SITRONIX ST7533

ST
Sitronix
ST7533
33 x 96 Dot Matrix LCD Controller/Driver
FEATURES
gradient –0.15%/°C ) V5 voltage regulator resistors
equipped internally, V1 to V4 voltage divider resistors
equipped internally, electronic volume function
equipped internally, voltage follower.
CR oscillator circuit equipped internally (external
clock can also be input)
Extremely low power consumption Operating power
when the built-in power supply is used (an example)
70uA (VDD – VSS = VDD – VSS2 =3.0 V, Quad voltage,
V5 – VDD = – 11.0 V).
Conditions: When displays pattern OFF and the
normal mode is selected.
Power supply operate on the low 1.8 voltage
Logic power supply
VDD – VSS = 1.8V to 3.3V (+10% Range)
Boost reference voltage: VDD – VSS2 = 1.8V to 3.3V
Booster maximum voltage limited
VOUT= -13V (+10% Range)
Liquid crystal drive power supply:
VDD – V5 = 4.0V to 13.0 V
Wide range of operating temperatures: –40 to 85°C
CMOS process
These chips not designed for resistance to light or
resistance to radiation.
Direct display of RAM data through the display data
RAM.
RAM capacity : 33 x 96 = 3168 bits
Display duty selectable by select pin
1/33 duty : 33 common x 96 segment
1/17 duty : 17 common x 96 segment
High-speed 8-bit MPU interface (The chip can be
connected directly to the both the 80x86 series MPUs
and the 68000 series MPUs)
/Serial interfaces are supported.
Abundant command functions
Display data Read/Write, display ON/OFF, Normal/
Reverse display mode, page address set, display start
line set, column address set, status read, display all
points ON/OFF, LCD bias set, electronic volume,
read/modify/write, segment driver direction select,
power saver, static indicator, common output status
select, V5 voltage regulation internal resistor ratio set.
Static drive circuit equipped internally for indicators.
(1 system, with variable flashing speed.)
Low-power liquid crystal display power supply circuit
equipped internally.
Booster circuit (with Boost ratios of 2X/3X/4X
, where the step-up voltage reference power
supply can be input externally).
High-accuracy voltage adjustment circuit (Thermal
GENERAL DESCRIPTION
The ST7533 is a single-chip dot matrix LCD drivers 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 ST7533 contain 33x96 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.
The ST7533 chips contain 33 common output circuits and 96
segment output circuits, so that a single chip can drive a
33x96 dot display (capable of displaying 8 columnsx4 rows of
PART NO.
ST7533
Ver 1.0
a 16x16 dot kanji font).
Moreover, the capacity of the display can be extended
through the use of master/slave structures between chips.
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, resistors for LCD driver power
voltage adjustment and a display clock CR oscillator circuit,
the ST7533 can be used to create the lowest power display
system with the fewest components for high-performance
portable devices.
VRS temperature gradient
-0.15%/°C
1/60
VRS range
-2.1V ±0.03V
2003/07/21
ST7533
ST7533 Pad Arrangement
Chip Size:
7240μm x 1,000 μm
Origin: Chip Center
Bump Pitch:
69.1μm(Min.)
Bump Size:
PAD No. 001〜005
PAD No. 006〜064
PAD No. 065〜070
PAD No. 071〜083
PAD No. 084〜088
PAD No. 089〜100
PAD No. 101〜196
PAD No. 197〜208
Bump Height:
18μm(Typ)
Chip Thickness: 660μm
30um
49.1μm x 70.5μm
56μm x 60μm
51μm x 60μm
56μm x 60μm
49.1μm x 70.5μm
70.5μm x 49.1μm
49.1μm x 70.5μm
70.5μm x 49.1μm
15 15
um um
15 um
15 um
40um
15 um
15 15
um um
30um
30um
15 um
25um 30um 25um
30um 30um
(-3405, 435)
(3385,435)
088
084 083
•••
089
071 070
•••
ST7533
PAD DIAGRAM
065 064
•••
006 005
•••••
001
•••
208
Y
(3266, 162)
•••
•••
X
(0,0)
(-3312,-175)
•••
100
101
Ver 1.0
197
196
2/60
2003/07/21
ST7533
Pad Center Coordinates (1/33 Duty)
PAD
No.
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
41
42
43
44
45
46
47
48
49
50
51
52
Ver 1.0
PIN Name
X
Y
COM[28]
COM[29]
COM[30]
COM[31]
COMS1
FRS
FR
CL
/DOF
VSS
/CS1
CS2
VDD
/RES
A0
VSS
/WR(R/W)
/RD(E)
VDD
D0
D1
D2
D3
D4
D5
D6
D7
VDD
VDD
VDD
VSS
VSS
VSS2
VSS2
VOUT
VOUT
CAP3CAP3CAP1+
CAP1+
CAP1CAP1CAP2CAP2CAP2+
CAP2+
VSS
VSS
VRS
VDD
VDD
V1
3290
3221
3152
3083
3014
2919
2843
2767
2691
2614
2538
2462
2386
2310
2234
2157
2081
2005
1929
1853
1777
1701
1624
1548
1472
1396
1320
1244
1168
1091
1015
939
863
787
711
634
558
482
406
330
254
178
101
25
-51
-127
-203
-279
-355
-432
-508
-584
409
409
409
409
409
414
414
414
414
414
414
414
414
414
414
414
414
414
414
414
414
414
414
414
414
414
414
414
414
414
414
414
414
414
414
414
414
414
414
414
414
414
414
414
414
414
414
414
414
414
414
414
PAD
No.
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
81
82
83
84
85
86
87
88
89
90
91
92
93
94
95
96
97
98
99
100
101
102
103
104
3/60
PIN Name
X
Y
V1
V2
V2
V3
V3
V4
V4
V5
V5
VR
VDD
VDD
TEST0
TEST1
TEST2
TEST3
TEST4
TEST5
VDD
M/S
CLS
VSS
C86
P/S
VDD
/HPM
VSS
IRS
VDD
SEL1
VSS
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]
-660
-736
-812
-889
-965
-1041
-1117
-1193
-1269
-1345
-1422
-1498
-1571
-1642
-1713
-1784
-1855
-1926
-2000
-2076
-2152
-2228
-2305
-2381
-2457
-2533
-2609
-2685
-2762
-2838
-2914
-3011
-3080
-3150
-3219
-3288
-3529
-3529
-3529
-3529
-3529
-3529
-3529
-3529
-3529
-3529
-3529
-3529
-3280
-3211
-3142
-3073
414
414
414
414
414
414
414
414
414
414
414
414
414
414
414
414
414
414
414
414
414
414
414
414
414
414
414
414
414
414
414
409
409
409
409
409
351
282
213
144
75
6
-64
-133
-202
-271
-340
-409
-409
-409
-409
-409
2003/07/21
ST7533
PAD
No.
105
106
107
108
109
110
111
112
113
114
115
116
117
118
119
120
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
Ver 1.0
PIN Name
X
Y
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]
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]
-3004
-2935
-2866
-2797
-2728
-2658
-2589
-2520
-2451
-2382
-2313
-2244
-2175
-2106
-2037
-1967
-1898
-1829
-1760
-1691
-1622
-1553
-1484
-1415
-1346
-1276
-1207
-1138
-1069
-1000
-931
-862
-793
-724
-655
-585
-516
-447
-378
-309
-240
-171
-102
-33
36
106
175
244
313
382
451
520
-409
-409
-409
-409
-409
-409
-409
-409
-409
-409
-409
-409
-409
-409
-409
-409
-409
-409
-409
-409
-409
-409
-409
-409
-409
-409
-409
-409
-409
-409
-409
-409
-409
-409
-409
-409
-409
-409
-409
-409
-409
-409
-409
-409
-409
-409
-409
-409
-409
-409
-409
-409
PAD
No.
157
158
159
160
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
201
202
203
204
205
206
207
208
4/60
PIN Name
X
Y
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]
SEG[87]
SEG[88]
SEG[89]
SEG[90]
SEG[91]
SEG[92]
SEG[93]
SEG[94]
SEG[95]
COM[16]
COM[17]
COM[18]
COM[19]
COM[20]
COM[21]
COM[22]
COM[23]
COM[24]
COM[25]
COM[26]
COM[27]
589
658
727
797
866
935
1004
1073
1142
1211
1280
1349
1418
1488
1557
1626
1695
1764
1833
1902
1971
2040
2109
2179
2248
2317
2386
2455
2524
2593
2662
2731
2800
2870
2939
3008
3077
3146
3215
3284
3529
3529
3529
3529
3529
3529
3529
3529
3529
3529
3529
3529
-409
-409
-409
-409
-409
-409
-409
-409
-409
-409
-409
-409
-409
-409
-409
-409
-409
-409
-409
-409
-409
-409
-409
-409
-409
-409
-409
-409
-409
-409
-409
-409
-409
-409
-409
-409
-409
-409
-409
-409
-409
-340
-271
-202
-133
-64
6
75
144
213
282
351
2003/07/21
ST7533
Pad Center Coordinates (1/17 Duty)
PAD
No.
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
41
42
43
44
45
46
47
48
49
50
51
52
Ver 1.0
PIN Name
X
Y
COM[12]
COM[13]
COM[14]
COM[15]
COMS1
FRS
FR
CL
/DOF
VSS
/CS1
CS2
VDD
/RES
A0
VSS
/WR(R/W)
/RD(E)
VDD
D0
D1
D2
D3
D4
D5
D6
D7
VDD
VDD
VDD
VSS
VSS
VSS2
VSS2
VOUT
VOUT
CAP3CAP3CAP1+
CAP1+
CAP1CAP1CAP2CAP2CAP2+
CAP2+
VSS
VSS
VRS
VDD
VDD
V1
3290
3221
3152
3083
3014
2919
2843
2767
2691
2614
2538
2462
2386
2310
2234
2157
2081
2005
1929
1853
1777
1701
1624
1548
1472
1396
1320
1244
1168
1091
1015
939
863
787
711
634
558
482
406
330
254
178
101
25
-51
-127
-203
-279
-355
-432
-508
-584
409
409
409
409
409
414
414
414
414
414
414
414
414
414
414
414
414
414
414
414
414
414
414
414
414
414
414
414
414
414
414
414
414
414
414
414
414
414
414
414
414
414
414
414
414
414
414
414
414
414
414
414
PAD
No.
