 - 162
)
commands to adjust the liquid crystal display
brightness.
In the range where | V0 | < | VOUT | the V0 voltage can
be calculated by equation C-1 below based on the R1
and R2 (variable resistor) and R3 settings, where R2
can be subjected to fine adjustments (Δ R2).
With this, according to equation C-2, C-3 and C-4,
R1 = 264kΩ
R2 = 211kΩ
R3 = 925kΩ
The V0 voltage variable range and notch width based
on the electron volume function is as shown in
Table 15.
(2.1)
When the current flowing VDD and V0 is set to 5uA,
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Rev1.4-13 Sep 2010
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Dot Matrix Type LCD Controller
Table 15
V0
Min
Variable Range
Notch width
5.3 (63 levels)
Typ
Max
7.0 (central value)
53
Units
8.7 (0 level)
[V]
[mV]
* When the V0 voltage regulator internal resistors or the electronic volume function is used, it is necessary to at
least set the voltage regulator circuit and the voltage follower circuit to an operating mode using the power control
set commands. Moreover, it is necessary to provide a voltage from VOUT when the Booster circuit is OFF.
* The VR terminal is enabled only when the V0 voltage regulator internal resistors are not used (i.e. the IRS
terminal = “L”).
When the V0 voltage regulator internal resistors are used (i.e. when the IRS terminal = “H”), then the VR terminal
is left open.
* Because the input impedance of the VR terminal is high, it is necessary to take into consideration short leads,
shield cables, etc. to handle noise.
The LCD Voltage Generator Circuit
The V0 voltage is produced by a resistive voltage
divider within the IC, and can be produced at the V1,
V2, V3, and V4 voltage levels required for liquid crystal
driving. Moreover, when the voltage follower changes
the impedance, it provides V1, V2, V3 and V4 to the
liquid crystal drive circuit.
The Internal Power Supply Shutdown Sequence
The sequence shown in Figure 18 is recommended for
shutting down the internal power supply, first placing
Sequence
the power supply in power saver mode and then turning
the power supply OFF.
Details(Command, status)
Step 1
Display OFF
D7
1
Step 2
Display all Point ON
1
End
Internal Power Supply OFF
D6
0
0
Command address
D5 D4 D3 D2
1
0
1
1
1
0
0
1
D1
1
D0
0
0
1
Power Saver
commands
(compound)
Figure 18
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Dot Matrix Type LCD Controller
Reference Circuit Examples
(1) When the V0 voltage regulator internal resistor
is not used.
(2) When the V0 voltage regulator internal resistor
is used.
(3) When the V/F circuit alone is used
(4) When the built-in power is not used
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Dot Matrix Type LCD Controller
Item
C1
C2
Set value
2.2 to 4.7
2.2 to 4.7
units
uF
uF
C1 and C2 are determined by the size of the LCD being driven
* 1. Because the VR terminal input impedance is high, use short leads and shielded lines.
* 2. C1 and C2 are determined by the size of the LCD being driven. Select a value that will stabilize the liquid crystal
drive voltage.
Example of the Process by which to Determine the Settings:
• Turn the voltage regulator circuit and voltage follower circuit ON and supply a voltage to VOUT from the outside.
• Determine C2 by displaying an LCD pattern with a heavy load (such as horizontal stripes) and selecting a C2 that
stabilizes the liquid crystal drive voltages (V0 to V4). Note that all C2 capacitors must have the same capacitance
value.
• Next turn all the power supplies ON and determine C1.
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Dot Matrix Type LCD Controller
The Reset Circuit
When the RSTP input comes to the “L” level, these
LSIs return to the default state. Their default states are
as follows:
1. Display OFF.
2. Normal display.
3. ADC select: Normal (ADC command D0 = “L”)
4. Power control register: (D2, D1, D0) = (0, 0, 0)
5. Serial interface internal register data clear.
6. LCD power supply bias rate:
1/97 DUTY = 1/10 bias
1/65 DUTY = 1/9 bias
1/33 DUTY = 1/6 bias
1/17,1/9 DUTY = 1/5 bias
1/5 DUTY = 1/3 bias
7. All-indicator lamps-on OFF (All-indicator lamps
ON/OFF. command D0 = “L”)
8. Power saving clear.
9. V0 voltage regulator internal resistors Ra and Rb
separation.
10. Output conditions of SEG and COM terminals
SEG=VSS , COM=VSS
11. Read modify write OFF.
12. Static indicator OFF Static indicator register :
STA =0.
13. Display start line set to first line.
14. Column address set to Address 0.
15. Page address set to Page 0.
16. Common output status normal.
17. V0 voltage regulator internal resistor ratio set mode
clear.
18. Electronic volume register set mode clear
Electronic volume register :
(D5, D4, D3, D2, D1, D0) = (1, 0. 0, 0, 0,0)
19. Test mode clear.
20. BE=0
21. Internal resistor used ExtR=1
22. DFR3~DFR0=0000
On the other hand, when the reset command is used,
the above default settings from 11 to 22 are only
executed.
When the power is turned on, the IC internal state
becomes unstable, and it is necessary to initialize it
using the RSTP terminal. After the initialization, each
input terminal should be controlled normally.
Moreover, when the control signal from the MPU is in
the high impedance, an over current may flow to the IC.
After applying a current, it is necessary to take proper
measures to prevent the input terminal from getting into
the high impedance state.
If the internal liquid crystal power supply circuit is not
used on RW1092,it is necessary that RSTP is “H” when
the external liquid crystal power supply is turned on.
This IC has the function to discharge V0 when RSTP is
“L,” and the external power supply short-circuits to VSS
when RSTP is “L.”
While RSTP is “L,” the oscillator and the display timing
generator stop, and the CL, FR terminals are fixed to
“H.” The terminals D0 to D7 are not affected. The VSS
level is output from the SEG and COM output
terminals. This means that an internal resistor is
connected between VSS and V0.
When the internal liquid crystal power supply circuit is
not used on other models of RW1092 series, it is
necessary that RSTP is “L” when the external liquid
crystal power supply is turned on.
While RSTP is “L,” the oscillator works but the display
timing generator stops, and the STACOM terminals is
fixed to “H.” The terminals D0 to D7 are not affected
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Dot Matrix Type LCD Controller
COMMANDS
The RW1092 identify the data bus signals by a combination of A0, XRD (E), XWR(R/W) signals. Command
interpretation and execution does not depend on the external clock, but rather is performed through internal
timing only, and thus the processing is fast enough that normally a busy check is not required.
In the 8080 MPU interface, commands are launched by inputting a low pulse to the RD terminal for reading, and
inputting a low pulse to the XWR terminal for writing. In the 6800 Series MPU interface, the interface is placed in
a read mode when an “H” signal is input to the R/W terminal and placed in a write mode when a “L” signal is input
to the R/W terminal and then the command is launched by inputting a high pulse to the E terminal. Consequently,
the 6800 Series MPU interface is different than the 80x86 Series MPU interface in that in the explanation of
commands and the display commands the status read and display data read XRD (E) becomes “1(H)”. In the
explanations below the commands are explained using the 8080 Series MPU interface as the example.
When the serial interface is selected, the data is input in sequence starting with D7.<Explanation of Commands>
Display ON/OFF
This command turns the display ON and OFF.
E
A0
0
XRD
1
R/W
XWR
0
D7
D6
D5
D4
D3
D2
D1
D0
Setting
1
0
1
0
1
1
1
1
0
Display ON
Display OFF
When the display OFF command is executed when in the display all points ON mode, power saver mode is entered.
See the section on the power saver for details.
Display Start Line Set
This command is used to specify the display start line address of the display data RAM shown in Figure 10. For
further details see the explanation of this function in “The Line Address Circuit”.
(a) Start line set command for S1065 and S1575 (single byte command)
E
A0
0
XRD
1
R/W
XWR
0
D7
D6
D5
D4
D3
D2
D1
D0
Line address
0
1
0
0
0
0
0
0
0
0
0
0
0
0
0
0
1
0
1
0
1
1
1
1
1
1
1
1
1
1
0
1
0
1
2
↓
62
63
↓
(b) Start line set command for all the other modes except S1065 and S1575 (double byte command)
E
R/W
D7
A0
0
XRD
1
D6
D5
D4
D3
D2
D1
D0
Line address
XWR
0
0
1
0
S6
S5
0
0
0
0
0
S4 S3 S2 S1 S0
75
0
1
2
↓
94
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Dot Matrix Type LCD Controller
Page Address Set
This command specifies the page address corresponding to the low address when the MPU accesses the display
data RAM (see Figure 10). Specifying the page address and column address enables to access a desired bit of the
display data RAM. Changing the page address does not accompany a change in the status display.
E
R/W
A0
XRD
XWR
0
1
0
D7
D6
D5
D4
D3
D2
D1
D0
1
0
1
1
0
0
0
0
0
0
0
0
1
0
1
0
1
0
1
0
1
0
1
1
1
0
1
1
↓
↓
Page address
For S1065
S1575
Page address For Other modes
0
1
2
↓
0
1
2
↓
10
11
7
8
↓
15
Column Address Set
This command specifies the column address of the display data RAM shown in Figure 4. The column address is
split into two sections (the higher 4 bits and the lower 4 bits) when it is set (fundamentally, set continuously). Each
time the display data RAM is accessed, the column address automatically increments (+1), making it possible for
the MPU to continuously read /write to the display data. The column address increment is topped at 83H(S1065),
A7H(S1575) and BFH(all the other modes except S1065 and S1575). This does not change the page address
continuously. See the function explanation in “The Column Address Circuit,” for details.
E
R/W
D7 D6 D5 D4 D3 D2 D1 D0 A7 A6 A5 A4 A3 A2 A1 A0
A0
XRD XWR
High bits →
Low bits →
0
0
1
0
0
1 A7 A6
0 A3 A2
0
A5 A4
A1 A0
0
0
0
0
0
0
0
0
0
0
0
0
1
1
0
0
0
0
0
0
1
1
0
0
1
1
0
0
↓
↓
0
0
0
0
0
0
0
0
1
0
1
0
0
0
0
0
1
1
0
1
0
0
1
1
1
1
0
1
166
167(S1575)
0
1
190
191(other
modes)
76
0
0
1
1
1
1
0
1
2
↓
130
131(S1065)
↓
↓
↓
1
1
Column
address
1
1
1
1
1
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Rev1.4-13 Sep 2010
RW1092
Dot Matrix Type LCD Controller
Status Read
E
R/W
A0
XRD
0
0
1
D6
BUSY
ADC
D5
D4
D3 D2 D1 D0
ON/OFF RESET
0
0
0
0
BUSY=1:it indicates that either processing is occurring internally or a reset condition is in
process
BUSY=0:A new command can be accepted. If the cycle time can be satisfied , there us no need
to check for BUSY condition.
This shows the relationship between the column address and the segment driver .
0:Normal (column address n ↔ SEG n)
1:Reverse (column address 131-n ↔ SEG n)
(The ADC command switches the polarity)
ON/OFF: indicates the display ON/OFF state.
0:Display ON
1:Display OFF
(This display ON/OFF command switches the polarity)
This indicates that the chip is in the process of initialization either because of a RSTP signal or
because of a reset command.
