HITACHI HD61203U

HD61203U
(Dot Matrix Liquid Crystal Graphic Display
64-Channel Common Driver)
ADE-207-274(Z)
'99.9
Rev. 0.0
Description
The HD61203U is a common signal driver for dot matrix liquid crystal graphic display systems. It
generates the timing signals (switch signal to convert LCD waveform to AC, frame synchronous signal)
and supplies them to the column driver to control display. It provides 64 driver output lines and the
impedance is low enough to drive a large screen.
As the HD61203U is produced by a CMOS process, it is fit for use in portable battery-driven equipment
utilizing the liquid crystal display’s low power consumption. The user can easily construct a dot matrix
liquid crystal graphic display system by combining the HD61203U and the column (segment) driver
HD61202U.
Features
•
•
•
•
•
•
•
•
•
•
Dot matrix liquid crystal graphic display common driver with low impedance
Low impedance: 1.5 kΩ max
Internal liquid crystal display driver circuit: 64 circuits
Internal dynamic display timing generator circuit
Display duty cycle
 When used with the column driver HD61202U: 1/48, 1/64, 1/96, 1/128
 When used with the controller HD61830: Selectable out of 1/32 to 1/128
Low power dissipation: During displays: 5 mW
Power supplies: VCC: 2.7~5.5V
Power supply voltage for liquid crystal display drive: 8V to 16V
CMOS process
100-pin plastic QFP, 100-pin plastic TQFP, chip
1
HD61203U
Ordering Information
Type No.
Package
HD61203UFS
100-pin plastic QFP (FP-100A)
HD61203UTE
100-pin thin plastic QFP (TFP-100B)
HCD61203U
Chip
2
HD61203U
HD61203UFS
(FP-100A)
31
32
33
34
35
36
37
38
39
40
41
42
43
44
45
46
47
48
49
50
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
80
79
78
77
76
75
74
73
72
71
70
69
68
67
66
65
64
63
62
61
60
59
58
57
56
55
54
53
52
51
X43
X44
X45
X46
X47
X48
X49
X50
X51
X52
X53
X54
X55
X56
X57
X58
X59
X60
X61
X62
X63
X64
VEE
V6R
V5R
V2R
V1R
TH
CL2
CL1
DS1
DS2
C
NC
R
NC
CR
STB
SHL
GND
NC
M/S
ø2
ø1
NC
FRM
M
NC
FCS
DR
X22
X21
X20
X19
X18
X17
X16
X15
X14
X13
X12
X11
X10
X9
X8
X7
X6
X5
X4
X3
X2
X1
VEE
V6L
V5L
V2L
V1L
VCC
DL
FS
100
99
98
97
96
95
94
93
92
91
90
89
88
87
86
85
84
83
82
81
X23
X24
X25
X26
X27
X28
X29
X30
X31
X32
X33
X34
X35
X36
X37
X38
X39
X40
X41
X42
Pin Arrangement
(Top view)
3
HD61203UTFIA
(TFP-100B)
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
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
DL
FS
DS1
DS2
C
NC
R
NC
CR
STB
SHL
GND
NC
M/S
ø2
ø1
NC
FRM
M
NC
FCS
DR
CL1
CL2
TH
X19
X18
X17
X16
X15
X14
X13
X12
X11
X10
X9
X8
X7
X6
X5
X4
X3
X2
X1
VEE
V6L
V5L
V2L
V1L
VCC
100
99
98
97
96
95
94
93
92
91
90
89
88
87
86
85
84
83
82
81
80
79
78
77
76
X20
X21
X22
X23
X24
X25
X26
X27
X28
X29
X30
X31
X32
X33
X34
X35
X36
X37
X38
X39
X40
X41
X42
X43
X44
HD61203U
(Top view)
4
75
74
73
72
71
70
69
68
67
66
65
64
63
62
61
60
59
58
57
56
55
54
53
52
51
X45
X46
X47
X48
X49
X50
X51
X52
X53
X54
X55
X56
X57
X58
X59
X60
X61
X62
X63
X64
VEE
V6R
V5R
V2R
V1R
HD61203U
Pad Arrangement
NO.79
No.1
NO.2
NO.78
TYPE CODE
HD61203U
NO.28
No.29
NO.54
Chip Size
: 3.40 × 4.08 µm2
Coordinate
: Pad Center
Origin
: Chip center
Pad Size
: 90 × 90 µm2
No.52
Pad Location Coordinates
Coordinate
Y
PAD
Name
Coordinate
X
Y
R
–586
PAD PAD
No. Name
1
X22
X
–1479
1853
34
2
X21
–1513
1712
35
3
X20
–1513
1544
36
4
X19
–1513
1385
37
5
X18
–1513
1238
38
6
X17
–1513
1091
39
SHL
–196
7
X16
–1513
952
40
GND
–65
8
X15
–1513
822
41
PAD
No.