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
81
82
83
84
85
86
87
88
89
90
91
92
93
94
95
96
97
98
99
100
101
102
103
104
5/60
PIN Name
X
Y
V1
V2
V2
V3
V3
V4
V4
V5
V5
VR
VDD
VDD
TEST0
TEST1
TEST2
TEST3
TEST4
TEST5
VDD
M/S
CLS
VSS
C86
P/S
VDD
/HPM
VSS
IRS
VDD
SEL1
VSS
Reserve
Reserve
Reserve
Reserve
Reserve
Reserve
Reserve
Reserve
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]
-660
-736
-812
-889
-965
-1041
-1117
-1193
-1269
-1345
-1422
-1498
-1571
-1642
-1713
-1784
-1855
-1926
-2000
-2076
-2152
-2228
-2305
-2381
-2457
-2533
-2609
-2685
-2762
-2838
-2914
-3011
-3080
-3150
-3219
-3288
-3529
-3529
-3529
-3529
-3529
-3529
-3529
-3529
-3529
-3529
-3529
-3529
-3280
-3211
-3142
-3073
414
414
414
414
414
414
414
414
414
414
414
414
414
414
414
414
414
414
414
414
414
414
414
414
414
414
414
414
414
414
414
409
409
409
409
409
351
282
213
144
75
6
-64
-133
-202
-271
-340
-409
-409
-409
-409
-409
2003/07/21
ST7533
PAD
No.
105
106
107
108
109
110
111
112
113
114
115
116
117
118
119
120
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
Ver 1.0
PIN Name
X
Y
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]
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]
-3004
-2935
-2866
-2797
-2728
-2658
-2589
-2520
-2451
-2382
-2313
-2244
-2175
-2106
-2037
-1967
-1898
-1829
-1760
-1691
-1622
-1553
-1484
-1415
-1346
-1276
-1207
-1138
-1069
-1000
-931
-862
-793
-724
-655
-585
-516
-447
-378
-309
-240
-171
-102
-33
36
106
175
244
313
382
451
520
-409
-409
-409
-409
-409
-409
-409
-409
-409
-409
-409
-409
-409
-409
-409
-409
-409
-409
-409
-409
-409
-409
-409
-409
-409
-409
-409
-409
-409
-409
-409
-409
-409
-409
-409
-409
-409
-409
-409
-409
-409
-409
-409
-409
-409
-409
-409
-409
-409
-409
-409
-409
PAD
No.
157
158
159
160
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
201
202
203
204
205
206
207
208
6/60
PIN Name
X
Y
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]
SEG[87]
SEG[88]
SEG[89]
SEG[90]
SEG[91]
SEG[92]
SEG[93]
SEG[94]
SEG[95]
Reserve
Reserve
Reserve
Reserve
Reserve
Reserve
Reserve
Reserve
COM[8]
COM[9]
COM[10]
COM[11]
589
658
727
797
866
935
1004
1073
1142
1211
1280
1349
1418
1488
1557
1626
1695
1764
1833
1902
1971
2040
2109
2179
2248
2317
2386
2455
2524
2593
2662
2731
2800
2870
2939
3008
3077
3146
3215
3284
3529
3529
3529
3529
3529
3529
3529
3529
3529
3529
3529
3529
-409
-409
-409
-409
-409
-409
-409
-409
-409
-409
-409
-409
-409
-409
-409
-409
-409
-409
-409
-409
-409
-409
-409
-409
-409
-409
-409
-409
-409
-409
-409
-409
-409
-409
-409
-409
-409
-409
-409
-409
-409
-340
-271
-202
-133
-64
6
75
144
213
282
351
2003/07/21
ST7533
BLOCK DIAGRAM
COMS
96 SEGMENT
DRIVERS
COMS
COM31
COM0
SEG95
SEG0
VDD
V1
V2
V3
V4
V5
33 COMMON
DRIVERS
COM output control circuit
Display data latch circuit
VR
VRS
IRS
Voltage
Regulator
circuit
Line address circuit
V5
I/O buffer
Page address circuit
Voltage
follower
circuit
Display timing generator circuit
HPM
DISPLAY DATA RAM
33 X 96 = 3186 Bits
VOUT
VSS2
Column address circuit
Voltage
booster
circuit
M/S
CL
DOF
FR
Oscillator
circuit
CAP1+
CAP1CAP2+
CAP2CAP3+
FRS
Power Supply
Circuit
Status
Command decoder
CLS
Bus holder
VSS
MPU INTERFACE ( Parallel and Serial )
D7(SI)
D6(SCL)
D5
D4
D3
D2
D1
D0
7/60
P/S
C86
/RES
CS2
CS1
A0
RW(WR)
E(RD)
SEL1
Ver 1.0
2003/07/21
ST7533
PIN DESCRIPTIONS
Power Supply Pins
Pin Name
VDD
VSS
VSS2
VRS
I/O
Power
Supply
Power
Supply
Power
Supply
Power
Supply
Function
No. of Pins
Shared with the MPU power supply terminal Vcc.
12
This is a 0V terminal connected to the system GND.
9
This is the reference power supply for the step-up voltage circuit for the
liquid crystal drive.
This is the internal-output VREG power supply for the LCD power supply
voltage regulator.
2
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 VDD, and must maintain the relative
magnitudes shown below.
VDD (= V0) ≧V1 ≧V2 ≧V3 ≧V4 ≧V5
V1, V2,
V3, V4,
V5
Power
Supply
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.
V1
V2
V3
V4
1/33 DUTY
1/6*V5,1/5*V5
2/6*V5,2/5*V5
4/6*V5,3/5*V5
5/6*V5,4/5*V5
10
1/17 DUTY
1/6*V5,1/5*V5
2/6*V5,2/5*V5
4/6*V5,3/5*V5
5/6*V5,4/5*V5
LCD Power Supply Pins
Pin Name
I/O
CAP1+
O
CAP1–
O
CAP2+
O
CAP2–
O
CAP3–
O
VOUT
O
VR
I
Ver 1.0
Function
DC/DC voltage converter. Connect a capacitor between this terminal and
the CAP1- terminal.
DC/DC voltage converter. Connect a capacitor between this terminal and
the CAP1+ terminal.
DC/DC voltage converter. Connect a capacitor between this terminal and
the CAP2- terminal.
DC/DC voltage converter. Connect a capacitor between this terminal and
the CAP2+ terminal.
DC/DC voltage converter. Connect a capacitor between this terminal and
the CAP1+ terminal.
DC/DC voltage converter. Connect a capacitor between this terminal and
VSS.
Output voltage regulator terminal. Provides the voltage between VDD and
V5 through a resistive voltage divider.
IRS = “L” : the V5 voltage regulator internal resistors are not used .
IRS = “H” : the V5 voltage regulator internal resistors are used .
8/60
No. of Pins
2
2
2
2
2
2
2
2003/07/21
ST7533
System Bus Connection Pins
Pin Name
I/O
D5 to D0
D6 (SCL)
D7 (SI)
I/O
A0
I
/RES
/CS1
CS2
/RD
(E)
/WR
(R/W)
C86
I
Function
No. of Pins
This is an 8-bit bi-directional data bus that connects to an 8-bit or 16-bit
standard MPU data bus.
When the serial interface is selected (P/S = “L”) :
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.
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 /RES is set to “L,” the settings are initialized.
8
1
1
The reset operation is performed by the /RES signal level.
I
I
I
I
This is the chip select signal. When /CS1 = “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 /RD signal of the 8080 MPU, and the
ST7533 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.
(R/W) This terminal connects to the 8080 MPU/WR signal. The signals on
the data bus are latched at the rising edge of the /WR signal.
• When connected to a 6800 Series MPU:
This is the read/write control signal input terminal.
When R/W = “H”: Read.
When R/W = “L”: Write.
This is the MPU interface switch terminal.
C86 = “H”: 6800 Series MPU interface.
C86 = “L”: 8080 MPU interface.
2
1
1
1
This is the parallel data input/serial data input switch terminal.
P/S = “H”: Parallel data input.
P/S = “L”: Serial data input.
The following applies depending on the P/S status:
P/S
I
P/S
Data/Command
Data
Read/Write Serial Clock
“H”
A0
D0 to D7
/RD, /WR
X
“L”
A0
SI (D7)
Write only
SCL (D6)
1
When P/S = “L”, D0 to D5 fixed to either “H”.
/RD (E) and /WR (R/W) are fixed to either “H” or “L”.
With serial data input, It is impossible read data from RAM .
Ver 1.0
9/60
2003/07/21
ST7533
Pin Name
CLS
I/O
I
Function
No. of Pins
Terminal to select whether or enable or disable the display clock internal
oscillator circuit.
CLS = “H” : used Internal oscillator circuit .
CLS = “L” : used external clock input .(internal oscillator is disable)
When CLS = “L”, input the display clock through the CL terminal.
1
This terminal selects the master/slave operation for the ST7533 Series chips.
Master operation outputs the timing signals that are required for the LCD display, while
slave operation input the timing signals required for the liquid crystal display,
Synchronizing the liquid crystal display system.
M/S = “H” Master operation
M/S = “L” Slave operation
M/S
I
M/S CLS
“H”
“L”
“H”
“L”
“H”
“L”
Power
Supply
Circuit
Oscillator
Circuit
Enabled
Disabled
Disabled
Disabled
CL
Enabled Output
Enabled Input
Disabled Input
Disabled Input
FR
FRS
DOF
Output
Output
Input
Input
Output
Output
Output
Output
Output
Output
Input
Input
1
This is the display clock input terminal
The following is true depending on the M/S and CLS status.