0:Operating state
1:Reset in progress
BUSY
ADC
ON/OFF
RESET
D7
XWR
Display Data Write
This command writes 8-bit data to the specified display data RAM address. Since the column address is
automatically incremented by “1” after the write, the MPU can write the display data.
E
R/W
D7 D6 D5 D4 D3 D2 D1 D0
A0
1
XRD
1
XWR
0
Write data
Display Data Read
This command reads 8-bit data from the specified display data RAM address. Since the column address is
automatically incremented by “1” after the read, the CPU can continuously read multiple-word data. One dummy
read is required immediately after the column address has been set. See the function explanation in “Display Data
RAM” for the explanation of accessing the internal registers. When the serial interface is used, reading of the
display data becomes unavailable.
E
R/W
D7 D6 D5 D4 D3 D2 D1 D0
A0
1
XRD XWR
0
1
Read data
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Dot Matrix Type LCD Controller
ADC Select (Segment Driver Direction Select)
This command can reverse the correspondence between the display RAM data column address and the segment
driver output. Thus, sequence of the segment driver output pins may be reversed by the command. See the column
address circuit for the detail. Increment of the column address (by “1”) accompanying the reading or writing the
display data is done according to the column address indicated in Figure 4.
A0
0
E
R/W
XRD
1
XWR
0
D7
D6
D5
D4
D3
D2
D1
D0
Setting
1
0
1
0
0
0
0
0
1
Normal
Reverse
Display Normal / Reverse
This command can reverse the lit and unlit display without overwriting the contents of the display data RAM. When
this is done the display data RAM contents are maintained.
A0
0
E
R/W
XRD
1
XWR
0
D7
D6
D5
D4
D3
D2
D1
D0
Setting
1
0
1
0
0
1
1
0
RAM Data “H”
LCD ON voltage (normal)
RAM Data “L”
LCD ON voltage (reverse)
1
Display All Point ON / OFF
This command makes it possible to force all display points ON regardless of the content of the display data RAM.
The contents of the display data RAM are maintained when this is done. This command takes priority over the
display normal/reverse command.
A0
0
E
R/W
XRD
1
XWR
0
D7
D6
D5
D4
D3
D2
D1
D0
Setting
1
0
1
0
0
1
0
0
1
Normal display mode
Display all points ON
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Dot Matrix Type LCD Controller
LCD Bias Set
This command selects the voltage bias ratio required for the liquid crystal display.
E
R/W
Select Status(BE=0)
D7
A0
XRD
XWR
1
0
D6
1
0
0
D5
D4
1
D3
0
D2
0
0
D1
D0
1
1/97duty
1/65duty 1/33duty
1/17,
1/9duty
1/5duty
static
0
1/10 bias
1/9 bias
1/6 bias
1/5 bias
1/3 bias
-
1
1/8 bias
1/7 bias
1/4 bias
1/4 bias
1/2 bias
1/2 bias
Furthermore,RW1092 provides more flexible LCD bias ratio by BE register which is set by a double byte command.
E
R/W
Select Status(BE=1)
D7
A0
XRD
XWR
1
0
1
0
D6
0
D5
1
D4
D3
0
0
D2
0
D1
1
D0
1/97duty
1/65duty
1/33duty
1/17,
1/9duty
1/5duty
0
1/9 bias
1/8 bias
1/5 bias
1/3 bias
-
1
1/7 bias
1/6 bias
1/3 bias
1/2 bias
-
BE register set (double byte command)
E
R/W
XRD
1
1
XWR
0
0
D7 D6 D5 D4 D3 D2 D1 D0
st
1
nd
2
Byte →
Byte →
A0
0
0
1
1
1 1
1 0
0 1
1
0 ExtR BE DFR3 ~ DFR0
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Dot Matrix Type LCD Controller
Read/ Modify/Write
This command is used paired with the “END” command. Once this command has been input, the display data read
command does not change the column address, but only the display data write command increments (+1) the
column address. This mode is maintained until the END command is input. When the END command is input, the
column address returns to the address it was at when the read/modify/write command was entered. This function
makes it possible to reduce the load on the MPU when there are repeating data changes in a specified display
region, such as when there is a blanking cursor.
E
R/W
D7 D6 D5 D4 D3 D2 D1 D0
A0
0
XRD
1
XWR
0
1
1
1
0
0
0
0
0
* Even in read/modify/write mode, other commands aside from display data read/write commands can also be used.
Page address set
Column address set
Read-modify-write cycle
Dummy read
Data read
Data write
NO
Changes
Finished ?
YES
END
Figure 19 Command Sequence For read modify write
Return
Column address
N
N+1
N+2
N+3
Read-modify-write mode set
N+m
N
End
Figure 20
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Dot Matrix Type LCD Controller
End
This command releases the read/modify/write mode, and returns the column address to the address it was at when
the mode was entered.
E
R/W
D7 D6 D5 D4 D3 D2 D1 D0
A0
0
XRD
1
XWR
0
1
1
1
0
1
1
1
0
Reset
This command initializes the display start line, the column address, the page address, the common output mode,
the V0 voltage regulator internal resistor ratio, the electronic volume, and the static indicator are reset, and the
read/modify/write mode and test mode are released. There is no impact on the display data RAM. See the function
explanation in “Reset” for details.
The reset operation is performed after the reset command is entered.
E
R/W
D7 D6 D5 D4 D3 D2 D1 D0
A0
0
XRD XWR
1
0
1
1
1
0
0
0
1
0
Common Output Mode Select(SHL)
This command can select the scan direction of the COM output terminal. For details, see the function explanation in
“Common Output Mode Select Circuit.”
E
A0
0
R/W
XRD XWR
1
0
D7 D6 D5 D4 D3 D2 D1 D0 Selected
Mode
1
1
0
0
0
1
*
*
*
Normal
Reverse
* Disabled bit
Status
Mode Select
Normal
Reverse
COM Scan Direction
SEL3,2,1=1,1,0
SEL3,2,1=1,1,1 SEL3,2,1=1,0,1 SEL3,2,1=0,1,1
SEL3,2,1=0,1,0 SEL3,2,1=0,0,1 SEL3,2,1=0,0,0
SEL3,2,1=1,0,0
COM0 → COM95 COM0 → COM63 COM0 → COM31 COM0 → COM15 COM0→ COM7 COM0→COM3
COM95 → COM0 COM63 → COM0 COM31 → COM0 COM15 → COM0 COM7→ COM0 COM3→ COM0
*Please refer to Page 3 ~ Page38 for the details
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Dot Matrix Type LCD Controller
Power Controller Set
This command sets the power supply circuit functions. See the function explanation in “The Power Supply Circuit,”
for details
E
R/W
Selected Mode
D7 D6 D5 D4 D3 D2 D1 D0
A0
XRD XWR
0
0
1
0
1
0
1
0
1
Booster circuit: OFF
Booster circuit: ON
Voltage regulator circuit: OFF
Voltage regulator circuit: ON
Voltage follower circuit: OFF
Voltage follower circuit: ON
0
1
0
0
1
V0 Voltage Regulator Internal Resistor Ratio Set
This command sets the V0 voltage regulator internal resistor ratio. For details, see the function explanation is “The
Voltage Regulator circuit " and table 11 .
E
R/W
Rb/Ra Ratio
D7 D6 D5 D4 D3 D2 D1 D0
A0
XRD XWR
0
0
1
0
0
1
0
0
0
0
0
1
1
0
0
1
↓
1
1
0
1
0
Small
↓
1
1
Large
The Electronic Volume (Double Byte Command)
This command makes it possible to adjust the brightness of the liquid crystal display by controlling the LCD drive
voltage V0 through the output from the voltage regulator circuits of the internal liquid crystal power supply. This
command is a two byte command used as a pair with the electronic volume mode set command and the electronic
volume register set command, and both commands must be issued one after the other.
The Electronic Volume Mode Set
When this command is input, the electronic volume register set command becomes enabled. Once the electronic
volume mode has been set, no other command except for the electronic volume register command can be used.
Once the electronic volume register set command has been used to set data into the register, then the electronic
volume mode is released.
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Dot Matrix Type LCD Controller
Electronic Volume Register Set
By using this command to set six bits of data to the electronic volume register, the liquid crystal drive voltage V0
assumes one of the 64 voltage levels.
When this command is input, the electronic volume mode is released after the electronic volume register has been
set.
E
R/W
(First Byte)
D7 D6 D5 D4 D3 D2 D1 D0
A0
0
XRD XWR
1
0
E
R/W
1
0
0
0
0
0
0
1
(Second Byte)
D7 D6 D5 D4 D3 D2 D1 D0
A0
0
| V0 |
XRD XWR
1
0
*
*
*
*
*
*
0
0
0
0
0
0
0
0
0
*
*
*
*
1
1
1
1
1
1
0
0
0
0
1
1
1
0
1
1
1
1
1
0
1
↓
Small
↓
Large
* Inactive bit (set “0”)
When the electronic volume function is not used, set this to (1, 0, 0, 0, 0, 0)
The Electronic Volume Register Set Sequence
Figure 21
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Dot Matrix Type LCD Controller
Static Indicator ON/OFF
When the power saver mode indicator ON command is entered, the power saver indicator register set command is
enabled. Once the power saver indicator ON command has been entered, no other command aside from the power
saver indicator register set command can be used. This mode is cleared when data is set in the register by the
power saver indicator register set command.
E
R/W
D7 D6 D5 D4 D3 D2 D1 D0
A0
0
Static Indicator
XRD XWR
1
1
0
0
1
0
1
1
0
0
1
OFF
ON
Static Indicator register set
This command sets one bit of data into the static indicator register, and is used to set static display enable.
E
R/W
D7 D6 D5 D4 D3 D2 D1 D0
A0
0
Static Display
XRD XWR
1
0
*
*
*
*
*
*
*
0
1
disable
enable
* Disabled bit (set “0”)
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RW1092
Dot Matrix Type LCD Controller
Power Save(valid for all modes except S1575,Compound Command)
When the display all points ON is performed while the display is in the OFF mode, the power saver mode is entered, thus
greatly reducing power consumption.
The power saver mode has two different modes: the sleep mode and the standby mode. When the static indicator is OFF, it is
the sleep mode that is entered. When the static indicator is ON, it is the standby mode that is entered.
In the sleep mode and in the standby mode, the display data is saved as is the operating mode that was in effect before the
power saver mode was initiated, and the MPU is still able to access the display data RAM.
Refer to figure 23 for power save off sequence.
Figure 23
Power Save for S1575 (SEL3,2,1=1,0,1) used only
E
R/W
D7 D6 D5 D4 D3 D2 D1 D0
A0
0
Static Indicator
XRD XWR
1
0
1
0
1
0
1
0
0
0
1
Stand-by state
Sleep state
Power Save Reset for S1575(SEL3,2,1=1,0,1) used only
E
R/W
D7 D6 D5 D4 D3 D2 D1 D0
A0
0
XRD XWR
1
0
1
1
1
0
0
0
0
1
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RW1092
Dot Matrix Type LCD Controller
Sleep Mode
This stops all operations in the LCD display system, and as long as there are no accesses from the MPU, the
consumption.
current is reduced to a value near the static current. The internal modes during sleep mode are as follows:
1. The oscillator circuit and the LCD power supply circuit are halted.
2. All liquid crystal drive circuits are halted, and the segment in common drive outputs output a VSS level.
Standby Mode
The duty LCD display system operations are halted and only the static drive system for the indicator continues to
operate, providing the minimum required consumption current for the static drive. The internal modes are in the
following states during standby mode.