CR
–456
Coordinate
Y
PAD
No.
PAD
Name
67
X56
1513
203
68
X55
1513
333
69
X54
1513
463
70
X53
1513
593
71
X52
1513
723
–1828
72
1513
853
–1828
73
X51
X50
1513
X49
1513
983
1122
–1828
–1828
X
9
X14
–1513
692
42
M/S
65
–1828
74
75
X48
1513
1261
10
X13
–1513
562
43
PHI2
195
–1828
76
X47
1513
1399
11
X12
X11
–1513
432
325
–1828
77
X46
1513
–1513
302
44
45
PHI1
12
78
X45
1513
13
X10
–1513
172
46
FRM
455
–1828
79
X44
1470
1546
1693
1853
14
X9
–1513
42
47
M
585
–1828
80
X43
1304
1853
15
X8
–1513
–88
48
81
X42
1170
1853
16
X7
–218
–349
49
50
X41
1040
1853
X6
–1513
–1513
82
17
83
X40
910
1853
18
X5
–1513
–479
51
84
X39
779
1853
19
X4
–1513
–609
52
85
X38
649
1853
20
X3
–1513
–739
53
86
X37
21
X2
–869
1513
–1522
87
X36
X1
VEE1
–999
54
55
V1R
22
–1513
–1513
519
389
V2R
88
X35
259
–1129
56
V5R
–1236
89
X34
129
1853
V6L
–1513
–1259
57
1513
1513
1513
–1374
–1513
–1097
90
X33
–1
23
24
FCS
DR
CL2
715
853
1407
–1828
–1828
–1828
1853
1853
1853
25
V5L
–1513
–1389
58
V6R
VEE2
1513
–967
91
X32
–131
1853
1853
26
V2L
–1513
–1527
59
X64
1513
–837
92
X31
–261
1853
27
–1513
–1665
60
–707
93
X30
–391
1853
–1513
–1821
61
X63
X62
1513
28
V1L
VCC
1513
–577
94
X29
–521
1853
29
DL
–1375
–1853
62
X61
1513
–447
X28
–651
1853
30
FS
–1213
–1853
63
X60
1513
X27
–781
1853
31
DS1
–976
–1828
64
X59
1513
–317
–187
95
96
97
X26
1853
32
DS2
–846
–1828
65
X58
1513
–57
98
X25
–911
–1041
33
C
–716
–1828
66
X57
1513
73
99
100
X24
–1171
1853
X23
–1301
1853
1853
5
6
STB
SHL
DL
TH
CL1
VCC
GND
VEE
Logic
Rf Cf
R CR
1
X1
C
Oscillator
V1L V5L
V2L V6L
M/S
2
X2
FS
DS1 DS2
ø1
Timing generation circuit
Bidirectional shift
register
Liquid crystal display
driver circuits
64 output terminals
ø2
62
63
Logic
64
Logic
Logic
X62 X63 X64 V1R V5R
V2R V6R
M
CL2
FRM
FCS
DR
HD61203U
Block Diagram
HD61203U
Block Functions
Oscillator
The CR oscillator generates display timing signals and operating clocks for the HD61202U. It is required
when the HD61203U is used with the HD61202U. An oscillation resister Rf and an oscillation capacitor Cf
are attached as shown in Figure 1. When using an external clock, input the clock into terminal CR and
don’t connect any lines to terminals R and C.