M/S
CL
I/O
“H”
“L”
CLS
CL
“H”
“L”
“H”
“L”
Output
Input
Input
Input
1
FR
O
This is the liquid crystal alternating current signal terminal.
1
/DOF
O
This is the LCD blanking control terminal.
1
FRS
O
IRS
I
/HPM
I
SEL1
I
This is the output terminal for the static drive.
This terminal is only enabled when the static indicator display is ON
and is used in conjunction with the FR terminal.
This terminal selects the resistors for the V5 voltage level adjustment.
IRS = “H”: Use the internal resistors
IRS = “L”: Do not use the internal resistors. The V5 voltage level is
regulated by an external resistive voltage divider attached to the VR terminal
This is the power control terminal for the power supply circuit for liquid crystal
drive.
/HPM = “H”: Normal mode
/HPM = “L”: High power mode
These pins are DUTY selection.
SEL 1
TEST0 ~ 5
Ver 1.0
I
DUTY
BIAS
0
1/33
1/5 or 1/6
1
1/17
1/5 or 1/6
These are terminals for IC testing .
TEST0 (PAD No.65) must connect to VDD
TEST1 ~ 5 must floating
10/60
1
1
1
1
6
2003/07/21
ST7533
LCD Driver Pins
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 VDD, V2, V3, and V5.
SEG0
to
SEG95
O
Output Voltage
RAM DATA
FR
Normal Display
Reverse Display
H
H
VDD
V2
H
L
V5
V3
L
H
V2
VDD
L
L
V3
V5
Power save
----
96
VDD
These are the LCD common drive outputs.
COM0
to
COMn
COMS
Ver 1.0
Part No.
COM
TOTAL
33 DUTY
COM0 ~ COM31
32
17 DUTY
COM0 ~ COM15
16
Through a combination of the contents of the scan data and with the FR
signal, a single level is selected from VDD, V1, V4, and V5.
O
O
Scan Data
FR
Output Voltage
H
H
V5
H
L
VDD
L
H
V1
L
L
V4
Power save
----
VDD
These are the COM output terminals for the indicator. Both terminals output
the same signal.
Leave these open if they are not used.
11/60
2
2003/07/21
ST7533
DESCRIPTION OF FUNCTIONS
The MPU Interface
Selecting the Interface Type
With the ST7533 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 P/ S 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
P/S
/CS1
CS2
A0
/RD
/WR
C86
D7
D6
D5~D0
H: Parallel Input
/CS1
CS2
A0
/RD
/WR
C86
D7
D6
D5~D0
—
—
—
SI
SCL
(HZ)
L: Serial Input
/CS1
CS2
A0
“—” indicates fixed to either “H” or to “L”
The Parallel Interface
When the parallel interface has been selected (P/S =“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
(P/S=H)
/CS1
CS2
A0
/RD
/WR
D7~D0
H: 6800 Series
/CS1
CS2
A0
E
R/W
D7~D0
L: 8080 Series
/CS1
CS2
A0
/RD
/WR
D7~D0
C86
Moreover, data bus signals are recognized by a combination
of A0, /RD (E), /WR (R/W) signals, as shown in Table 3.
Table 3
Ver 1.0
Shared
6800 Series
8080 Series
A0
R/W
/RD
/WR
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)
12/60
Function
2003/07/21
ST7533
The Serial Interface
When the serial interface has been selected (P/S = “L”) then
when the chip is in active state (/CS1 = “L” and CS2 = “H”)
the serial data input (SI) and the serial clock input (SCL) 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.
CS1
CS2
SI
D7
D6
D5
D4
D3
D2
D1
D0
D7
D6
D5
D4
D3
D2
SCL
1
2
3
4
5
6
7
8
9
10
11
12
13
14
A0
Figure 1
* 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.
The Chip Select
The ST7533 have two chip select terminals: /CS1 and CS2.
The MPU interface or the serial interface is
enabled only when /CS1 = “L” and CS2 = “H”.
When the chip select is inactive, D0 to D7 enter a high
impedance state, and the A0, /RD, and /WR inputs are
inactive. When the serial interface is selected, the shift
register and the counter are reset.
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 ST7533. Wait time may not be considered.
And, in the ST7533, 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 display data RAM,
Ver 1.0
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 2.
13/60
2003/07/21
ST7533
The Busy Flag
When the busy flag is “1” it indicates that the ST7533 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.
MPU
Writing
WR
Internal Timing
DATA
N
N+1
N+2
N
BUS Holder
N+1
N+3
N+2
N+3
Write Signal
Reading
MPU
WR
RD
DATA
N
N
n
n+1
Internal Timing
Address Preset
Read Signal
Column Address
Preset N
Bus Holder
N
Address Set
#n
Increment N+1
n
Dummy
Read
N+2
n+1
Data Read #n
n+2
Data Read
#n+1
Figure 2
Ver 1.0
14/60
2003/07/21
ST7533
Display Data RAM
The display data RAM stores the dot data for the LCD. It has
a 33 (4 page x 8 bit +1) x 96 bit structure.
as is shown in Figure 3, 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 ST7533 are used, thus and display structures
can be created easily and with a high degree of freedom.
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 3
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, and only display data D0 is used.
(see Figure 4)
The Column Addresses
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 5FH. Because the column
address is independent of the page address, when moving,
for example, from page 0 column 5FH to page 1 column 00H,
it is necessary to respecify 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
SEG Output
ADC
(D0) “0”
(D0) “1”
SEG0
SEG 95
0 (H) → Column Address →
5F(H)
5F(H) ← Column Address ←
0 (H)
The Line Address Circuit
The line address circuit, as shown in Table 4, 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 COM31 output
Ver 1.0
for ST7533 , the detail is shown page.11 The display area is
a 33 line area for the ST7533.
If the line addresses are changed dynamically using the
display start line address set command, screen scrolling,
page swapping, etc. can be performed.
15/60
2003/07/21
ST7533
5B
02 5D
5F
0
04
03 5C
5E
05
01
00
1
S90
S91
S92
S93
S94
S95
ADC
Column
addres
s
59
5A
06
S89
D0 D0
58
07
Regardless of the display
start line address,
1/33duty => 32th line,
1/17duty =>16th line.
LCD
Out
57
08
08
S88
07
57
S8
S87
06
58
COM
Output
COM0
COM1
COM2
COM3
COM4
COM5
COM6
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
COMS
Page 4
S7
0
05
0
59
1
S6
0
Page 3
04
1
5A
1
S5
0
03
0
Page 2
5B
0
S4
1
02
0
5D
0
Page 1
S3
1
01
0
5D
0
S2
0
When the common
output is normal
00H
01H
02H
03H
04H
05H
06H
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
Page 0
00
0
5F
0
5E
0
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
S1
0
Line
Address
Data
S0
Page Address
D3 D2 D1 D0
Figure 4
Ver 1.0
16/60
2003/07/21
ST7533
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 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.
The Oscillator Circuit
This is a CR-type oscillator that produces the display clock.
The oscillator circuit is only enabled when M/S= “H” and CLS
= “H”.
When CLS = “L” the oscillation stops, and the external
clock is input through the CL 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
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 5, for the liquid crystal drive circuit.
Two-frame alternating current drive waveform
32
33
1
2
3
4
5
6
28
29
30
31
32
33
1
2
3
4
5
6
CL
FR
VDD
V1
COM0
V4
V5
VDD
V1
COM1
V4
V5
RAM
Data
VDD
V2
SEGn
V3
V5
Figure 5
Ver 1.0
17/60
2003/07/21
ST7533
The Common Output Status Select Circuit
In the ST7533 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
Normal
Reverse
Duty
1/33
1/17
COM Scan Direction
1/33 DUTY
1/17 DUTY
COM0 → COM31 COM0 → COM15
COM31 → COM0 COM15 → COM0
com[0:15] Common output pins com[16:31]
Com
dir 0 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 coms
0
com[0:7]
com[8:15]
com[16:23]
com[23:31]
coms
1
com[31:23]
com[23:16]
com[15:8]
com[7:0]
coms
0
com[0:7]
1
com[15:8]
reserve
reserve
com[8:15]
coms
com[7:0]
coms
The LCD Driver Circuits
These are a 129-channel, that generate four voltage levels
for driving the LCD . The combination of the display data, the
COM scan signal, and the FR signal produces the liquid
Ver 1.0
crystal drive voltage output.
Figure-6 shows examples of the SEG and COM output
wave form.
18/60
2003/07/21
ST7533
VDD
VSS
VDD
V1
V2
V3
V4
V5
VDD
V1
V2
V3
V4
V5
VDD
V1
V2
V3
V4
V5
VDD
V1
V2
V3
V4
V5
VDD
V1
V2
V3
V4
V5
V5
V4
V3
V2
V1
VDD
-V1
-V2
-V3
-V4
-V5
V5
V4
V3
V2
V1
VDD
-V1
-V2
-V3
-V4
-V5
FR
COM0
COM1
COM0
COM2
COM3
COM4
COM5
COM6
COM1
COM7
COM8
COM9
COM2
COM10
COM11
COM12
COM13
COM14
SEG0
SEG 0
1
2
3
4
SEG1
COM0 to
SET0
COM0 to
SET1
Figure 6
Ver 1.0
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ST7533
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
Status
“1”
“0”
function
D2
D1
D0
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
The Control Details of Each Bit of the Power Control Set Command
Table 8
Use Settings
D2
D1 D0
Voltage Voltage Voltage
booster regulator follower
External
voltage
input
Step-up
voltage
VSS2
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, VSS2
Open
Only the V/F circuit is used
0
0
1
OFF
OFF
ON
V5, VSS2
Open
Only the external power supply is used
0
0
0
OFF
OFF
OFF
V1 to V5
Open
Reference Combinations
* The “step-up system terminals” refer CAP1+, CAP1–, CAP2+, CAP2–, and CAP3–.