1 The LCD power supply circuits are halted. The oscillator circuit continues to operate.
2 The duty drive system liquid crystal drive circuits are halted and the segment and common driver outputs output a
VSS level.
The static drive system does not operate.
When a reset command is performed while in standby mode, the system enters sleep mode.
* When an external power supply is used, it is recommended that the functions of the external power supply circuit
be stopped when the power saver mode is started. For example, when the various levels of liquid crystal drive
voltage are provided by external resistive voltage dividers, it is recommended that a circuit be added in order to cut
the electrical current flowing through the resistive voltage divider circuit when the power saver mode is in effect.
N-line Reversal Drive Register Set
This command sets the number of reversal lines of the liquid crystal drive in register. 2 to 16 lines can be set.
E
R/W
D7 D6 D5 D4 D3 D2 D1 D0
A0
0
No. of reversal line
XRD XWR
1
0
0
0
0
0
0
0
1
1
1
1
1
1
0
0
0
0
0
0
0
1
1
1
1
1
1
↓
0
0
0
0
1
1
1
0
1
1
1
1
1
0
1
-2
3
↓
15
16
N-line Reversal Drive Reset
This command resets the n-line reversal alternating current drive and returns to the normal 2-frame reversal
alternating current drive system. The value of the n-line reversal alternating current drive register is not changed.
E
R/W
D7 D6 D5 D4 D3 D2 D1 D0
A0
0
XRD XWR
1
0
1
1
1
0
0
1
0
0
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RW1092
Dot Matrix Type LCD Controller
Set Data Length for 3-SPI (double byte command)
In 3 lines SPI mode, set Data length command indicates the length of data which, are going to be received by RW1092. User
should set data length before display data sent. Each data length instruction maximum can set 192 bytes of data. The table
below shows how SPA bits set the data length
E
R/W
(First Byte)
D7 D6 D5 D4 D3 D2 D1 D0
A0
XRD XWR
0
1
0
0
E
R/W
1
1
1
0
0
0
0
(Second Byte)
Function
A0
XRD XWR SPA7 SPA6 SPA5 SPA4 SPA3 SPA2 SPA1 SPA0
0
0
0
1
0
0
0
0
0
0
0
0
0
0
0
0
1
↓
1
0
0
0
1
1
Followed by 1 data write
Followed by 2 data write
↓
1
1
1
1
Followed by 192 data write
Built-in Oscillator Circuit ON( valid for S1575 only)
This command starts the operation of the built-in CR oscillator circuit. This command is valid only in S1575 mode
and when CLS=”H”.
E
R/W
D7 D6 D5 D4 D3 D2 D1 D0
A0
0
XRD XWR
1
0
1
0
1
0
1
0
1
1
The built-in oscillator circuit will be turned on when the reset procedure is completed and CLS=”H’ for all the other
modes except S1575(SEL3,2,1=1,0,1).
NOP
Non-Operation Command
E
R/W
D7 D6 D5 D4 D3 D2 D1 D0
A0 XRD XWR
0
1
0
1
1
1
0
0
0
1
1
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RW1092
Dot Matrix Type LCD Controller
External Ra,Rb used command
BE register set (double byte command)
E
R/W
XRD
1
1
XWR
0
0
D7 D6 D5 D4 D3 D2 D1 D0
st
1
nd
2
Byte →
Byte →
A0
0
0
1 1
1
1
0
0
1
1
1 0 ExtR BE DF3 FR2 DFR1 DFR0
Initial value after reset : ExtR=1, BE=0, DFR3~DFR0=0000
ExtR=1: internal resistor Ra,Rb used, IRSP pin set to “H”
ExtR=0: external resistor Ra,Rb used, IRSP pin set to “L”
Frame frequency adjustment command
BE register set (double byte command)
E
R/W
XRD
1
1
XWR
0
0
D7 D6 D5 D4 D3 D2 D1 D0
st
1
nd
2
Byte →
Byte →
A0
0
0
1
1
1 1
1 0
0 1
1
0 ExtR BE DFR3 ~ DFR0
Initial value after reset : ExtR=1, BE=0, DFR3~DFR0=0000
DFR3 ~ DFR0 =0000
0001
0010
0011
0100
0101
.
.
.
1100
1101
1110
1111
slow
fast
TEST
This is a command for IC chip testing. Please do not use it. If the test command is used by accident, it can be
cleared by applying a “L” signal to the RSTP input by the reset command or by using an NOP.
E
R/W
D7 D6 D5 D4 D3 D2 D1 D0
A0
0
XRD XWR
1
0
1
1
1
1
*
*
*
*
* Inactive bit
Note: The RW1092 maintain their operating modes until something happens to change them. Consequently,
excessive external noise, etc., can change the internal modes of the RW1092 . Thus in the packaging and
system design it is necessary to suppress the noise or take measure to prevent the noise from influencing the
chip. Moreover, it is recommended that the operating modes be refreshed periodically to prevent the effects of
unanticipated noise.
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RW1092
Dot Matrix Type LCD Controller
Table 16: Table of RW1092 Commands
Command
A0 XRD XWR
(1) Display ON/OFF
(Note) *: disabled data
Command Code
Function
D7 D6 D5 D4 D3 D2 D1 D0
1 0 1 0 1 1 1 0 LCD display ON/OFF
1 0: OFF, 1: ON
0
1
0
0
1
0
0
1
0
1
0
0
0
Sets the display RAM display start
1 0 0 0 0 0 0 line address
Display start address
(3) Page address set
0
1
0
1
0
(4) Column address set upper bit
0
1
0
0
0
Column address set lower bit
0
1
0
0
0
(5) Status read
0
0
1
(6) Display data write
1
1
0
Write data
Writes to the display RAM
(7) Display data read
1
0
1
Read data
Reads from the display RAM
(8) ADC select
0
1
0
(9) Display normal/ reverse
0
1
0
(10) Display all points ON/OFF
0
1
0
(11) LCD bias set
0
1
0
(12) Read/modify/write
0
1
(13) End
0
(14) Reset
(2-1) Display start line set
(valid for S1065 and S1575 only)
(2-2) Display start line set
(valid for all the other modes
except S1065 and S1575, double
byte commands)
Display start address
Sets the display RAM page
address
0 1 Most significant Sets the most significant 4 bits of
column address the display RAM column address.
0 0 Least significant Sets the least significant 4 bits of
column address the display RAM column address.
1
1
Status
Page address
0
0
0
0 Reads the status data
Sets the display RAM address
0 ADC SEG output correspondence
ADC=0: normal, ADC=1: reverse
Sets the LCD display normal/
1 0
reverse
1
0: normal, 1: reverse
Display all points
0 0
0: normal display
1
1: all points ON
Sets the LCD drive voltage bias
1 0
ratio
1
0: 1/9 bias, 1: 1/7 bias (RW1092)
Column address increment
0 0 At write: +1
At read: 0
1
0
1
0
0
1
0
1
0
0
1
1
0
1
0
0
1
1
0
1
0
0
0
0
1
1
1
0
0
0
1
0
1
1
1
0
1
1
1
0 Clear read/modify/write
0
1
0
1
1
1
0
0
0
1
0 Internal reset
(15) Common output mode select
0
1
0
1
1
0
0
(16) Power control set
0
1
0
0
0
1
0
1
(17) V0 voltage regulator
internal resistor ratio set
0
1
0
0
0
1
0
0
89
SHL
0
Select COM output scan direction
SHL=0: normal direction
SHL=1: reverse direction
Operating Select internal power supply
mode
operating mode
Resistor Select internal resistor
ratio
ratio(Rb/Ra) mode
*
*
*
Rev1.4-13 Sep 2010
RW1092
Dot Matrix Type LCD Controller
Table 16 (continued) : Table of RW1092 Commands
Command
Command Code
A0 XRD XWR
(18) Electronic volume mode set
Electronic volume register
set
0
1
0
Function
D7 D6 D5 D4 D3 D2 D1 D0
1
0
0 0 0 0 0 0 1 Set the V0 output voltage
0 Electronic volume value electronic volume register
1
0
1
0
0
0
0
1
0
1
0
1
1
1
1
0
0
0
1
1
0
(19) Static indicator ON/OFF
Static display enable register
set
0
1
0
(21)Set stand by mode(valid for
all modes except S1575)
1
0 1: stand by indicator on
1 0: sleep indicator on
0
(20)Set sleep mode(valid for all
modes except S1575)
(22) Power save( valid for S1575) 0
(Note) *: disabled data
0
(23)Power save reset
(valid for S1575))
0 Mode Mode=1: static display enable
Mode=0: static display disable
Power saver indicator set for
sleep indicator on (2 bytes)
↓
Display off
↓
Display all point ON
Power saver indicator set for
stand by indicator on (2 bytes)
↓
Display off
↓
Display all point ON
0 0 0 Moves to the power save state
1 0: stand by 1: sleep
0
0
0
1
Resets power save
(24) N-line Reversal Drive
Register Set
0
1
0
0
0
1
1
Number of Sets the number of line
Reversal lines reversal drive lines.
(25) N-line Reversal Drive reset
0
1
0
1
1
1
0
0
1
0
0 Resets the line reversal drive
(26)Set Data Length for 3SPI
0
1
0
0
1
1
1
0
0
0
0 Set Data Length for 3-line
serial interface
Set Data Length for SPA bits
(27)Built in oscillator circuit on
(Valid for S1575 only)
0
1
0
1
1
1
(28) NOP
0
1
0
1
1
1
(29)External RA,RB used
and frame frequency adjustment
0
1
0
1
1
(29) Test
0
1
0
1
0 0
0
0
1
0
0
1
0 Start the built-in Oscillator
1 Command for non-operation
ExtR=1:internal resistor used
ExtR=0:external resistor used
1 1 1 0 0 1 1
BE: register set
0 ExtR BE DF3 ~ DF0
DF3~DF0:frame frequency
adjustment
Command for IC test. Do not
1 1 1
* * * *
use this command
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Dot Matrix Type LCD Controller
COMMAND DESCRIPTION
Instruction Setup : Reference
(1).Initialization:
Note: With this IC, when the power is applied, LCD driving non-selective potentials V2 and V3 (SEG pin) and V1
and V4 (COM pin) are output through the LCD driving output pins SEG and COM. When electric charge is
remaining in the smoothing capacitor connecting between the LCD driving voltage output pins (V0 ~ V4) and the
VSS pin, the picture on the display may become totally dark instantaneously when the power is turned on. To avoid
occurrence of such a failure, we recommend the
following flow when turning on the power.
1. When the built-in power is being used immediately after turning on the power:
Turn ON the power and keeping
the RSTP pin = “L”.
When the power is stabilized
Release the reset state. (RSTP pin = “H”)
Waiting reset circuit stabilized (<1ms)
Initialized state (Default) *1
Function setup by command input
(User setup)
(11) LCD bias setting *2
(8) ADC selection *3
(15) Common output state selection *4
Function setup by command input
(User setup)
(17) Setting the built-in resistance ratio
for regulation of the V0 voltage *5
(18) Electronic volume control *6
Arrange to execute all the
procedures from releasing the
reset state through setting the
power control within 5ms.