The oscillator is not required when the HD61203U is used with the HD61830. Then, connect terminal CR
to the high level and don’t connect any lines to terminals R and C (Figure 2).
R
CR
C
R
Open
Rf
Cf
CR
C
External Open
clock
Figure 1 Oscillator Connection with HD61202U
R
Open
CR
VCC
C
Open
Figure 2 Oscillator Connection with HD61830
7
HD61203U
Timing Generator Circuit
The timing generator circuit generates display timing and operating clock for the HD61202U. This circuit
is required when the HD61203U is used with the HD61202U. Connect terminal M/S to high level (master
mode). It is not necessary when the display timing signal is supplied from other circuits, for example, from
HD61830. In this case connect the terminals FS, DS1, and DS2 to high level and M/S to low level (slave
mode).
Bidirectional Shift Register
A 64-bit bidirectional shift register. The data is shifted from DL to DR when SHL is at high level and from
DR to DL when SHL is at low level. In this case, CL2 is used as shift clock. The lowest order bit of the
bidirectional shift register, which is on the DL side, corresponds to X1 and the highest order bit on the DR
side corresponds to X64.
Liquid Crystal Display Driver Circuit
The combination of the data from the shift register with the M signal allows one of the four liquid crystal
display driver levels V1, V2, V5 and V6 to be transferred to the output terminals (Table 1).
Table 1
Output Levels
Data from the Shift
Register
M
Output Level
1
1
V2
0
1
V6
1
0
V1
0
0
V5
8
HD61203U
HD61203U Terminal Functions
Terminal
Name
Number of
Terminals
VCC
GND
VEE
1
1
2
Power supply
V1L, V2L
V5L, V6L
V1R, V2R
V5R, V6R
8
Power supply
M/S
1
I/O
Connected to
Functions
VCC–GND: Power supply for internal logic.
VCC–VEE: Power supply for driver circuit logic.
Liquid crystal display driver level power supply.
V1L (V1R), V2L (V2R): Selected level
V5L (V5R), V6L (V6R): Non-selected level
Voltages of the level power supplies connected
to V1L and V1R should be the same. (This
applies to the combination of V2L & V2R, V5L &
V5R and V6L & V6R respectively.)
I
VCC or GND
Selects master/slave.
•
M/S = VCC: Master mode
When the HD61203U is used with the
HD61202U, timing generation circuit
operates to supply display timing signals and
operation clock to the HD61202U. Each of
I/O common terminals DL, DR, CL2, and M
is in the output state.
•
M/S = GND: Slave mode
The timing operation circuit stops operating.
The HD61203U is used in this mode when
combined with the HD61830. Even if
combined with the HD61202U, this mode is
used when display timing signals (M, data,
CL2, etc.) are supplied by another
HD61203U in the master mode. Terminals M
and CL2 are in the input state.
When SHL is VCC, DL is in the input state and
DR is in the output state.
When SHL is GND, DL is in the output state and
DR is in the input state.
FCS
1
I
VCC or GND
Selects shift clock phase.
•
FCS = VCC
Shift register operates at the rising edge of
CL2. Select this condition when HD61203U
is used with HD61202U or when MA of the
HD61830 connects to CL2 in combination
with the HD61830.
•
FCS = GND
Shift register operates at the fall of CL2.
Select this condition when CL1 of HD61830
connects to CL2 in combination with the
HD61830.
9
HD61203U
Terminal
Name
Number of
Terminals
I/O
Connected to Functions
FS
1
I
VCC or GND
Selects frequency.
When the frame frequency is 70 Hz, the oscillation
frequency should be:
f OSC = 430 kHz at FCS = VCC
f OSC = 215 kHz at FCS = GND
This terminal is active only in the master mode.
Connect it to VCC in the slave mode.
DS1, DS2
2
I
VCC or GND
Selects display duty factor.
Display Duty Factor
1/48
1/64
1/96
1/128
DS1
GND
GND
VCC
VCC
DS2
GND
VCC
GND
VCC
These terminals are valid only in the master mode.
Connect them to V CC in the slave mode.