* While other combinations, not shown above, are also possible, these combinations are not recommended
because they have no practical use.
The Step-up Voltage Circuits
Using the step-up voltage circuits equipped within the ST7533 chips it is possible to product a 2X,3X or 4X step-up of the
VDD – VSS2 voltage levels.
4X step-up: Connect capacitor C1 between CAP1+ and CAP1–, between CAP2+ and CAP2–, between CAP1+ and CAP3–,
and between VSS2 and VOUT, to produce a voltage level in the negative direction at the VOUT terminal that is
4 times the voltage level between VDD and VSS2.
3X step-up: Connect capacitor C1 between CAP1+ and CAP1–, between CAP2+ and CAP2– and between VSS2 and VOUT,
and short and shor between CAP3– and VOUT to produce a voltage level in the negative direction at the VOUT
terminal that is 3 times the voltage difference between VDD and VSS2.
2X step-up: Connect capacitor C1 between CAP1+ and CAP1–, and between VSS2 and VOUT, leave CAP2+ open, and short
between CAP2–, CAP3– and VOUT to produce a voltage in the negative direction at the VOUT terminal that Is twice
the voltage between VDD and VSS2.
The step-up voltage relationships are shown in Figure 7
Ver 1.0
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ST7533
VSS2
VSS2
VSS2
C1
C1
C1
VOUT
VOUT
VOUT
CAP3-
CAP3-
CAP3-
CAP1CAP2C1
CAP1+
C1
CAP1-
CAP1-
CAP2-
CAP2-
ST7533
CAP1+
C1
ST7533
CAP1+
C1
ST7533
C1
C1
CAP2+
4x step-up voltage circuit
VDD=0V
CAP2+
3x step-up voltage circuit
VDD=0V
VSS2=-3V
VOUT=4xV SS2=-12V
VSS2=-3V
VOUT=3xV SS2=-9V
3x step-up voltage relationships
OPEN
CAP2+
2x step-up voltage circuit
VDD=0V
VSS2=-3V
VOUT=2xV SS2=-6V
2x step-up voltage relationships
4x step-up voltage relationships
Figure 7
* The VSS2 voltage range must be set so that the VOUT terminal voltage does not exceed the absolute maximum rated value.
The Voltage Regulator Circuit
The step-up voltage generated at VOUT outputs the LCD
driver voltage V5 through the voltage regulator circuit.
Because the ST7533 chips have an internal high-accuracy
fixed voltage power supply with a 64-level electronic volume
Ver 1.0
function and internal resistors for the V5 voltage regulator,
systems can be constructed without having to include
high-accuracy voltage regulator circuit components.
(VREG thermal gradients approximate -0.15%/°C)
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ST7533
The Voltage Regulator Circuit
The step-up voltage generated at VOUT outputs the LCD
driver voltage V5 through the voltage regulator circuit.
Because the ST7533 chips have an internal high-accuracy
fixed voltage power supply with a 64-level electronic volume
function and internal resistors for the V5 voltage regulator,
systems can be constructed without having to include
high-accuracy voltage regulator circuit components.
(VREG thermal gradients approximate -0.15%/°C)
(A) When the V5 Voltage Regulator Internal Resistors Are Used
Through the use of the V5 voltage regulator internal resistors
and the electronic volume function the liquid crystal power
supply voltage V5 can be controlled by commands alone
(without adding any external resistors), making it possible to
adjust the liquid crystal display brightness. The V5 voltage
can be calculated using equation A-1 over the range where
| V5 | < | VOUT |.
V
( Rb
Ra )
α
Rb
=(1 +
1V
)
(
162 )
Ra
α
[∵ V = ( 1 - 162
) V ]
V5 = 1 +
EV
REG
EV
REG
VDD
VEV(constant voltage supply+electronic volume)
Internal Ra
V5
Internal Rb
Figure 8
Ver 1.0
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ST7533
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.
ST7533
Equipment Type
Thermal Gradient
VREG
–0.15 %/°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 register. Table 10 shows the value for α depending on the electronic volume register settings.
Rb/Ra is the V5 voltage regulator internal resistor ratio, and can be set to 8 different levels through the V5 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 V5 voltage regulator internal resistor ratio register.
Table 10
D5
0
0
0
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
:
:
1
1
1
1
1
1
1
1
1
V5 voltage regulator internal resistance ratio register value and (1 + Rb/Ra) ratio (Reference value)
Table 11
Register
ST7533
D2 D1 D0
(1) –0.15 %/°C
0
0
0
0
1
1
1
1
0
0
1
1
0
0
1
1
3.0
3.5
4.0
4.5
5.0
5.5
6.0
6.5
0
1
0
1
0
1
0
1
Figures 9, 10 show V5 voltage measured by values of the internal resistance ratio resistor for V5 voltage adjustment and electric
volume resister for each temperature grade model.
Ver 1.0
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ST7533
V5
UNIT:V
Ta = 25 °C and booster off ,regulator,follower on VSS=-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
V5 voltage regulator
internal resistor ratio set
D2,D1,D0
Electronic volume registered
D5 ~ D0
1FH
3FH
Figure 9 : (1) For ST7533 the Thermal Gradient = -0.15%/°C
The V5 voltage as a function of the V5 voltage regulator internal resistor ratio register and the electronic volume register.
Setup example: When selecting Ta = 25°C and V5 = –7V for an ST7533 on which Temperature gradient = –0.15%/°C.
Using Figure 9 and the equation A-1, the following setup is enabled.
At this time, the variable range and the notch width of the V5 voltage is, as shown Table 13, as dependent on the electronic
volume.
Table 12
Register
D5 D4 D3 D2 D1 D0
— — — 0 1 0
Contents
For V5 voltage regulator
Electronic Volume
1
0
0
1
0
1
Table 13
Ver 1.0
V5
Min
Typ
Max
Units
Variable Range
Notch width
–8.4 (63 levels)
–7.0 (central value)
51
–5.1 (0 level)
[V]
[mV]
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ST7533
(B) When an External Resistance is Used (The V5 Voltage Regulator Internal Resistors Are Not Used) (1)
The liquid crystal power supply voltage V5 can also be set
without using the V5 voltage regulator internal resistors (IRS
terminal = “L”) by adding resistors Ra’ and Rb’ between VDD
and VR, and between VR and V5, 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 V5
through commands.
In the range where | V5 | < | VOUT |, the V5 voltage can be
calculated using equation B-1 based on the external
resistances Ra’ and Rb’.
V
( Rb'
Ra' )
Rb'
α
=(1 +
1V
)
(
Ra'
162 )
α
[∵ V = ( 1 - 162
) V ]
V5 = 1 +
EV
REG
EV
REG
VDD
VEV(fixed voltage power supply+electronic volume)
External
resistor Ra'
V5
External
resistor Rb'
Figure 11
Setup example: When selecting Ta = 25°C and V5 = –7 V for
ST7533 the temperature gradient = –0.15%/°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,
α
1( Rb'
Ra' ) (
162 )
31
Rb'
-7V = ( 1 +
1)
(
162 )
Ra'
V5 = 1 +
Rb'
= 3.12
Ra'
Ra' = 340kΩ
VREG
Rb' = 1060kΩ
(-2.1)
At this time, the V5 voltage variable range and notch
width, based on the electron volume function, is as
given in Table 14.
Moreover, when the value of the current running through
Ra’ and Rb’ is set to 5 uA,
Consequently, by equations B-2 and B-3,
Table 14
Ver 1.0
V5
Min
Typ
Max
Units
Variable Range
Notch width
–8.6 (63 levels)
–7.0 (central value)
52
–5.3 (0 level)
[V]
[mV]
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ST7533
(C) When External Resistors are Used (The V5 Voltage Regulator Internal Resistors 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 V5. In this case, the use of the electronic volume
function makes it possible to control the liquid crystal power
supply voltage V 5 by commands to adjust the liquid
crystal display brightness.
In the range where | V5 | < | VOUT | the V5 voltage can be
calculated by equation C-1 below based on the R1 and R2
(variable resistor) and R 3 settings, where R 2 can
be subjected to fine adjustments (Δ R2).
V
( R3+R2-ΔR2
R1+ΔR2 )
R3+R2-ΔR2
α
=(1 +
1R1+ΔR2 ) (
162 )
α
[∵ V = ( 1 - 162
) V ]
V5 = 1 +
EV
EV
VREG
REG
VDD
VEV(fixed voltage power supply+electronic volume)
External
resistor R1
Ra'
ΔR2
External
resistor R2
V5
VR
External
resistor R3
Rb'
Figure 12
Setup example: When selecting Ta = 25°C and V5 = –5 to –9
V (using R2) for an ST7533 the temperature gradient
= –0.15%/°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 Δ
R2 = 0 Ω, in order to make V5 = –9 V,
R3+R2
-9V= 1 +
R1
(
) (
31
1162
)
With this, according to equation C-2, C-3 and C-4,
R1 = 264kΩ
R2 = 211kΩ
R3 = 925kΩ
(-2.1)
The V5 voltage variable range and notch width based on the
electron volume function is as shown in Table 15.
When ΔR2 = R2, in order to make V = –5 V,
(
-5V = 1 +
R3
R1+R2
31
) ( 1 - 162
)
(-2.1)
When the current flowing VDD and V5 is set to 5 uA,
Table 15
Ver 1.0
V5
Min
Typ
Max
Units
Variable Range
Notch width
–8.7 (63 levels)
–7.0 (central value)
53
–5.3 (0 level)
[V]
[mV]
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ST7533
* When the V5 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 V5 voltage regulator internal resistors are not used (i.e. the IRS terminal = “L”).