(In case of other models)
execute the procedures from
turning on the power to setting
the power control in 5ms.
Function setup by command input
(User setup)
(16) Power control setting *7
This concludes the initialization
* The target time of 5ms will result to vary depending on the panel characteristics and the capacitance of the
smoothing capacitor. Therefore, we suggest you to conduct an operation check using the actual equipment.
Notes: Refer to respective sections or paragraphs listed below.
*1: Description of functions; Resetting circuit.
*2: Command description; LCD bias setting.
*3: Command description; ADC selection.
*4: Command description; Common output state selection.
*5: Description of functions; Power circuit & Command description; Setting the built-in resistance ratio for regulation
of the V0 voltage.
*6: Description of functions; Power circuit & Command description; Electronic volume control.
*7: Description of functions; Power circuit & Command description; Power control setting.
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Dot Matrix Type LCD Controller
2. When the built-in power is not being used immediately after turning on the power:
Turn ON the VDD-VSS power keeping the
RSTP pin = “L”.
When the power is stabilized
Release the reset state. (RSTP pin = “H”)
Waiting reset circuit stabilized (<1ms)
Initialized state (Default) *1
Power saver START
(multiple commands) *8
Arrange to start the
p ower s a ver within
5ms after releasing the
reset state. (In case of
other models) execute
the procedures from
turning on the power
to setting the power
control in 5ms.
Function setup by command input (User
setup)
(11) LCD bias setting *2
(8) ADC selection *3
(15) Common output state selection *4
Function setup by command input (User
setup)
(17) Setting the built-in resistance ratio
for regulation of the V0 voltage *5
(18) Electronic volume control *6
Power saver OFF *8
Function setup by command input
(User setup)
(16) Power control setting *7
Arrange to start power
control setting within
5ms after turning OFF
the power saver.
This concludes the initialization
* The target time of 5ms will result to vary depending on the panel characteristics and the capacitance of the
smoothing capacitor. Therefore, we suggest you to conduct an operation check using the actual equipment.
Notes: Refer to respective sections or paragraphs listed below.
*1: Description of functions; Resetting circuit.
*2: Command description; LCD bias setting.
*3: Command description; ADC selection.
*4: Command description; Common output state selection.
*5: Description of functions; Power circuit & Command description; Setting the built-in resistance radio for
regulation of the V0 voltage.
*6: Description of functions; Power circuit & Command description; Electronic volume control.
*7: Description of functions; Power circuit & Command description; Power control setting.
*8: The power saver ON state can either be in sleep state or stand-by state.
Command description; Power saver START. (multiple commands)
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Dot Matrix Type LCD Controller
(2)Data Display
End of initialization
Function setup by command input
(User setup)
(2) Display start line set *9
(3) Page address set *10
(4) Column address set *11
Function setup by command input
(User setup)
(6) Display data write *12
Function setup by command input
(User setup)
(1) Display ON/OFF *13
End of data display
Notes: Reference items
*9: Command Description; Display start line set
*10: Command Description; Page address set
*11: Command Description; Column address set
*12: Command Description; Display data write
*13: Command Description; Display ON/OFF
Avoid displaying all the data at the data display start (when the display is ON) in white.
(3) Power OFF *14
Optional status
Function setup by command input
(User setup)
(19)or (22) Power save *15
wait >200ms
VDD – VSS power OFF
Notes: Reference items
*14: The logic circuit of this IC’s power supply VDD - VSS controls the driver of the LCD power supply VSS –
V0. So, if the power supply VDD - VSS is cut off when the LCD power supply VSS – V0 has still any
residual voltage, the driver (COM. SEG) may output any uncontrolled voltage. When turning off the
power, observe the following basic procedures:
• After turning off the internal power supply, make sure that the potential V0 ~ V4 has become below the
threshold voltage of the LCD panel, and then turn off this IC’s power supply (VDD - VSS).
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Dot Matrix Type LCD Controller
Refresh
It is recommended to turn on the refresh sequence regularly at a specified interval.
Refresh sequence
Reset command or NOP command
Set all commands to the ready state
Refreshing of DRAM
Precautions on Turning off the Power
<Turning the power (VDD - VSS) off>
1) Power Save (The LCD powers (V0 - VSS) are off.) → Reset input → Power (VDD - VSS) OFF
• Observe tL > tH.
• When tL < tH, an irregular display may occur.
Set tL on the MPU according to the software. tH is determined according to the external capacity C2 (smoothing
capacity of V0 ~ V4) and the driver’s discharging capacity.
<Turning the power (VDD - VSS) off : When command control is not possible.>
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Dot Matrix Type LCD Controller
2) Reset (The LCD powers (VDD - VSS) are off.) → Power (VDD - VSS) OFF
• Observe tL > tH.
• When tL < tH, an irregular display may occur.
For tL, make the power (VDD - VSS) falling characteristics longer or consider any other method. tH is
determined according to the external capacity C2 (smoothing capacity of V4 to V0) and the driver’s discharging
capacity.
<Reference Data>
V0 voltage falling (discharge) time (tH) after the process of operation → power save → reset.
V0 voltage falling (discharge) time (tH) after the process of operation → reset.
Figure 24
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Rev1.4-13 Sep 2010
RW1092
Dot Matrix Type LCD Controller
ABSOLUTE MAXIMUM RATINGS
Unless otherwise noted, VDD = 0V
Table 17
Parameter
Symbol
Conditions
Unit
Power Supply Voltage
VDD
0.3 ~ 5.0
V
Power supply voltage (VDD standard)
VDD2
0.3 ~ 4.0
V
Power supply voltage (VDD standard)
V0, VOUT
0.3 ~ 18.0
V
Power supply voltage (VDD standard)
V1, V2, V3, V4
V0 to 0.3
V
Operating temperature
TOPR
–40 to +85
°C
TSTR
–55 to +125
°C
Storage temperature
Bare chip
Figure 25
Notes and Cautions
1. The VDD2, V0 to V4 and VOUT are relative to the VSS = 0V reference.
2. Insure that the voltage levels of V1, V2, V3, and V4 are always such that VOUT ≧ V0 ≧ V1 ≧ V2 ≧ V3 ≧ V4.
3. Permanent damage to the LSI may result if the LSI is used outside of the absolute maximum ratings. Moreover,
it is recommended that in normal operation the chip be used at the electrical characteristic conditions, and use of
the LSI outside of these conditions may not only result in malfunctions of the LSI, but may have a negative impact
on the LSI reliability as well.
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Dot Matrix Type LCD Controller
DC CHARACTERISTICS
Unless otherwise specified, VSS = 0 V, VDD = 3.0 V ± 10%, Ta = –40 to 85°C
Min.
Rating
Typ.
Max.
VDD
1.8
—
VDD2 (Relative to VSS)
2.4
Item
Symbol
Operating Voltage (1)
Operating Voltage (2)
Condition
Units
Applicable
Pin
3.6
V
VSS*1
—
3.6
V
VSS
High-level Input Voltage
VIHC
0.8 x VDD
—
VDD
V
*3
Low-level Input Voltage
VILC
VSS
—
0.2 x VDD
V
*3
0.8 x VDD
—
VDD
V
*4
VSS
—
0.2 x VDD
V
*4
High-level Output Voltage
VOHC IOH = –0.5 mA
Low-level Output Voltage
VOLC IOL = 0.5 mA
Input leakage current
ILI
VIN = VDD or VSS
–1.0
—
1.0
μA
*5
Output leakage current
ILO
VIN = VDD or VSS
–3.0
—
3.0
μA
*6
—
2.0
3.5
KΩ
SEGn
COMn *7
Ta
= V0 = 13.0 V
25°C
RON
(Relative V0 = 8.0 V
To VDD)
Liquid Crystal Driver ON
Resistance
Static Consumption Current ISSQ
Output Leakage Current
I5Q
Input Terminal Capacitance
CIN
Oscillator
Frequency
Internal
Oscillator
External
Input
fOSC
fCL
V0 = 13.0 V(Relative
To VDD)
Ta = 25°C , f = 1 MHz
1/65 duty
Ta = 25°C
1/33 duty
—
3.2
5.4
—
0.01
2
μA
VDD,
VDD2
—
0.01
10
μA
V0
—
5.0
8.0
pF
105.5
124.1
148.9
kHz
*8
105.5
124.1
148.9
kHz
CL
Table 19
Internal Power
Item
Input voltage
Supply Step-up
output voltage
Circuit
Voltage regulator
Circuit Operating
Voltage
Voltage Follower
Circuit Operating
Voltage
Base Voltage
Symbol
VDD2
Condition
Min.
2.4
(Relative To VSS)
Rating
Typ.
—
Max.
3.6
Units
Applicable
Pin
V
VSS
VOUT (Relative To VSS)
—
—
16.0
V
VOUT
VOUT (Relative To VSS)
6.0
—
18.0
V
VOUT
4.0
—
14.0
V
V0 * 9
2.07
2.10
2.13
V
*10
V0
(Relative To VSS)
VR
Ta = 25°C , (Relative To
VSS)
–0.05%/°C
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Rev1.4-13 Sep 2010
RW1092
Dot Matrix Type LCD Controller
Dynamic Consumption Current : During Display, with the Internal Power Supply OFF Current
consumed by total ICs when an external power supply is used .
Rating
Units Notes
Test pattern
Symbol
Condition
Typ.
Max.
Min.
Display Pattern
OFF
IDD
VDD = 3.0 V,
V0 – VSS = 11.0 V
—
11
19
μA
*11
Display Pattern
Checker
IDD
VDD = 3.0 V,
V0 – VSS = 11.0 V
—
15
26
μA
*11
Dynamic Consumption Current : During Display, with the Internal Power Supply ON
Rating
Test pattern Symbol
Condition
Min.
Typ.
Max.
Units Notes
Display
Pattern OFF
IDD
VDD = 3.0 V,
Quad step-up 4x voltage.
V0 – VSS = 11.0 V
—
200
260
μA
*12
Display
Pattern
Checker
IDD
VDD = 3.0 V,
Quad step-up 4x voltage.
V0 – VSS = 11.0 V
—
220
280
μA
*12
Consumption Current Time of Power Saver Mode : VSS= -3.0 ± 10%
Table 22
Item
Symbol
Condition
Sleep mode
Standby Mode
IDD
IDD
Ta = 25°C
Ta = 25°C
Min.
—
—
98
Rating
Typ.
0.1
4.4
Max.
4
10
Units
Notes
μA
Rev1.4-13 Sep 2010
RW1092
Dot Matrix Type LCD Controller
The Relationship Between Oscillator Frequency fOSC, Display Clock Frequency fCL
and the Liquid Crystal Frame Rate Frequency fFR
Table 23
Item
fCL
fFR
Used internal oscillator circuit
fOSC / 16
fOSC / (16*98)
Used external display clock
fOSC / 16
fOSC / (16*98)
Used internal oscillator circuit
fOSC / 24
fOSC / (24*66)
Used external display clock
fOSC / 24
fOSC / (24*66)
Used internal oscillator circuit
fOSC / 48
fOSC / (48*34)
Used external display clock
fOSC / 48
fOSC / (48*34)
Used internal oscillator circuit
fOSC / 88
fOSC / (88*18)
Used external display clock
fOSC / 88
fOSC / (88*18)
Used internal oscillator circuit
fOSC / 176
fOSC / (176*9)
Used external display clock
fOSC / 176
fOSC / (176*9)
Used internal oscillator circuit
fOSC / 320
fOSC / (320*5)
Used external display clock
fOSC / 320
fOSC / (320*5)
1/97 DUTY
1/65 DUTY
1/33 DUTY
1/17 DUTY
1/9 DUTY
1/5 DUTY
(fFR is the liquid crystal alternating current period, and not the FR signal period.)