STB
TH
CL1
1
1
1
CR, R, C
3
I
VCC or GND
Input terminal for testing
Connect to STB V CC.
Connect TH and CL1 to GND.
Oscillator
In the master mode, use these terminals as shown
below:
Internal oscillation
Rf
R
Cf
CR
External clock
Open
External
clock
Open
R
CR
C
C
In the slave mode, stop the oscillator as shown
below:
ø1, ø2
10
2
O
HD61202U
Open
VCC
Open
R
CR
C
Operating clock output terminals for the HD61202U
•
Master mode
Connect these terminals to terminals ø1 and ø2
of the HD61202U respectively.
•
Slave mode
Don’t connect any lines to these terminals.
HD61203U
Terminal
Name
Number of
Terminals
I/O
Connected to Functions
FRM
1
O
HD61202U
M
1
I/O
Frame signal
•
Master mode
Connect this terminal to terminal FRM of the
HD61202U.
•
Slave mode
Don’t connect any lines to this terminal.
MB of
Signal to convert LCD driver signal into AC
HD61830 or M • Master mode: Output terminal
of HD61202U
Connect this terminal to terminal M of the
HD61202U.
•
CL2
DL, DR
1
2
I/O
I/O
CL1 or MA of
HD61830 or
CL of
HD61202U
Open or FLM
of HD61830
Slave mode: Input terminal
Connect this terminal to terminal MB of the
HD61830.
Shift clock
•
Master mode: Output terminal
Connect this terminal to terminal CL of the
HD61202U.
•
Slave mode: Input terminal
Connect this terminal to terminal CL1 or MA of
the HD61830.
Data I/O terminals of bidirectional shift register
DL corresponds to X1’s side and DR to X64’s side.
•
Master mode
Output common scanning signal. Don’t connect
any lines to these terminals normally.
•
Slave mode
Connect terminal FLM of the HD61830 to DL
(when SHL = VCC) or DR (when SHL = GND).
M/S
NC
5
Open
VCC
GND
SHL
VCC
GND
VCC
GND
DL
Output
Output
Input
Output
DR
Output
Output
Output
Input
Not used.
Don’t connect any lines to this terminal.
SHL
1
I
VCC or GND
Selects shift direction of bidirectional shift register.
SHL
Shift Direction
Common
Scanning Direction
VCC
DL → DR
X1 → X64
GND
DL ← DR
X1 ← X64
11
HD61203U
Terminal
Name
Number of
Terminals
I/O
Connected to Functions
X1–X64
64
O
Liquid crystal
display
Liquid crystal display driver output
Output one of the four liquid crystal display driver
1
M
Data
Output
level
1
0
0
1
0
V2 V6 V1 V5
When SHL is VCC, X1 corresponds to COM1 and
X64 corresponds to COM64.
When SHL is GND, X64 corresponds to COM1
and X1 corresponds to COM64.
12
L
L
H
H
L
B
C
D
E
F
L
L
L
L
L
L
H
H
H
H
H
L
} Fixed
L
L
L
L
L
L
Rf: Oscillation resister
Cf: Oscillation capacitor
H
H
H
H
H
H
CL1 FCS FS
“—” means “open”.