When the V5 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 V5 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.
High Power Mode
The power supply circuit equipped in the ST7533 chips has
very low power consumption (normal mode: HPM = “H”).
However, for LCDs or panels with large loads, this low-power
power supply may cause display quality to degrade. When
this occurs, setting the HPM terminal to “L” (high power mode)
can improve the quality of the display. We recommend that
the display be checked on actual equipment to determine
whether or not to use this mode. Moreover, if the
improvement to the display is inadequate even after high
power mode has been set, then it is necessary to add a liquid
c r y s t a l
d r i v e
p o w e r
s u p p l y
externally.
The Internal Power Supply Shutdown Command Sequence
The sequence shown in Figure 13 is recommended for
shutting down the internal power supply, first placing the
Sequence
Step1
Step2
End
power supply in power saver mode and then turning
the power supply OFF.
Details
(Command, status)
Display OFF
Display all points ON
Command address
D7 D6 D5 D4 D3 D2 D1 D0
1 0 1 0 1 1 1 0
Power saver
1
commands
0 1
0 0
1 0
Internal power supply OFF
1
(compound)
Figure 13
The temperature grade of the Internal Power Supply for ST7533 (-0.15%/°C) :
Ta=-40°C , V5=9.40V
9.40V
Ta=25°C , V5=8.46V
8.46V
Ta=85°C , V5=7.60V
7.60V
V5
0V
-40°C
-20°C
0°C
25°C
50°C
85°C
Ta
Figure 14
Ver 1.0
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ST7533
Reference Circuit Examples
Figure 15 shows reference circuit examples.
1. When used all of the step-up circuit, voltage regulating circuit and V/F circuit
(1) When the voltage regulator internal resistor
(2) When the voltage regulator internal resistor
is used.
is not used.
(Example where VSS2 = VSS, with 4x step-up)
(Example where VSS2 = VSS, with 4x step-up)
VDD
VDD
IRS
M/S
IRS
VSS2
VSS
M/S
VSS2
C1
VSS
C1
VOUT
VOUT
CAP4-
CAP3C1
CAP3-
CAP4-
CAP1+
CAP5-
C1
CAP5-
CAP1+
C1
C1
CAP1-
CAP1-
CAP2+
CAP2+
C1
C1
CAP2-
CAP2-
VR
V5
VR
R2
VDD
VDD
R1
VDD
C2
VDD
C2
V1
C2
C2
V2
C2
C2
V3
C2
C2
V4
C2
ST7533
R3
ST7533
V5
C2
V5
V1
V2
V3
V4
V5
2. When the voltage regulator circuit and V/F circuit alone are used
(1) When the V 5 voltage regulator internal resistor
(2) When the V 5 voltage regulator internal resistor
is not used.
is used.
VDD
IRS
VDD
M/S
IRS
VSS2
VSS2
VSS
VSS
VOUT
External
power
supply
CAP4-
CAP1+
CAP5-
External
power
supply
CAP4-
CAP1+
CAP5-
CAP1-
CAP2+
CAP2+
CAP2-
CAP2V5
VR
R1
ST7533
ST7533
VR
VDD
VDD
C2
C2
C2
C2
C2
Ver 1.0
CAP3-
CAP1-
V5
R2
VOUT
CAP3-
R3
VDD
M/S
VDD
C2
V1
C2
V2
C2
V3
C2
V4
C2
V5
28/60
V1
V2
V3
V4
V5
2003/07/21
ST7533
3. When the V/F circuit alone is used
4. When the built-in power is not used
VDD
VDD
VSS
IRS
M/S
IRS
VSS2
M/S
VSS2
VSS
VOUT
CAP4-
CAP3-
CAP4-
CAP1+
CAP5-
CAP1+
CAP5-
CAP1-
CAP1-
CAP2+
CAP2+
CAP2-
CAP2-
V5
VR
V5
VR
VDD
ST7533
ST7533
External
power
supply
VOUT
CAP3-
VDD
C2
C2
C2
C2
C2
VDD
VDD
V1
V1
V2
V2
External power supply
V3
V3
V4
V4
V5
V5
5. When the built-in power circuit is used to drive a liquid
crystal panel heavily loaded with AC or DC, it is
recommended to connect an external resistor to stabilize
potentials of V1, V2, V3 and V4 which are output from the
built-in voltage follower.
Examples of shared reference settings When V5 can vary
between –8 and 12 V
VDD,V0
R4
R4
C2
Item
Set value
units
c1
c2
1.0 to 4.7
0.1 to 4.7
uF
uF
V1
V3
C1 and C2 are determined by the size of
the LCD being driven
ST7533
V2
V4
R4
R4
V5
crystal display and the drive waveform.
Reference set value R4: 100KΩ ~ 1MΩ It is recommended
to set an optimum resistance value R4 taking the liquid
Figure 15
* 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 (V1 to V5). Note that all C2 capacitors must have the same capacitance value.
• Next turn all the power supplies ON and determine C1.
Ver 1.0
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ST7533
The Reset Circuit
When the /RES 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:
1/33 DUTY = 1/6 bias
1/17 DUTY = 1/5 bias
7. All-indicator lamps-on OFF (All-indicator lamps ON/OFF
command D0 = “L”)
8. Power saving clear
9. V 5 voltage regulator internal resistors Ra and Rb
separation
10. Output conditions of SEG and COM terminals
SEG=VDD , COM=VDD
11. Read modify write OFF
12. Static indicator OFF Static indicator register : (D1, D2) =
(0, 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. V5 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
Ver 1.0
On the other hand, when the reset command is used, the
above default settings from 11 to 19 are only executed.
When the power is turned on, the IC internal state becomes
unstable, and it is necessary to initialize it using the /RES
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
ST7533,it is necessary that /RES is “H” when the external
liquid crystal power supply is turned on. This IC has the
function to discharge V5 when /RES is “L,” and the external
power supply short-circuits to V DD when /RES is “L.”
While /RES is “L,” the oscillator and the display timing
generator stop, and the CL, FR, FRS and /DOF terminals are
fixed to “H.” The terminals D0 to D7 are not affected. The
VDD level is output from the SEG and COM output terminals.
This means that an internal resistor is connected between
VDD and V5.
When the internal liquid crystal power supply circuit is not
used on other models of ST7533 series, it is necessary that
/RES is “L” when the external liquid crystal power supply is
turned on.
While /RES is “L,” the oscillator works but the display timing
generator stops, and the CL, FR, FRS and /DOF terminals
are fixed to “H.” The terminals D0 to D7 are not affected.
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ST7533
COMMANDS
The ST7533 identify the data bus signals by a combination of A0, /RD (E), /WR(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 WR 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
/RD (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.
A0
0
E
R/W
RD
1
WR
0
D7
D6
D5
D4
D3
D2
D1
1
0
1
0
1
1
1
D0
Setting
1
Display ON
0
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 4. For further details
see the explanation of this function in “The Line Address Circuit”.
A0
0
E
R/W
RD
1
WR
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
1
0
1
0
1
1
1
1
1
1
1
1
0
1
0
1
2
↓
30
31
↓
Page Address Set
This command specifies the page address corresponding to the low address when the MPU accesses the display data RAM
(see Figure 4). 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.
A0
0
Ver 1.0
E
R/W
RD
1
WR
0
D7
D6
D5
D4
D3
D2
D1
D0
Page address
1
0
1
1
0
0
0
0
0
1
0
0
1
1
0
0
1
0
1
0
0
1
2
3
4
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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 from/write
to the display data. The column address increment is topped at 5FH. This does not change the page address continuously. See
the function explanation in “The Column Address Circuit,” for details.
E
A0
0
High bits →
Low bits →
R/W
RD WR
1
0
D7 D6 D5 D4 D3 D2 D1 D0 A7 A6 A5 A4 A3 A2 A1 A0
0
0
0
1 A7 A6
0 A3 A2
A5 A4 0
A1 A0 0
0
0
0
0
0
0
0
0
0
1
1
0
0
0
0
0
0
0
0
↓
1 1
1 1
0
0
0
0
0
1
0
1
0
1
1
1
1
0
1
Column
address
0
1
2
↓
94
95
Status Read
E
R/W
A0
RD
WR
0
0
1
BUSY
D7
D6
BUSY
ADC
D5
D4
ON/OFF RESET
D3 D2 D1 D0
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 is no need to check
for BUSY conditions.
This shows the relationship between the column address and the segment driver.
0: Normal (column address n ↔ SEG n)
1: Reverse (column address 95-n ↔ SEG n)
(The ADC command switches the polarity.)
ADC
ON/OFF
RESET
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 /RES signal or because of a
reset command.
0: Operating state
1: Reset in progress
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.
A0
1
Ver 1.0
E
R/W
RD
WR
1
0
D7 D6 D5 D4 D3 D2 D1 D0
Write data
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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.
A0
1
E
R/W
RD
WR
0
1
D7 D6 D5 D4 D3 D2 D1 D0
Read data
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 (Figure 4)
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
RD
1
WR
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
RD
1
WR
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 Points 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
RD
1
WR
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
When the display is in an OFF mode, executing the display all points ON command will place the display in power save mode.
For details, see the Power Save section.
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LCD Bias Set
This command selects the voltage bias ratio required for the liquid crystal display.
A0
E
R/W
RD
WR
0
1
Select Status
0
D7
D6
D5
D4
D3
D2
D1
D0
1/33duty
1/17duty
1
0
1
0
0
0
1
0
1/6 bias
1/6 bias
1
1/5 bias
1/5 bias
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.
A0
0
E
R/W
RD
WR
1
0
D7 D6 D5 D4 D3 D2 D1 D0
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 24 Command Sequence For read modify write
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Return
Column address
N
N+2
N+1
N+3
N+m
Read-modify-write mode set
N
End
Figure 25
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.