References for items market with *
*1 While a broad range of operating voltages is guaranteed, performance cannot be guaranteed if there are sudden
fluctuations to the voltage while the MPU is being accessed.
*2 The operating voltage range for the VSS system and the V0 system is. This applies when the external power
supply is being used.
*3 The A0, D0 to D5, D6, D7, XRD (E), XWR (RW), CS1B, CS2, CLS, STACOM, C86, PSB, RSTP, and IRS
terminals.
*4 The D0 to D7and STACOM terminals.
*5 The A0, XRD (E), XWR (RW), CS1B, CS2, CLS, C86, PSB, RSTP, and IRS terminals.
*6 Applies when the D0 to D5, D6 ,D7, STACOM, and FR terminals are in a high impedance state.
*7 These are the resistance values for when a 0.1 V voltage is applied between the output terminal SEGn or COMn
and the various power supply terminals (V1, V2, V3, and V4). These are specified for the operating voltage (3)
range.
RON = 0.1 V /ΔI (Where ΔI is the current that flows when 0.1 V is applied while the power supply is ON.)
*8 See Table 23 for the relationship between the oscillator frequency and the frame rate frequency.
*9 The V0 voltage regulator circuit regulates within the operating voltage range of the voltage follower.
*10 This is the internal voltage reference supply for the V0 voltage regulator circuit. In the RW1092 , the
temperature range approximately –0.05%/°C.
*11, 12 It indicates the current consumed on ICs alone when the internal oscillator circuit and display are turned on.
The RW1092 is 1/9 biased. Does not include the current due to the LCD panel capacity and wiring capacity.
Applicable only when there is no access from the MPU.
*12 It is the value on a RW1092 having the VREG temperature gradient is –0.05%/°C when the V0 voltage regulator
internal resistor is used.
99
Rev1.4-13 Sep 2010
RW1092
Dot Matrix Type LCD Controller
TIMING CHARACTERISTICS
System Bus Read / Write Characteristics 1 (For the 8080 Series MPU)
Figure 26
Table 24
Item
Signal
Address hold time
Address setup time
Enable H pulse width (WRITE)
Enable L pulse width (READ)
Enable H pulse width (READ)
A0
WR
RD
WRITE Data setup time
WRITE Address hold time
READ access time
READ Output disable time
Condition
tAH8
System cycle time
Enable L pulse width (WRITE)
Symbol
D0 to D7
(VDD = 3.3V , Ta =25°C)
Rating
Units
Min.
Max.
0
—
tAW8
0
—
tCYC8
240
—
tCCLW
80
—
tCCHW
80
—
tCCLR
140
—
tCCHR
80
tDS8
40
—
tDH8
0
—
tACC8
CL = 100 pF
—
70
tOH8
CL = 100 pF
5
50
100
Ns
Rev1.4-13 Sep 2010
RW1092
Dot Matrix Type LCD Controller
Table 25
Item
Signal
Address hold time
Address setup time
Enable H pulse width (WRITE)
Enable L pulse width (READ)
Enable H pulse width (READ)
A0
WR
RD
WRITE Data setup time
WRITE Address hold time
READ access time
Condition
tAH8
System cycle time
Enable L pulse width (WRITE)
Symbol
D0 to D7
READ Output disable time
(VDD = 2.7 V , Ta = 25°C )
Rating
Units
Min.
Max.
0
—
tAW8
0
—
tCYC8
400
—
tCCLW
220
—
tCCHW
180
—
tCCLR
220
—
tCCHR
180
—
tDS8
40
—
tDH8
0
—
tACC8
CL = 100 pF
—
140
tOH8
CL = 100 pF
10
100
ns
Table 26
Item
Signal
Address hold time
Address setup time
Enable H pulse width (WRITE)
Enable L pulse width (READ)
Enable H pulse width (READ)
A0
WR
RD
WRITE Data setup time
WRITE Address hold time
READ access time
READ Output disable time
Condition
tAH8
System cycle time
Enable L pulse width (WRITE)
Symbol
D0 to D7
(VDD = 1.8V , Ta = 25°C )
Rating
Units
Min.
Max.
0
—
tAW8
0
—
tCYC8
640
—
tCCLW
360
—
tCCHW
280
—
tCCLR
360
—
tCCHR
280
tDS8
80
—
tDH8
0
—
tACC8
CL = 100 pF
—
240
tOH8
CL = 100 pF
10
200
ns
*1 The input signal rise time and fall time (tr, tf) is specified at 15 ns or less. When the system cycle time is
extremely fast, (tr +tf) ≦ (tCYC8 – tCCLW – tCCHW) for (tr + tf) ≦ (tCYC8 – tCCLR – tCCHR) are specified.
*2 All timing is specified using 20% and 80% of VDD as the reference.
*3 tCCLW and tCCLR are specified as the overlap between CS1B being “L” (CS2 = “H”) and XWR and XRD being
at the “L” level.
101
Rev1.4-13 Sep 2010
RW1092
Dot Matrix Type LCD Controller
System Bus Read / Write Characteristics 2 (For the 6800 Series MPU)
Figure 27
Table 27
Item
Signal
Address hold time
Address setup time
Enable H pulse width (WRITE)
Enable L pulse width (READ)
Enable H pulse width (READ)
A0
WR
RD
WRITE Data setup time
WRITE Address hold time
READ access time
READ Output disable time
Condition
tAH6
System cycle time
Enable L pulse width (WRITE)
Symbol
D0 to D7
(VDD = 3.3 V , Ta = 25°C )
Rating
Units
Min.
Max.
0
—
tAW6
0
—
tCYC6
240
—
tEWLW
80
—
tEWHW
80
—
tEWLR
80
—
tEWHR
140
tDS6
40
—
tDH6
0
—
tACC6
CL = 100 pF
—
70
tOH6
CL = 100 pF
5
50
102
ns
Rev1.4-13 Sep 2010
RW1092
Dot Matrix Type LCD Controller
Table 28
Item
Signal
Address hold time
Address setup time
Enable H pulse width (WRITE)
Enable L pulse width (READ)
Enable H pulse width (READ)
A0
WR
RD
WRITE Data setup time
WRITE Address hold time
READ access time
Condition
tAH6
System cycle time
Enable L pulse width (WRITE)
Symbol
D0 to D7
READ Output disable time
(VDD = 2.7V , Ta =25°C )
Rating
Units
Min.
Max.
0
—
tAW6
0
—
tCYC6
400
—
tEWLW
220
—
tEWHW
180
—
tEWLR
220
—
tEWHR
180
—
tDS6
40
—
tDH6
0
—
tACC6
CL = 100 pF
—
140
tOH6
CL = 100 pF
10
100
ns
Table 29
Item
Signal
Address hold time
Address setup time
Enable H pulse width (WRITE)
Enable L pulse width (READ)
Enable H pulse width (READ)
A0
WR
RD
WRITE Data setup time
WRITE Address hold time
READ access time
READ Output disable time
Condition
tAH6
System cycle time
Enable L pulse width (WRITE)
Symbol
D0 to D7
(VDD =1.8V , Ta =25°C )
Rating
Units
Min.
Max.
0
—
tAW6
0
—
tCYC6
640
—
tEWLW
360
—
tEWHW
280
—
tEWLR
360
—
tEWHR
280
—
tDS6
80
—
tDH6
0
—
tACC6
CL = 100 pF
—
240
tOH6
CL = 100 pF
10
200
ns
*1 The input signal rise time and fall time (tr, tf) is specified at 15 ns or less. When the system cycle time is
extremely fast, (tr +tf) ≦ (tCYC6 – tEWLW – tEWHW) for (tr + tf) ≦ (tCYC6 – tEWLR – tEWHR) are specified.
*2 All timing is specified using 20% and 80% of VDD as the reference.
*3 tEWLW and tEWLR are specified as the overlap between CS1B being “L” (CS2 = “H”) and E.
103
Rev1.4-13 Sep 2010
RW1092
Dot Matrix Type LCD Controller
The Serial Interface
tCCSS
tCSH
CS1
(CS2="1")
tSAS
tSAH
A0
tSCYC
tSLW
SCL
tSHW
tf
tr
tSDS
tSDH
SI
Figure 28
Table 30
Item
Serial Clock Period
SCL “H” pulse width
SCL “L” pulse width
Address setup time
Address hold time
Data setup time
Data hold time
CS-SCL time
CS-SCL time
Signal
SCL
A0
SI
CS
Symbol
Tscyc
Tshw
TSLW
TSAS
Tsah
Tsds
TSDH
Tcss
Tcsh
104
Condition
(VDD = 3.3V, Ta =25°C )
Rating
Units
Min.
Max.
50
—
25
—
25
—
20
—
ns
10
—
20
—
10
—
20
—
40
—
Rev1.4-13 Sep 2010
RW1092
Dot Matrix Type LCD Controller
Table 31
Item
Serial Clock Period
SCL “H” pulse width
SCL “L” pulse width
Address setup time
Address hold time
Data setup time
Data hold time
CS-SCL time
CS-SCL time
Signal
SCL
A0
SI
CS
Symbol
Condition
Tscyc
TSHW
TSLW
TSAS
TSAH
TSDS
TSDH
TCSS
TCSH
(VDD =2.7V , Ta =25°C )
Rating
Units
Min.
Max.
100
—
50
—
50
—
30
—
ns
20
—
30
20
30
60
—
—
—
—
Table32
Item
Serial Clock Period
SCL “H” pulse width
SCL “L” pulse width
Address setup time
Address hold time
Data setup time
Data hold time
CS-SCL time
CS-SCL time
Signal
SCL
A0
SI
CS
Symbol
Condition
TSCYC
TSHW
TSLW
TSAS
TSAH
TSDS
TSDH
TCSS
TCSH
(VDD = 1.8V , Ta = 25°C )
Rating
Units
Min.
Max.
200
—
80
—
80
—
60
—
ns
30
—
60
30
40
100
—
—
—
—
*1 The input signal rise and fall time (tr, tf) are specified at 15 ns or less.
*2 All timing is specified using 20% and 80% of VDD as the standard.
105
Rev1.4-13 Sep 2010
RW1092
Dot Matrix Type LCD Controller
IIC interface
SDA
tBUF
tHIGH
tLOW
SCL
tDH;STA
tSU;DAT
tf
tr
tHD;DAT
SDA
tSU;STA
Item
SCL clock frequency
SCL clock low period
Signal Symbol Condition
fSCLK
SCL
SCL clock high period
Data set-up time
Data hold time
SCL,SDA rise time
SCL,SDA fall time
Capacitive load represent by each bus
line
Setup time for a repeated START
condition
Start condition hold time
—
tHIGH
SI
SCL,
SDA
SI
Setup time for STOP condition
Bus free time between a Stop and
START condition
tLOW
SCL
tSU;DAT
tHD:DAT
tr
—
—
tf
tSU;STO
VDD=1.8 to 2.7V
Rating
( Ta = 25°C )
VDD=2.7 to 3.6V
Rating
Units
Min.