A0
0
E
R/W
RD
WR
1
0
D7 D6 D5 D4 D3 D2 D1 D0
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 V5 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.
A0
0
E
R/W
RD
WR
1
0
D7 D6 D5 D4 D3 D2 D1 D0
1
1
1
0
0
0
1
0
The initialization when the power supply is applied must be done through applying a reset signal to the /RES terminal. The reset
command must not be used instead.
Common Output Mode Select
This command can select the scan direction of the COM output terminal. For details, see the function explanation in
“Common Output Mode Select Circuit.”
Selected Mode
E R/W
A0 RD WR
0
1
0
D7 D6 D5 D4 D3 D2 D1 D0
1
1
0
0
0
1
*
*
*
1/33duty
1/17duty
Normal COM0→COM31 COM0→COM15
Reverse COM31→COM0 COM15→COM0
* Disabled bit
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Power Controller Set
This command sets the power supply circuit functions. See the function explanation in “The Power Supply Circuit,” for details
A0
E
R/W
RD
WR
D7 D6 D5 D4 D3 D2 D1 D0
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
Selected Mode
0
1
V5 Voltage Regulator Internal Resistor Ratio Set
This command sets the V5 voltage regulator internal resistor ratio. For details, see the function explanation is “The Voltage
Regulator circuit " and table 11 .
A0
E
R/W
RD
WR
D7 D6 D5 D4 D3 D2 D1 D0
0
0
1
0
1
0
0
0
0
0
0
1
1
0
0
1
↓
1
1
Rb/Ra Ratio
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 V5
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.
A0
0
Ver 1.0
E
R/W
RD
WR
1
0
D7 D6 D5 D4 D3 D2 D1 D0
1
0
0
0
0
0
0
1
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Electronic Volume Register Set
By using this command to set six bits of data to the electronic volume register, the liquid crystal drive voltage V5 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.
A0
0
E
R/W
RD
WR
1
0
D7 D6 D5 D4 D3 D2 D1 D0
*
*
*
*
*
*
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
↓
| V5 |
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
electronic volume mode set
electronic volume register set
Electronic volume mode clear
NO
Set complete ?
YES
Figure 26
Static Indicator (Double Byte Command)
This command controls the static drive system indicator display. The static indicator display is controlled by this command only,
and is independent of other display control commands.
This is used when one of the static indicator liquid crystal drive electrodes is connected to the FR terminal, and the other is
connected to the FRS terminal. A different pattern is recommended for the static indicator electrodes than for the dynamic drive
electrodes. If the pattern is too close, it can result in deterioration of the liquid crystal and of the electrodes.
The static indicator ON command is a double byte command paired with the static indicator register set command, and thus
one must execute one after the other. (The static indicator OFF command is a single byte command.)
Static Indicator ON/OFF
When the static indicator ON command is entered, the static indicator register set command is enabled. Once the static
indicator ON command has been entered, no other command aside from the static indicator register set command can be used.
T h i s m o d e is clea red whe n dat a is se t in the r egist er by th e st atic ind ic at or reg is te r set com mand .
A0
0
Ver 1.0
E
R/W
RD
WR
1
0
D7 D6 D5 D4 D3 D2 D1 D0
1
0
1
0
1
1
0
Static Indicator
0
1
OFF
ON
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Static Indicator Register Set
This command sets two bits of data into the static indicator register, and is used to set the static indicator into a blinking mode.
A0
E
R/W
RD
WR
D7 D6 D5 D4 D3 D2 D1 D0
*
0
1
*
*
*
*
*
0
0
0
1
1
0
1
0
1
Indicator Display State
OFF
ON (blinking at approximately one second intervals)
ON (blinking at approximately 0.5 second intervals)
ON (constantly on)
* Disabled bit (set “0”)
Static Indicator Register Set Sequence
Static indicator mode set
Static indicator register set
Static indicator mode clear
NO
Set complete ?
YES
Figure 27
Power Save (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 28 for power save off sequence.
Static indicator ON
Static indicator OFF
Display OFF
Display OFF
Display all point ON
Display all point ON
Standby mode
Sleep mode
Power save OFF
( Display all point OFF )
Power save OFF
Display all point OFF
Static indicator ON (2 bytes)
Standby mode cancel
Sleep mode cancel
Figure 28
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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 VDD 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 VDD 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. The ST7533 series chips have a liquid
crystal display blanking control terminal /DOF. This terminal enters an “L” state when the power saver mode is launched.
Using the output of /DOF, it is possible to stop the function of an external power supply circuit.
NOP
Non-OPeration Command
A0
0
E
R/W
RD
WR
1
0
D7 D6 D5 D4 D3 D2 D1 D0
1
1
1
0
0
0
1
1
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 /RES input by the reset command or by using an NOP.
A0
0
E
R/W
RD
WR
1
0
D7 D6 D5 D4 D3 D2 D1 D0
1
1
1
1
1
1
*
*
* Inactive bit
Note: The ST7533 maintain their operating modes until something happens to change them. Consequently, excessive external
noise, etc., can change the internal modes of the ST7533 . 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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Table 16: Table of ST7533 Commands
(Note) *: disabled data
Command Code
Command
Function
A0 RD WR
D7 D6 D5 D4 D3 D2 D1 D0
1 0 1 0 1 1 1 0
1
LCD display ON/OFF
0: OFF, 1: ON
Sets the display RAM display start
line address
Sets the display RAM page
address
Sets the most significant 4 bits of
the display RAM column address.
Sets the least significant 4 bits of
the display RAM column address.
(1) Display ON/OFF
0
1
0
(2) Display start line set
0
1
0
0
1
Display start address
(3) Page address set
0
1
0
1
0
1
1
(4) Column address set
upper bit
Column address set
lower bit
0
1
0
0
0
0
0
1
0
0
0
0
1 Most significant
column address
0 Least significant
column address
(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
Status
Page address
0
0
0
0
Reads the status data
Sets the display RAM address
SEG output correspondence
0: normal, 1: reverse
Sets the LCD display normal/
reverse
0: normal, 1: reverse
Display all points
0: normal display
1: all points ON
Sets the LCD drive voltage bias
ratio
0: 1/6 bias, 1: 1/5 bias (ST7533)
Column address increment
At write: +1
At read: 0
1
0
1
0
0
0
0
0
1
1
0
1
0
0
1
1
0
1
1
0
1
0
0
1
0
0
1
1
0
1
0
0
0
1
0
1
0
1
1
1
0
0
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
0
1
*
*
*
(16) Power control set
0
1
0
0
0
1
0
1
Operating
mode
Select COM output scan direction
0: normal direction
1: reverse direction
Select internal power supply
operating mode
0
1
0
0
0
1
0
0
Resistor
ratio
Select internal resistor
ratio(Rb/Ra) mode
0
1
0
1
0
0 0 0 0 0 0 1
0 Electronic volume value
1
0
1
0
1
0
0
0
0
(17) V5 voltage regulator
internal resistor ratio
set
(18) Electronic volume
mode set
Electronic volume
register set
(19) Static indicator
ON/OFF
Static indicator
register set
0
0
1
1
0
0
0
0: OFF, 1: ON
1
0 0 Mode Set the flashing mode
Display OFF and display all
points ON compound command
(20) Power saver
(21) NOP
(22) Test
Ver 1.0
Set the V5 output voltage
electronic volume register
0
0
1
1
0
0
1
1
1
1
1
1
0
1
40/60
0
*
0
*
1
*
1
Command for non-operation
*
Command for IC test. Do not
use this command
2003/07/21
ST7533
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 (V1 ~ V5) and the VDD 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 /RES pin = “L”
When the power is stabilized
Release the reset state. (/RES 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 radio
for regulation of the V5 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 radio for regulation of
the V5 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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2. When the built-in power is not being used immediately after turning on the power:
Turn ON the VDD-VSS power keeping the
/RES pin = “L”.
When the power is stabilized
Release the reset state. (/RES pin = “H”)
Waiting reset circuit stabilized (<1ms)
Initialized state (Default) *1
Power saver START
(multiple commands) *8
Arrange to start the
power saver 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 radio
for regulation of the V5 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 V5
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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(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)
(20) Power save *15
Reset active (RES pin = “L”)
VDD – VSS power OFF
Set the time ( t L ) from reset
active to turning off the VDD VSS power (VDD - VSS = 1.8V)
longer than the time (tH) when
the potential of V5 ~ V1
becomes below the threshold
voltage (approximately 1V) of
the LCD panel. For tH, refer to
the <Reference Data> of this
event. When t H is too long,
insert a resistor between V 5
and VDD to reduce it.
Notes: Reference items
*14: The logic circuit of this IC’s power supply VDD - VSS controls the driver of the LCD power supply VDD - V5. So, if the
power supply VDD - VSS is cut off when the LCD power supply VDD - V5 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 V5 ~ V1 has become below the threshold
voltage of the LCD panel, and then turn off this IC’s power supply (VDD - VSS). 6. Description of Function, 6.7 Power
Circuit
*15: After inputting the power save command, be sure to reset the function using the /RES terminal until the power
supply VDD - VSS is turned off. 7. Command Description (20) Power Save
*16: After inputting the power save command, do not reset the function using the /RES terminal until the power supply
VDD - VSS is turned off. 7. Command Description (20) Power Save
Ver 1.0
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ST7533
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 (VDD - V5) 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 V5 ~ V1) and the driver’s discharging capacity.
Power Off
Reset
Power save
tL
VDD
1.8V
RES
VDD
SEG
Since the power (V DD-VSS) is cut off,the
output comes not to be fixed.
VDD
COM
V1
V2
V3
V4
V5
Ver 1.0
About 1V:below Vth of the LCD Panel
tH
44/60
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ST7533
<Turning the power (VDD - VSS) off : When command control is not possible.>
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 V5 to V1) and the driver’s discharging
capacity.