Max.
Min.
Max.
DC
DC
1.3
0.6
400
—
—
KHz
0.6
400
—
—
180
—
80
—
ns
0
0.9
0
0.9
us
20+0.1Cb
300
20+0.1Cb
300
20+0.1Cb
300
20+0.1Cb
300
1.3
us
ns
Cb
—
—
400
—
400
pf
tSU;STA
—
0.6
—
0.6
—
us
tHD;STA
—
0.6
—
0.6
—
us
tSU;STO
—
0.6
—
0.6
—
us
tBUF
—
1.3
—
1.3
—
us
106
Rev1.4-13 Sep 2010
RW1092
Dot Matrix Type LCD Controller
RESET TIMING
Figure 29
Table 36
Item
Reset time
Reset “L” pulse width
Signal Symbol
Condition
tR
RSTP tRW
(VDD = 3.3V , Ta = –40 to 85°C )
Rating
Units
Min.
Typ.
Max.
—
—
1.0
us
1.0
—
—
us
Table 37
Item
Reset time
Reset “L” pulse width
Signal Symbol
Condition
tR
RSTP tRW
(VDD = 2.7V , Ta = –40 to 85°C )
Rating
Units
Min.
Typ.
Max.
—
—
2.0
us
2.0
—
—
us
Table 38
Item
Reset time
Reset “L” pulse width
Signal Symbol
Condition
tR
RSTP tRW
(VDD = 1.8V , Ta = –40 to 85°C )
Rating
Units
Min.
Typ.
Max.
—
—
3.0
us
3.0
—
—
us
*1 All timing is specified with 20% and 80% of VDD as the standard.
107
Rev1.4-13 Sep 2010
RW1092
Dot Matrix Type LCD Controller
★Application Notes for Static Display:
RW1092 can support Static display with different gray level thru STACOM pad and SEG0~191
pads.
When static display has been selected, please set up the relative registers as follow:
1.
2.
3.
4.
5.
6.
7.
static indicator set to “ON” and static indicator register set to “1” ( instruction code : ADH + 01H)
LCD bias set to 1/2 bias ( instruction code : A3H)
Switch off all LCD power including booster, regulator, follower.(instruction code : 28H)
duty set to 1/5 duty ( Pin select : SEL1=”L”, SEL2=”L”, SEL3=”L”)
CLS set to VDD ( internal oscillator used )
Connect V0 to VDD
keep all COMMON pads opened
Gray scale output static display
RW1092 has a special design for the static output, that can make user to get a different gray level output display.
Figure. A-1 and Table A-1 shows a example for the gray scale output display waveform for static display
Page
Address Data
Column
S
0
S
1
S
2
S
3
S
4
Address
S
5
S191
DB0
0,0,0,0
DB1
DB2
DB3
1,1,1,1
DB0
Table A-1 RAM map for static display
Tfr
STACOM
S
0
S
1
S
2
S
3
S
4
S
5
STACOM
VDD
VSS
VDD
SEG 0
VSS
VDD
SEG 1
VSS
VDD
SEG 2
VSS
VDD
SEG 3
VSS
VDD
SEG 4
VSS
VDD
SEG 5
VSS
Figure A-1 static display waveform for different gray level LCD output
108
Rev1.4-13 Sep 2010
RW1092
Dot Matrix Type LCD Controller
The following shows Example waveform for Static Display for RW1092.
Column Address
1,0,1,1
1111
Data
Page
addr
ess
0,0,0,0
0 1
2
3
4
5
6
185186187188189190 191
Display
RAM
Scan
Address
D0
00H
D1
01H
D2
02H
D3
03H
D4
04H
D5
05H
D6
06H
D7
07H
D0
52H
D1
53H
D2
54H
D3
55H
D4
56H
D5
57H
D6
58H
D7
59H
D0
60H
109
ICON
Rev1.4-13 Sep 2010
RW1092
Dot Matrix Type LCD Controller
FR
VDD
STACOM
VSS
Display
RAM Scan
Address
60H
00H
01H
02H
03H
60H
00H
01H
02H
03H
60H
00H
V0
Seg0 Output
VSS
V0
Seg1 Output
VSS
V0
Seg2 Output
VSS
V0
Seg3 Output
VSS
V0
Seg4 Output
VSS
V0
Seg5 Output
VSS
V0
Seg6 Output
VSS
Fig 22 Static Display Output Waveform
110
Rev1.4-13 Sep 2010
RW1092
Dot Matrix Type LCD Controller
THE MPU INTERFACE (REFERENCE EXAMPLES)
The RW1092 Series can be connected to either 80X86 Series MPUs or to 6800 Series MPUs. Moreover, using the serial
interface it is possible to operate the RW1092 series chips with fewer signal lines.
The display area can be enlarged by using multiple RW1092 Series chips. When this is done, the chip select signal
can be used to select the individual ICs to access.
(1) 6800 Series MPUs (PSB=”H”,C86=”H”)
Figure 30-1
(2) 8080 Series MPUs (PSB=”H”,C86=”L”)
Figure 30-2
111
Rev1.4-13 Sep 2010
RW1092
Dot Matrix Type LCD Controller
(3) Using the Serial Interface(4-line) (PSB=”L”,C86=”H”)
D0~D5: connect to VDD
E、CS2、RW: connect to VDD
Figure 30-3
(4) Using the Serial Interface(3-line) (PSB=”L”,C86=”H”)
D0~D5: connect to VDD
E、CS2、RW: connect to VDD
RS: connect to VSS
Figure 30-4
112
Rev1.4-13 Sep 2010
RW1092
Dot Matrix Type LCD Controller
(5) Using the Serial Interface(IIC) (PSB=”L”,C86=”L”)
D2~D5: connect to D6
E、CS1、CS2、RW: connect
to VDD
RS: connect to VSS
Figure 30-5
113
Rev1.4-13 Sep 2010
1
2
Interface Selection
D
PSB
C86
0
0
1
1
0
1
0
1
4
6
5
Interface databus pin setting
Interface
IIC
3/4 SPI
Interface CS1B CS2 A0 E(XRD) RW(XWR)
8080 series
Now Setting
6800 series
3
VDD
SCLK
VDD
VDD
SDA
SDA
SCLK
C6
C7
C8
CAP
CAP
CAP
D
VDD
CS1B
VDD
VSS
VDD
VDD
SDA
CS1B
VDD
A0
XRD
XWR
D7
SCLK
D6
D5~D0
VDD
CS1B
VDD
A1
E
RW
D7
D6
D5~D0
C0
CAP
C1
CAP
C2
CAP
C3
CAP
R1
IRS="H" use the internal resistors
V1
C4
CAP
R2
RES1
V0
C5
CAP
RES1
V2
V3
V4
Now Setting: 4X
Cap: 2.2uF~4.7uF
Cap: 2.2uF~4.7uF
Bias ratio default :1/10 bias(Instruction setting)
C2P
VDD
A0
C2N
VSS
VDD
Booster Circuit
C1P
VDD
CS1B
D5~D2 connect to D6
D0,D1 is Slave address
C1N
VDD
3SPI
4SPI
8080
6800
D5~D0
C3P
IIC
Regulator,Follower Circuit
D6
VOUT
CLS="H" used internal oscillator circuit
D7
C95
Display
SEG160 X 96 COM+1 ICON
C
C47
C0
C
C48
COMS2
328
313
314
...........................................................................................................................................................
152
153
154
..........................................................................................................
.............
139
S159
...................
S0
COM88
COMS1
COM95
1
9
8
V0
VSS
SEL3
VDD
SEL2
VSS
SEL1
VDD
IRS
VSS
PSB
VDD
C86
VSS
CLS
VDD
T[0]
T[1]
T[2]
T[3]
T[4]
T[5]
T[6]
T[7]
T[8]
VDD
VRAB
V0
V0
V1
V1
V2
V2
V3
V3
V4
V4
VDD
VRS
VSS
CAP6P
CAP6P
CAP2N
CAP2N
CAP4P
CAP4P
CAP2N
CAP2N
CAP2P
CAP2P
CAP1P
CAP1P
CAP1N
CAP1N
CAP3P
CAP3P
CAP1N
CAP1N
CAP5P
CAP5P
VOUT
VOUT
VOUT
VOUT
VSS
VSS
VSS
VSS
VDD2
VDD2
VDD2
VDD2
VDD
VDD
VDD
VDD
D7
D6
D5
D4
D3
D2
D1
D0
VDD
E(XRD)
RW(XWR)
VSS
A0
RSTP
VDD
CS2
CS1B
VSS
STACOM
COM47
SHL=0
104
103
102
101
VDD 100
99
98
97
VDD 96
95
94
93
VDD 92
91
90
VDD 89
88
87
86
85
84
83
82
81
80
79
78
V0
77
76
75
V1
74
V2
73
72
71
V3
70
V4
69
68
67
66
65
64
63
62
61
60
59
58
57
C2N
56
C2P
55
54
C1P
53
52
C1N
51
50
C3P
49
48
47
46
45
44
VOUT
43
42
41
40
VSS
39
38
37
VDD
36
35
34
33
32
31
30
29
D7
28
D6
27
D5
26
D4
25
D3
24
D2
23
D1
22
D0
21
20
E
19
RW
18
17
A0
16
RSTP
15
14
13
12
CS1B
11
10
105
COM39
113
COM38
.....
114
329
COM63
B
...........................
RW1092(晶晶晶晶)
COM62
COM0
COMS2
SEG0
COM13
COM14
.......................
138
.....
B
SEG159
COM48
IC1
COM87
353
RW1092_96DUTY
A
A
Title
Size
B
Date:
File:
1
2
3
4
5
RockWorks
Number
Revision
RW1092_160x96
17-May-2010
D:\公公公公\99se\MyDesign.ddb
Sheet of
Drawn By:
6
A
1
2
Interface Selection
D
PSB
C86
0
0
1
1
0
1
0
1
3
4
6
5
Interface databus pin setting
Interface
IIC
3/4 SPI
Interface CS1B CS2 A0 E(XRD) RW(XWR)
Now Setting
8080 series
6800 series
VDD
SCLK
VDD
VDD
SDA
SDA
SCLK
C6
C7
C8
CAP
CAP
CAP
D
VDD
CS1B
VDD
VSS
VDD
VDD
SDA
CS1B
VDD
A0
XRD
XWR
D7
SCLK
D6
D5~D0
VDD
CS1B
VDD
A1
E
RW
D7
D6
D5~D0
C0
CAP
C1
CAP
C2
CAP
C3
CAP
R1
V0
IRS="H" use the internal resistors
V1
C4
CAP
R2
RES1
RES1
V2
C5
CAP
V3
V4
Now Setting: 4X
Cap: 2.2uF~4.7uF
Cap: 2.2uF~4.7uF
Bias ratio default :1/9 bias(Instruction setting)
C2P
VDD
A0
C2N
VSS
VDD
Booster Circuit
C1P
VDD
CS1B
D5~D2 connect to D6
D0,D1 is Slave address
C1N
VDD
3SPI
4SPI
8080
6800
D5~D0
C3P
IIC
Regulator,Follower Circuit
D6
VOUT
CLS="H" used internal oscillator circuit
D7
C63
Display
SEG192 X 64 COM+1 ICON
C
C31
C0
C
C32
COMS2
S0
328
S191
...............................................................................................................................................
...............................................................................................................................................
139
S1
....................................................................
COM56
COMS1
COM63
SHL=0
V0
VSS
SEL3
VDD
SEL2
VSS
SEL1
VDD
IRS
VSS
PSB
VDD
C86
VSS
CLS
VDD
T[0]
T[1]
T[2]
T[3]
T[4]
T[5]
T[6]
T[7]
T[8]
VDD
VRAB
V0
V0
V1
V1
V2
V2
V3
V3
V4
V4
VDD
VRS
VSS
CAP6P
CAP6P
CAP2N
CAP2N
CAP4P
CAP4P
CAP2N
CAP2N
CAP2P
CAP2P
CAP1P
CAP1P
CAP1N
CAP1N
CAP3P
CAP3P
CAP1N
CAP1N
CAP5P
CAP5P
VOUT
VOUT
VOUT
VOUT
VSS
VSS
VSS
VSS
VDD2
VDD2
VDD2
VDD2
VDD
VDD
VDD
VDD
D7
D6
D5
D4
D3
D2
D1
D0
VDD
E(XRD)
RW(XWR)
VSS
A0
RSTP
VDD
CS2
CS1B
VSS
STACOM
COM22
COM31
....................
114
RW1092(晶晶晶晶)
SEG191
COM32
329
330
B
...........................
SEG0
COMS2
COM0
SEG1
138
137
136
COM23
B
SEG190
IC1
COM55
353
1
9
8
CS1B
A0
RSTP
XRD
XWR
D7
D6
D5
D4
D3
D2
D1
D0
VDD
VSS
VOUT
C3P
C1N
C1P
C2N
C2P
V4
V3
V2
V1
V0
VDD
VSS
VDD
VDD
VSS
.....
VDD
104
103
102
101
100
99
98
97
96
95
94
93
92
91
90
89
88
87
86
85
84
83
82
81
80
79
78
77
76
75
74
73
72
71
70
69
68
67
66
65
64
63
62
61
60
59
58
57
56
55
54
53
52
51
50
49
48
47
46
45
44
43
42
41
40
39
38
37
36
35
34
33
32
31
30
29
28
27
26
25
24
23
22
21
20
19
18
17
16
15
14
13
12
11
10
105
.....
113
RW1092_64DUTY
A
A
Title
Size
B
Date:
File:
1
2
3
4
5
RockWorks
Number
Revision
RW1092_192x64
17-May-2010
D:\公公公公\99se\MyDesign.ddb
Sheet of
Drawn By:
6
A
1
2
Interface Selection
D
PSB
C86
0
0
1
1
0
1
0
1
3
4
6
5
Interface databus pin setting
Interface
IIC
3/4 SPI
Interface CS1B CS2 A0 E(XRD) RW(XWR)
Now Setting 4SPI
8080 series
6800 series
VDD
SCLK
VDD
VDD
SDA
SDA
SCLK
C6
C7
C8
CAP
CAP
CAP
D
VDD
CS1B
VDD
VSS
VDD
VDD
SDA
CS1B
VDD
A0
XRD
XWR
D7
SCLK
D6
D5~D0
VDD
CS1B
VDD
A1
E
RW
D7
D6
D5~D0
C0
CAP
C1
CAP
C2
CAP
C3
CAP
R1
IRS="H" use the internal resistors
V1
C4
CAP
R2
RES1
V0
C5
CAP
RES1
V2
V3
V4
Now Setting: 4X
Cap: 2.2uF~4.7uF
Cap: 2.2uF~4.7uF
Bias ratio default :1/6 bias(Instruction setting)
C2P
VDD
A0
C2N
VSS
VDD
Booster Circuit
C1P
VDD
CS1B
D5~D2 connect to D6
D0,D1 is Slave address
C1N
VDD
3SPI
4SPI
8080
6800
D5~D0
C3P
IIC
Regulator,Follower Circuit
D6
VOUT
CLS="H" used internal oscillator circuit
D7
C31
Display
C
C31
SEG192 X 32 COM+1 ICON
C0
C
C0
COMS2
S191
328
S190
...............................................................................................................................................
139
S1
...............................................................................................................................................
S0
....................................................................
SEG1
SHL=0
COM24
COMS1
COM31
COM31
COM22
COM23
114
SEG191
COM0
329
330
B
...........................
....................
RW1092(晶晶晶晶)
V0
VSS
SEL3
VDD
SEL2
VSS
SEL1
VDD
IRS
VSS
PSB
VDD
C86
VSS
CLS
VDD
T[0]
T[1]
T[2]
T[3]
T[4]
T[5]
T[6]
T[7]
T[8]
VDD
VRAB
V0
V0
V1
V1
V2
V2
V3
V3
V4
V4
VDD
VRS
VSS
CAP6P
CAP6P
CAP2N
CAP2N
CAP4P
CAP4P
CAP2N
CAP2N
CAP2P
CAP2P
CAP1P
CAP1P
CAP1N
CAP1N
CAP3P
CAP3P
CAP1N
CAP1N
CAP5P
CAP5P
VOUT
VOUT
VOUT
VOUT
VSS
VSS
VSS
VSS
VDD2
VDD2
VDD2
VDD2
VDD
VDD
VDD
VDD
D7
D6
D5
D4
D3
D2
D1
D0
VDD
E(XRD)
RW(XWR)
VSS
A0
RSTP
VDD
CS2
CS1B
VSS
STACOM
B
SEG0
COMS2
COM0
SEG190
IC1
138
137
136
COM23
353
1
9
8
CS1B
A0
RSTP
SDA
SCLK
VDD
VSS
VOUT
C3P
C1N
C1P
C2N
C2P
V4
V3
V2
V1
V0
VDD
VDD
VSS
VDD
.....
VSS
104
103
102
101
100
99
98
97
96
95
94
93
92
91
90
89
88
87
86
85
84
83
82
81
80
79
78
77
76
75
74
73
72
71
70
69
68
67
66
65
64
63
62
61
60
59
58
57
56
55
54
53
52
51
50
49
48
47
46
45
44
43
42
41
40
39
38
37
36
35
34
33
32
31
30
29
28
27
26
25
24
23
22
21
20
19
18
17
16
15
14
13
12
11
10
105
..........
113
RW1092_32DUTY
A
A
Title
Size
B
Date:
File:
1
2
3
4
5
RockWorks
Number
Revision
RW1092_192x32
17-May-2010
D:\公公公公\99se\MyDesign.ddb
Sheet of
Drawn By:
6
A
1
2
Interface Selection
D
PSB
C86
0
0
1
1
0
1
0
1
3
4
Interface databus pin setting
Interface
IIC
3/4 SPI
Interface CS1B CS2 A0 E(XRD) RW(XWR)
Now Setting 3SPI
8080 series
6800 series
D7
VDD
SCLK
VDD
VDD
SDA
SDA
SCLK
C6
C7
C8
CAP
CAP
CAP
D
VDD
CS1B
VDD
VSS
VDD
VDD
SDA
CS1B
VDD
A0
XRD
XWR
D7
SCLK
D6
D5~D0
VDD
CS1B
VDD
A1
E
RW
D7
D6
D5~D0
C0
CAP
C1
CAP
C2
CAP
C3
CAP
R1
IRS="H" use the internal resistors
V1
C4
CAP
R2
RES1
V0
C5
CAP
RES1
V2
V3
V4
Now Setting: 4X
Cap: 2.2uF~4.7uF
Cap: 2.2uF~4.7uF
Bias ratio default :1/5 bias(Instruction setting)
C2P
VDD
A0
C2N
VSS
VDD
Booster Circuit
C1P
VDD
CS1B
D5~D2 connect to D6
D0,D1 is Slave address
C1N
VDD
3SPI
4SPI
8080
6800
D5~D0
C3P
IIC
Regulator,Follower Circuit
D6
VOUT
CLS="H" used internal oscillator circuit
C
6
5
C15
C
C15
Display
SEG192 X 16 COM+1 ICON
C0
C0
COMS2
S191
328
S190
...............................................................................................................................................
139
S1
...............................................................................................................................................
S0
....................................................................
SEG1
COM15
NC
NC
NC
NC
NC
329
330
B
345
346
....
..........
114
SHL=0
V0
VSS
SEL3
VDD
SEL2
VSS
SEL1
VDD
IRS
VSS
PSB
VDD
C86
VSS
CLS
VDD
T[0]
T[1]
T[2]
T[3]
T[4]
T[5]
T[6]
T[7]
T[8]
VDD
VRAB
V0
V0
V1
V1
V2
V2
V3
V3
V4
V4
VDD
VRS
VSS
CAP6P
CAP6P
CAP2N
CAP2N
CAP4P
CAP4P
CAP2N
CAP2N
CAP2P
CAP2P
CAP1P
CAP1P
CAP1N
CAP1N
CAP3P
CAP3P
CAP1N
CAP1N
CAP5P
CAP5P
VOUT
VOUT
VOUT
VOUT
VSS
VSS
VSS
VSS
VDD2
VDD2
VDD2
VDD2
VDD
VDD
VDD
VDD
D7
D6
D5
D4
D3
D2
D1
D0
VDD
E(XRD)
RW(XWR)
VSS
A0
RSTP
VDD
CS2
CS1B
VSS
STACOM
COM15
NC
SEG191
COM0
...............
RW1092(晶晶晶晶)
...
121
120
COMS1
NC
B
SEG0
COMS2
COM0
SEG190
IC1
138
137
136
NC
353
1
9
8
CS1B
RSTP
SDA
SCLK
VDD
VSS
VOUT
C3P
C1N
C1P
C2N
C2P
V4
V3
V2
V1
V0
VDD
VDD
VSS
VDD
VSS
VDD
.....
VSS
104
103
102
101
100
99
98
97
96
95
94
93
92
91
90
89
88
87
86
85
84
83
82
81
80
79
78
77
76
75
74
73
72
71
70
69
68
67
66
65
64
63
62
61
60
59
58
57
56
55
54
53
52
51
50
49
48
47
46
45
44
43
42
41
40
39
38
37
36
35
34
33
32
31
30
29
28
27
26
25
24
23
22
21
20
19
18
17
16
15
14
13
12
11
10
105
..........