Power Off
Reset
tL
1.8V
VDD
RES
VDD
SEG
Since the power (VDD-VSS) is cut off,the
output comes not be fixed.
VDD
COM
About 1V:below Vth of the LCD Panel
V1
V2
V3
V4
V5
tH
<Reference Data>
V5 voltage falling (discharge) time (tH) after the process of operation → power save → reset.
V5 voltage falling (discharge) time (tH) after the process of operation → reset.
100
V5 voltage falling time (mSec)
VDD-VSS(V)
1.8
2.4
50
3.0
4.0
5.0
0
0.5
1.0
C2 : V1 to V5 capacity (uF)
Figure 31
Ver 1.0
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ST7533
ABSOLUTE MAXIMUM RATINGS
Unless otherwise noted, VSS = 0V
Table 17
Parameter
Symbol
Conditions
Unit
Power Supply Voltage
VDD
–0.3 ~ +5.0
V
Power supply voltage (VDD standard)
VSS2
–4.0 ~ -1.8
V
Power supply voltage (VDD standard)
V5, VOUT
–16.0 ~ +0.3
V
Power supply voltage (VDD standard)
V1, V2, V3, V4
V5 to +0.3
V
Input voltage
VIN
–0.3 to VDD + 0.3
V
Output voltage
VO
–0.3 to VDD + 0.3
V
TOPR
–40 to +85
°C
TSTR
–55 to +125
°C
Operating temperature
Storage temperature
Bare chip
VCC
VDD
GND
VSS
VDD
VSS2,V1 to V4
V5.,VOUT
System (MPU) side
ST7533 chip side
Figure 30
Notes and Cautions
1. The VSS2, V1 to V5 and VOUT are relative to the VDD = 0V reference.
2. Insure that the voltage levels of V1, V2, V3, and V4 are always such that VDD ≧ V1 ≧ V2 ≧ V3 ≧ V4 ≧ V5.
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.
Ver 1.0
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ST7533
DC CHARACTERISTICS
Unless otherwise specified, VSS = 0 V, VDD = 3.0 V ± 10%, Ta = –40 to 85°C
Table 18
Item
Symbol
Operating Voltage (1)
Vss
Operating Voltage (2)
VSS2
Operating Voltage (3)
VSS2
Condition
(Relative to VDD)
(Relative to VDD)
Min.
Rating
Typ.
Max.
-3.3
—
–3.3
Units
Applicable
Pin
-1.8
V
Vss*1
—
–1.8
V
VSS2
–13.0
—
–4.0
0.4 x V5
—
VDD
V5
—
0.6 x V5
V5 *2
V
V1, V2
V3, V4
High-level Input Voltage
VIHC
0.8 x VDD
—
VDD
V
*3
Low-level Input Voltage
VILC
VSS
—
0.2 x VDD
V
*3
High-level Output Voltage
VOHC IOH = –0.5 Ma
0.8 x VDD
—
VDD
V
*4
Low-level Output Voltage
VOLC IOL = 0.5 mA
VSS
—
0.2 x VDD
V
*4
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
Liquid Crystal Driver ON
Resistance
Ta
= V5 = –13.0 V
25°C
(Relative V5 = –8.0 V
To VDD)
—
2.0
3.5
RON
—
3.2
5.4
KΩ
SEGn
COMn *7
Static Consumption Current
ISSQ
—
0.01
2
μA
VSS, VSS2
Output Leakage Current
I5Q
—
0.01
10
μA
V5
Input Terminal Capacitance
CIN
—
5.0
8.0
pF
17
24
27
kHz
*8
17
24
27
kHz
CL
Oscillator
Frequency
Ver 1.0
Internal
Oscillator
External
Input
V5 = –13.0 V(Relative To
VDD)
Ta = 25°C , f = 1 MHz
fOSC
1/33 duty , Ta = 25°C
fCL
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ST7533
Table 19
Item
Symbol
Internal Power
Input voltage
VSS2
Supply Step-up output
voltage Circuit
Voltage regulator
Circuit Operating
Voltage
Voltage Follower
Circuit Operating
Voltage
Base Voltage
Condition
Rating
Typ.
Min.
Max.
Units
Applicable
Pin
(Relative To VDD)
–3.3
—
–1.8
V
VSS2
VOUT (Relative To VDD)
–13.0
—
—
V
VOUT
VOUT (Relative To VDD)
–13.0
—
–6.0
V
VOUT
(Relative To VDD)
–13.0
—
–4.0
V
V5 * 9
Ta = 25°C , (Relative To VDD)
–0.15%/°C
–2.07
–2.10
–2.13
V
*10
V5
VRS
• Dynamic Consumption Current : During Display, with the Internal Power Supply OFF Current consumed by total ICs
when an external power supply is used .
Table 20
Rating
Test pattern
Symbol
Condition
Units
Notes
Min.
Typ.
Max.
Display Pattern
OFF
IDD
VDD = 3.0 V,
V5 – VDD = –11.0 V
—
4
12
μA
*11
Display Pattern
Checker
IDD
VDD = 3.0 V,
V5 – VDD = –11.0 V
—
7
21
μA
*11
• Dynamic Consumption Current : During Display, with the Internal Power Supply ON
Table 21
Rating
Test pattern Symbol
Condition
Min.
Typ.
Display
Pattern OFF
IDD
VDD = 3.0 V,
Quad step-up voltage.
V5 – VDD = –11.0 V
Display
Pattern
Checker
IDD
VDD = 3.0 V,
Quad step-up voltage.
V5 – VDD = –11.0 V
Max.
Normal Mode
—
70
110
High-Power Mode
—
90
150
Normal Mode
—
95
130
High-Power Mode
—
130
Units Notes
μA
*12
μA
*12
180
• Consumption Current at Time of Power Saver Mode : VSS = -3.0 V ± 10%
Table 22
Rating
Typ.
0.1
Max.
4
Ta = 25°C
—
5
10
Symbol
Condition
Sleep mode
IDD
IDD
Standby Mode
Ver 1.0
Ta = 25°C
Min.
—
Item
48/60
Units
Notes
μA
2003/07/21
ST7533
• The Relationship Between Oscillator Frequency fOSC, Display Clock Frequency fCL and the Liquid Crystal Frame
Rate Frequency fFR
Table 23
Item
1/33 DUTY
1/17 DUTY
fCL
fFR
Used internal oscillator circuit
fOSC / 8
fOSC / (8*33)
Used external display clock
External input (fCL)
fCL / 264
Used internal oscillator circuit
fOSC / 16
fOSC / (16*17)
Used external display clock
External input (fCL)
fCL / 272
(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 VDD system and the V5 system is. This applies when the external power supply is
being used.
*3 The A0, D0 to D5, D6 (SCL), D7 (SI), RD (E), /WR (R/W), /CS1, CS2, CLS, CL, FR, M/S and
C86, P/S, /DOF, /RES, IRS, and /HPM terminals.
*4 The D0 to D7, FR, FRS, /DOF, and CL terminals.
*5 The A0, /RD (E), /WR (R/W), /CS1, CS2, CLS, M/S, C86, P/S, /RES, IRS, and /HPM terminals.
*6 Applies when the D0 to D5, D6 (SCL), D7 (SI), CL, FR, and /DOF 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 (V 1 , V 2 , V 3 , and V 4 ). 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 V5 voltage regulator circuit regulates within the operating voltage range of the voltage follower.
*10 This is the internal voltage reference supply for the V5 voltage regulator circuit. In the ST7533 , the temperature range
approximately –0.15%/°C.
*11, 12 It indicates the current consumed on ICs alone when the internal oscillator circuit and display are turned on.
The ST7533 is 1/5 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 ST7533 having the VREG temperature gradient is –0.15%/°C when the V5 voltage regulator
internal resistor is used.
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ST7533
TIMING CHARACTERISTICS
System Bus Read/Write Characteristics 1 (For the 8080 Series MPU)
A0
tAW8
tAH8
CS1
(CS2="1")
tCYC8
tCCLR,tCCLW
WR,RD
tCCHR,tCCHW
tDS8
tDH8
D0 to D7
(Write)
tACC8
tOH8
D0 to D7
(Read)
Figure 37
Table 24
Item
Signal
Address hold time
Address setup time
A0
System cycle time
Enable L pulse width (WRITE)
Enable H pulse width (WRITE)
Enable L pulse width (READ)
Enable H pulse width (READ)
WR
RD
WRITE Data setup time
WRITE Data hold time
READ access time
READ Output disable time
Ver 1.0
D0 to D7
Symbol
Condition
(VDD = 3.3V , Ta =25°C)
Rating
Units
Min.
Max.
tAH8
0
—
tAW8
0
—
tCYC8
240
—
tCCLW
80
—
tCCHW
80
—
tCCLR
140
—
tCCHR
80
tDS8
40
—
tDH8
10
—
tACC8
CL = 100 pF
—
70
tOH8
CL = 100 pF
5
50
50/60
ns
2003/07/21
ST7533
Table 25
Item
Signal
Address hold time
Address setup time
A0
System cycle time
Enable L pulse width (WRITE)
Enable H pulse width (WRITE)
Enable L pulse width (READ)
Enable H pulse width (READ)
WR
RD
WRITE Data setup time
WRITE Data hold time
READ access time
D0 to D7
READ Output disable time
Symbol
Condition
(VDD = 2.7 V , Ta = 25°C )
Rating
Units
Min.
Max.
tAH8
0
—
tAW8
0
—
tCYC8
400
—
tCCLW
220
—
tCCHW
180
—
tCCLR
220
—
tCCHR
180
—
tDS8
40
—
tDH8
15
—
tACC8
CL = 100 pF
—
140
tOH8
CL = 100 pF
10
100
ns
Table 26
Item
Signal
Address hold time
Address setup time
A0
System cycle time
Enable L pulse width (WRITE)
Enable H pulse width (WRITE)
Enable L pulse width (READ)
Enable H pulse width (READ)
WR
RD
WRITE Data setup time
WRITE Data hold time
READ access time
READ Output disable time
D0 to D7
Symbol
Condition
(VDD = 1.8V , Ta = 25°C )
Rating
Units
Min.
Max.
tAH8
0
—
tAW8
0
—
tCYC8
640
—
tCCLW
360
—
tCCHW
280
—
tCCLR
360
—
tCCHR
280
tDS8
80
—
tDH8
30
—
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 CS1 being “L” (CS2 = “H”) and WR and RD being at the “L” level.
Ver 1.0
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ST7533
A0
R/W
tAW6
tAH6
CS1
(CS2="1")
tCYC6
tCCLR,tCCLW
E
tCCHR,tCCHW
tDH6
tDS6
D0 to D7
(Write)
tACC6
tOH6
D0 to D7
(Read)
System Bus Read/Write Characteristics 2 (For the 6800 Series MPU)
Figure 38
Table 27
Item
Signal
Address hold time
Address setup time
A0
System cycle time
Enable L pulse width (WRITE)
Enable H pulse width (WRITE)
Enable L pulse width (READ)
Enable H pulse width (READ)
WR
RD
WRITE Data setup time
WRITE Data hold time
READ access time
READ Output disable time
Ver 1.0
D0 to D7
Symbol
Condition
(VDD = 3.3 V , Ta = 25°C )
Rating
Units
Min.
Max.
tAH6
0
—
tAW6
0
—
tCYC6
240
—
tEWLW
80
—
tEWHW
80
—
tEWLR
80
—
tEWHR
140
tDS6
40
—
tDH6
10
—
tACC6
CL = 100 pF
—
70
tOH6
CL = 100 pF
5
50
52/60
ns
2003/07/21
ST7533
Table 28
Item
Signal
Address hold time
Address setup time
A0
System cycle time
Enable L pulse width (WRITE)
Enable H pulse width (WRITE)
Enable L pulse width (READ)
Enable H pulse width (READ)
WR
RD
WRITE Data setup time
WRITE Data hold time
READ access time
D0 to D7
READ Output disable time
Symbol
Condition
(VDD = 2.7V , Ta =25°C )
Rating
Units
Min.
Max.
tAH6
0
—
tAW6
0
—
tCYC6
400
—
tEWLW
220
—
tEWHW
180
—
tEWLR
220
—
tEWHR
180
—
tDS6
40
—
tDH6
15
—
tACC6
CL = 100 pF
—
140
tOH6
CL = 100 pF
10
100
ns
Table 29
Item
Signal
Address hold time
Address setup time
A0
System cycle time
Enable L pulse width (WRITE)
Enable H pulse width (WRITE)
Enable L pulse width (READ)
Enable H pulse width (READ)
WR
RD
WRITE Data setup time
WRITE Data hold time
READ access time
READ Output disable time
D0 to D7
Symbol
Condition
(VDD =1.8V , Ta =25°C )
Rating
Units
Min.
Max.
tAH6
0
—
tAW6
0
—
tCYC6
640
—
tEWLW
360
—
tEWHW
280
—
tEWLR
360
—
tEWHR
280
—
tDS6
80
—
tDH6
30
—
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 CS1 being “L” (CS2 = “H”) and E.
Ver 1.0
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ST7533
The Serial Interface
tCCSS
tCSH
CS1
(CS2="1")
tSAS
tSAH
A0
tSCYC
tSLW
SCL
tSHW
tf
tr
tSDS
tSDH
SI
Figure 39
Table 30
Item
Signal
Serial Clock Period
SCL “H” pulse width
SCL
SCL “L” pulse width
Address setup time
Address hold time
Data setup time
A0
SI
Data hold time
CS-SCL time
CS
CS-SCL time
Symbol
Condition
tSCYC
tSHW
tSLW
tSAS
tSAH
tSDS
tSDH
tCSS
tCSH
(VDD = 3.3V, Ta =25°C )
Rating
Units
Min.
Max.
50
—
25
—
25
—
20
—
10
—
20
—
10
—
20
—
40
—
ns
Table 31
Item
Signal
Serial Clock Period
SCL “H” pulse width
SCL
SCL “L” pulse width
Address setup time
Address hold time
Data setup time
Data hold time
CS-SCL time
CS-SCL time
Ver 1.0
A0
SI
CS
Symbol
tSCYC
tSHW
tSLW
tSAS
tSAH
tSDS
tSDH
tCSS
tCSH
54/60
Condition
(VDD =2.7V , Ta =25°C )
Rating
Units
Min.
Max.
100
—
50
—
50
—
30
—
20
—
30
—
20
—
30
—
60
—
ns
2003/07/21
ST7533
Table 32
Item
Signal
Serial Clock Period
SCL “H” pulse width
SCL
SCL “L” pulse width
Address setup time
Address hold time
Data setup time
Data hold time
CS-SCL time
CS-SCL time
A0
SI
CS
Symbol
TSCYC
TSHW
TSLW
TSAS
TSAH
TSDS
TSDH
TCSS
tCSH
Condition
(VDD = 1.8V , Ta = 25°C )
Rating
Units
Min.
Max.
200
—
80
—
80
—
60
—
30
—
60
—
30
—
40
—
100
—
ns
*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.
Ver 1.0
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ST7533
Reset Timing
tRW
RES
tR
Internal
status
During reset
Reset complete
Figure 41
Table 36
Item
Reset time
Reset “L” pulse width
Signal
RES
Symbol
Condition
tR
tRW
(VDD = 3.3V , Ta = –40 to 85°C )
Rating
Units
Min.
Typ.
Max.
us
—
—
1.0
us
1.0
—
—
Table 37
Item
Reset time
Reset “L” pulse width
Signal
RES
Symbol
Condition
tR
tRW
(VDD = 2.7V , Ta = –40 to 85°C )
Rating
Units
Min.
Typ.
Max.
us
—
—
2.0
us
2.0
—
Table 38
Item
Reset time
Reset “L” pulse width
Signal
RES
Symbol
Condition
tR
tRW
(VDD = 1.8V , Ta = –40 to 85°C )
Rating
Units
Min.
Typ.
Max.
us
—
—
3.0
us
3.0
—
—
*1 All timing is specified with 20% and 80% of VDD as the standard.
Ver 1.0
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ST7533
THE MPU INTERFACE (REFERENCE EXAMPLES)
The ST7533 Series can be connected to either 80X86 Series MPUs or to 68000 Series MPUs. Moreover, using the serial
interface it is possible to operate the ST7533 series chips with fewer signal lines.
The display area can be enlarged by using multiple ST7533 Series chips. When this is done, the chip select signal can be
used to select the individual ICs to access.
(1) 8080 Series MPUs
VDD
VCC
A1 to A7
IORQ
CS1
CS2
Decoder
DO to D7
RD
WR
RES
DO to D7
RD
WR
RES
GND
VDD
C86
A0
ST7533
MPU
A0
P/S
VSS
RESET
VSS
Figure 42-1
(2) 6800 Series MPUs
VDD
VCC
A1 to A15
VMA
CS1
CS2
Decoder
DO to D7
E
R/W
RES
GND
VDD
C86
A0
ST7533
MPU
A0
DO to D7
E
R/W
RES
P/S
VSS
RESET
VSS
Figure 42-2
(3) Using the Serial Interface
VDD or VSS
VCC
A0
Port 1
Port 2
RES
GND
VDD
C86
ST7533
CS1
CS2
Decoder
MPU
A1 to A7
A0
SI
SCL
RES
P/S
VSS
RESET
VSS
Figure 42-3
Ver 1.0
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ST7533
CONNECTIONS BETWEEN LCD DRIVERS (REFERENCE
EXAMPLE)
The liquid crystal display area can be enlarged with ease through the use of multiple ST7533 Series chips. Use a same
equipment type.
(1) ST7533 (master) ↔ ST7533 (slave)
VDD
CLS
CLS
FR
FR
ST7533
Master
M/S
CL
CL
DOF
DOF
Output
ST7533
Slave
M/S
Input
VSS
VDD
CLS
CLS
FR
FR
ST7533
Master
M/S
CL
CL
DOF
DOF
Output
Input
ST7533
Slave
M/S
VSS
Figure 43-1
Ver 1.0
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2003/07/21
ST7533
(2) Single-chip Structure
96 X 33
Dots
ST7533
Master
Figure 43-2
(3) Double-chip Structure
192 x 33 Dots
COM
SEG
ST7533
Master
Ver 1.0
SEG
Figure 43-3
59/60
COM
ST7533
Slave
2003/07/21
ST7533
Revisions
Version 0.1
- Preliminary.
Version 0.2
- update Pad Center Coordinates page 2,3,4.
Version 0.2a - update PIN DESCRIPTIONS M/S.
Version 0.2b - update ABSOLUTE MAXIMUM RATINGS & DC CHARACTERISTICS.
Version 0.2c - update Master and Slave reference example.
Version 0.3 - update Pad Center Coordinates (1/33 , 1/17 Duty) page 3,4,5,6 and page-18.
Version 0.3a - update Pad diagram page2 and v5 regulator voltage diagram page24
Version 0.3b - Logic power supply VDD – VSS = 1.8V to 3.3V (+10% Range) , VOUT= -13V (+10% Range)
Version 0.3c - Modify page-27 The temperature grade of the Internal Power Supply for ST7533 (-0.05%/°C) Figure 14
Version 0.3d - Delete page-40 Figure 29
Version 0.4
- Modify VRS temperature gradient (-0.15%/°C) and Reset “L” pulse width
Version 0.5
- Delete shipping forms include bare chip and TCP
Version 0.6
- Modify page-10 The TEST0(PAD No.65) must connect VDD
Version 1.0
- Modify Tdh (data hold time) and page41,42 initial flow , datasheet version change version 1.0
Ver 1.0
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2003/07/21