113
RW1092_16DUTY
A
A
Title
Size
B
Date:
File:
1
2
3
4
5
RockWorks
Number
Revision
RW1092_192x16
17-May-2010
D:\公公公公\99se\MyDesign.ddb
Sheet of
Drawn By:
6
A
1
2
Interface Selection
D
PSB
C86
0
0
1
1
0
1
0
1
3
4
6
5
Interface databus pin setting
Interface
IIC
3/4 SPI
Interface CS1B CS2 A0 E(XRD) RW(XWR)
Now Setting
8080 series
6800 series
VDD
SCLK
VDD
VDD
SDA
SDA
SCLK
C6
C7
C8
CAP
CAP
CAP
D
VDD
CS1B
VDD
VSS
VDD
VDD
SDA
CS1B
VDD
A0
XRD
XWR
D7
SCLK
D6
D5~D0
VDD
CS1B
VDD
A1
E
RW
D7
D6
D5~D0
C0
CAP
C1
CAP
C2
CAP
C3
CAP
R1
IRS="H" use the internal resistors
V1
C4
CAP
R2
RES1
V0
C5
CAP
RES1
V2
V3
V4
Now Setting: 4X
Cap: 2.2uF~4.7uF
Cap: 2.2uF~4.7uF
Bias ratio default :1/5 bias(Instruction setting)
C2P
VDD
A0
C2N
VSS
VDD
Booster Circuit
C1P
VDD
CS1B
D5~D2 connect to D6
D0,D1 is Slave address
C1N
VDD
3SPI
4SPI
8080
6800
D5~D0
C3P
IIC
Regulator,Follower Circuit
D6
VOUT
CLS="H" used internal oscillator circuit
D7
C
C
C7
C7
Display
SEG192 X 8 COM+1 ICON
C0
C0
COMS2
S191
328
S190
...............................................................................................................................................
139
S1
...............................................................................................................................................
S0
....................................................................
SEG1
COM7
NC
NC
NC
NC
NC
329
330
B
337
338
..........
........
114
SHL=0
V0
VSS
SEL3
VDD
SEL2
VSS
SEL1
VDD
IRS
VSS
PSB
VDD
C86
VSS
CLS
VDD
T[0]
T[1]
T[2]
T[3]
T[4]
T[5]
T[6]
T[7]
T[8]
VDD
VRAB
V0
V0
V1
V1
V2
V2
V3
V3
V4
V4
VDD
VRS
VSS
CAP6P
CAP6P
CAP2N
CAP2N
CAP4P
CAP4P
CAP2N
CAP2N
CAP2P
CAP2P
CAP1P
CAP1P
CAP1N
CAP1N
CAP3P
CAP3P
CAP1N
CAP1N
CAP5P
CAP5P
VOUT
VOUT
VOUT
VOUT
VSS
VSS
VSS
VSS
VDD2
VDD2
VDD2
VDD2
VDD
VDD
VDD
VDD
D7
D6
D5
D4
D3
D2
D1
D0
VDD
E(XRD)
RW(XWR)
VSS
A0
RSTP
VDD
CS2
CS1B
VSS
STACOM
COM7
NC
SEG191
COM0
.......
RW1092(晶晶晶晶)
...
129
128
COMS1
NC
B
SEG0
COMS2
COM0
SEG190
IC1
138
137
136
NC
353
SA1
SA0
01111
0
0
0x78
01111
0
1
0x7a
01111
1
0
0x7c
01111
1
1
0x7e
Now Setting
Title
B
Date:
File:
2
3
4
1
Slave address
Size
1
9
8
RSTP
SA1
SA0
SCLK
SDA
VDD
VSS
VOUT
C3P
C1N
C1P
C2N
C2P
V4
V3
V2
V1
V0
VDD
VSS
VDD
VSS
104
103
102
101
100
99
98
97
96
95
94
93
92
91
90
89
88
87
86
85
84
83
82
81
80
79
78
77
76
75
74
73
72
71
70
69
68
67
66
65
64
63
62
61
60
59
58
57
56
55
54
53
52
51
50
49
48
47
46
45
44
43
42
41
40
39
38
37
36
35
34
33
32
31
30
29
28
27
26
25
24
23
22
21
20
19
18
17
16
15
14
13
12
11
10
105
.....
A
..........
113
RW1092_8DUTY
5
A
RockWorks
Number
Revision
RW1092_192x8
17-May-2010
D:\公公公公\99se\MyDesign.ddb
Sheet of
Drawn By:
6
A
1
2
Interface Selection
D
PSB
C86
0
0
1
1
0
1
0
1
3
4
6
5
Interface databus pin setting
Interface
IIC
3/4 SPI
Interface CS1B CS2 A0 E(XRD) RW(XWR)
Now Setting
8080 series
6800 series
VDD
SCLK
VDD
VDD
SDA
SDA
SCLK
C6
C7
C8
CAP
CAP
CAP
D
VDD
CS1B
VDD
VSS
VDD
VDD
SDA
CS1B
VDD
A0
XRD
XWR
D7
SCLK
D6
D5~D0
VDD
CS1B
VDD
A1
E
RW
D7
D6
D5~D0
C0
CAP
C1
CAP
C2
CAP
C3
CAP
R1
IRS="H" use the internal resistors
V1
C4
CAP
R2
RES1
V0
C5
CAP
RES1
V2
V3
V4
Now Setting: 4X
Cap: 2.2uF~4.7uF
Cap: 2.2uF~4.7uF
Bias ratio default :1/3 bias(Instruction setting)
C2P
VDD
A0
C2N
VSS
VDD
Booster Circuit
C1P
VDD
CS1B
D5~D2 connect to D6
D0,D1 is Slave address
C1N
VDD
3SPI
4SPI
8080
6800
D5~D0
C3P
IIC
Regulator,Follower Circuit
D6
VOUT
CLS="H" used internal oscillator circuit
D7
C
C
C3
C3
Display
SEG192 X 4 COM+1 ICON
C0
C0
COMS2
S191
328
S190
...............................................................................................................................................
139
S1
...............................................................................................................................................
S0
....................................................................
NC
NC
NC
NC
329
330
B
333
334
..............
........
114
SHL=0
COMS1
NC
RW1092(晶晶晶晶)
COM3
NC
SEG191
COM0
COM3
NC
V0
VSS
SEL3
VDD
SEL2
VSS
SEL1
VDD
IRS
VSS
PSB
VDD
C86
VSS
CLS
VDD
T[0]
T[1]
T[2]
T[3]
T[4]
T[5]
T[6]
T[7]
T[8]
VDD
VRAB
V0
V0
V1
V1
V2
V2
V3
V3
V4
V4
VDD
VRS
VSS
CAP6P
CAP6P
CAP2N
CAP2N
CAP4P
CAP4P
CAP2N
CAP2N
CAP2P
CAP2P
CAP1P
CAP1P
CAP1N
CAP1N
CAP3P
CAP3P
CAP1N
CAP1N
CAP5P
CAP5P
VOUT
VOUT
VOUT
VOUT
VSS
VSS
VSS
VSS
VDD2
VDD2
VDD2
VDD2
VDD
VDD
VDD
VDD
D7
D6
D5
D4
D3
D2
D1
D0
VDD
E(XRD)
RW(XWR)
VSS
A0
RSTP
VDD
CS2
CS1B
VSS
STACOM
133
132
SEG1
B
SEG0
COMS2
COM0
SEG190
IC1
138
137
136
NC
353
SA1
SA0
01111
0
0
0x78
01111
0
1
0x7a
01111
1
0
0x7c
01111
1
1
0x7e
Now Setting
Title
B
Date:
File:
2
3
4
1
Slave address
Size
1
9
8
RSTP
SA1
SA0
SCLK
SDA
VDD
VSS
VOUT
C3P
C1N
C1P
C2N
C2P
V4
V3
V2
V1
V0
VDD
VSS
VDD
VSS
104
103
102
101
100
99
98
97
96
95
94
93
92
91
90
89
88
87
86
85
84
83
82
81
80
79
78
77
76
75
74
73
72
71
70
69
68
67
66
65
64
63
62
61
60
59
58
57
56
55
54
53
52
51
50
49
48
47
46
45
44
43
42
41
40
39
38
37
36
35
34
33
32
31
30
29
28
27
26
25
24
23
22
21
20
19
18
17
16
15
14
13
12
11
10
105
.....
A
..........
113
RW1092_4DUTY
5
A
RockWorks
Number
Revision
RW1092_192x4
17-May-2010
D:\公公公公\99se\MyDesign.ddb
Sheet of
Drawn By:
6
A
1
2
Interface Selection
D
PSB
C86
0
0
1
1
0
1
0
1
3
4
6
5
Interface databus pin setting
Interface
IIC
3/4 SPI
Interface CS1B CS2 A0 E(XRD) RW(XWR)
Now Setting
8080 series
6800 series
CLS="H" used internal oscillator circuit
D7
D6
D5~D0
D5~D2 connect to D6
D0,D1 is Slave address
IIC
VDD
VDD
VSS
VDD
VDD
SCLK
3SPI
4SPI
8080
6800
CS1B
VDD
A0
VDD
VDD
SDA
SCLK
CS1B
VDD
VSS
VDD
VDD
SDA
SCLK
CS1B
VDD
A0
XRD
XWR
D7
D6
D5~D0
CS1B
VDD
A1
E
RW
D7
D6
D5~D0
SDA
D
VDD
VDD
IRS="H" use the internal resistors
Bias selection must be set to 1/2 bias
Static Display
SEG192 X 1 COM
C
C
C0
S191
328
S190
...............................................................................................................................................
139
S1
...............................................................................................................................................
S0
....................................................................
SEG1
SA1
SA0
01111
0
0
0x78
01111
0
1
0x7a
01111
1
0
0x7c
01111
1
1
0x7e
NC
1
9
8
Date:
File:
4
RW1092_STATIC
A
B
3
353
Now Setting
Size
2
NC
B
Slave address
Title
1
329
330
RSTP
SA1
SA0
SCLK
SDA
VSS
VDD
VDD
VSS
VDD
A
COMS1
NC
V0
VSS
SEL3
VDD
SEL2
VSS
SEL1
VDD
IRS
VSS
PSB
VDD
C86
VSS
CLS
VDD
T[0]
T[1]
T[2]
T[3]
T[4]
T[5]
T[6]
T[7]
T[8]
VDD
VRAB
V0
V0
V1
V1
V2
V2
V3
V3
V4
V4
VDD
VRS
VSS
CAP6P
CAP6P
CAP2N
CAP2N
CAP4P
CAP4P
CAP2N
CAP2N
CAP2P
CAP2P
CAP1P
CAP1P
CAP1N
CAP1N
CAP3P
CAP3P
CAP1N
CAP1N
CAP5P
CAP5P
VOUT
VOUT
VOUT
VOUT
VSS
VSS
VSS
VSS
VDD2
VDD2
VDD2
VDD2
VDD
VDD
VDD
VDD
D7
D6
D5
D4
D3
D2
D1
D0
VDD
E(XRD)
RW(XWR)
VSS
A0
RSTP
VDD
CS2
CS1B
VSS
STACOM
NC
VSS
104
103
102
101
100
99
98
97
96
95
94
93
92
91
90
89
88
87
86
85
84
83
82
81
80
79
78
77
76
75
74
73
72
71
70
69
68
67
66
65
64
63
62
61
60
59
58
57
56
55
54
53
52
51
50
49
48
47
46
45
44
43
42
41
40
39
38
37
36
35
34
33
32
31
30
29
28
27
26
25
24
23
22
21
20
19
18
17
16
15
14
13
12
11
10
105
NC
113
.....
NC
..........
114
SEG191
NC
......................
RW1092(晶晶晶晶) Static Drive
....................
B
SEG0
COMS2
NC
SEG190
IC1
138
137
136
5
RockWorks
Number
Revision
RW1092_192x1_Static
17-May-2010
D:\公公公公\99se\MyDesign.ddb
Sheet of
Drawn By:
6
A