Notes: H: VCC
L: GND
L
M/S TH
A
H
L
L
L
L
H
H
H
or
or
H
H
L
H
L
H
H
H
H
H
H
H
H
H
H
Cf
Rf
Cf
Rf
H
H
H
DS1 DS2 STB CR
—
Rf
Rf
—
—
—
R
—
Cf
Cf
—
—
—
C
—
—
—
ø2
—
—
—
FRM
From MB of
HD61830
From MB of
HD61830
From MB of
HD61830
M
—
—
—
From M of
HD61203U
No. 1
To ø1 of
To ø2 of
To FRM of To M of
HD61202U HD61202U HD61202U HD61202U
HD61203U
To ø1 of
To ø2 of
To FRM of To M of
HD61202U HD61202U HD61202U HD61202U
—
—
—
ø1
From CL2 of
HD61203U
No. 1
To CL of
HD61202U
To CL2 of
HD61203U
To CL of
HD61202U
From MA of
HD61830
From MA of
HD61830
From CL1 of
HD61830
CL2
From DL/DR
of HD61203U
No. 1
—
L
To DL/DR
of HD61203U
No. 2
—
—
H
L
H
L
—
—
L
H
From DL/DR
of HD61203U
No. 1
To DL/DR
of HD61203U
No. 2
L
H
From FLM of
HD61830
—
L
H
From FLM of
HD61830
DL
H
SHL
COM65–COM128
COM64–COM1
COM1–COM64
COM64–COM1
COM1–COM64
X1–X64
COM64–COM1
COM1–COM64
COM1–COM64
COM64–COM1
From DL/DR COM64–COM1
of HD61203U
No. 1
—
—
To DL/DR
COM1–COM64
of HD61203U
No. 2
—
—
From DL/DR COM128–COM65
of HD61203U
No. 1
—
From FLM of
HD61830
To DL/DR of
HD61203U
No. 2
From FLM of
HD61830
—
DR
HD61203U
Example of Application
HD61203U Connection List
13
HD61203U
Outline of HD61203U System Configuration
Use with HD61830
1. When display duty ratio of LCD is 1/64
HD61830
No. 1
COM1
COM64
LCD
One HD61203U drives
common signals.
Refer to Connection
List A.
One HD61203U drives
common signals for
upper and lower
panels.
Refer to Connection
List A.
Two HD61203Us drive
upper and lower panels
separately to ensure
the quality of display.
No. 1 and No. 2 operate
in parallel.
For both of No. 1 and
No. 2, refer to
Connection List A.
LCD
HD61830
No. 1
COM1
COM64
COM1
COM64
Upper
Lower
HD61830
No. 1
No. 2
LCD
COM1
COM64
COM1
COM64
Upper
Lower
2. When display duty ratio of LCD is from 1/65 to 1/128
HD61830
No. 1
COM1
COM128
LCD
Two HD61203Us
connected serially drive
common signals.
Refer to Connection
List B for No. 1.
Refer to Connection
List C for No. 2.
Two HD61203Us
connected serially
drive upper and lower
panels in parallel.
Refer to Connection
List B for No. 1.
Refer to Connection
List C for No. 2.
Two sets of HD61203Us
connected serially
drive upper and lower
panels in parallel to
ensure the quality of
display.
Refer to Connection
List B for No. 1 and 3.
Refer to Connection
List C for No. 2 and 4.
No. 2
HD61830
No. 1
No. 2
LCD
COM1
Upper
COM128
COM1
Lower
COM128
HD61830
No. 1
LCD
No. 2
No. 3
No. 4
14
COM1
Upper
COM128
COM1
Lower
COM128
HD61203U
Use with HD61202 (1/64 Duty Ratio)
No. 1
COM1
COM64
LCD
HD61202U
HD61202U
One HD61203U drives
common signals and
supplies timing signals
to the HD61202Us.
Refer to Connection
List D.
LCD
COM1
COM64
No. 1
COM1
COM64
HD61202U
Upper
Lower
Refer to Connection
One HD61203U drives
List D.
upper and lower panels
and supplies timing
signals to the HD61202Us.
HD61202U
No. 1
No. 2
LCD
COM1
COM64
COM1
COM64
HD61202U
Upper
Lower
Two HD61203Us drive
upper and lower panels
in parallel to ensure
the quality of display.
No. 1 supplies timing
signals to No. 2 and
the HD61202Us.
Refer to Connection
List E for No. 1.
Refer to Connection
List F for No. 2.
15
HD61203U
Connection Example 1
Use with HD61202U (RAM Type Segment Driver)
1. 1/64 duty ratio (see Connection List D)
X1
(X64)
C
Cf
COM1
CR
LCD panel
Rf
R1
R2
R1
R1
R3 V6
–
+
R3
–
+
V3
R3
–
+
–
+
V4
R3 V5
R3 V2
VEE
–10V
0V
V5L, V5R
V2L, V2R
VEE
Contrast
GND
Open
Open
COM64
V6L, V6R
DL
DR
HD61203U
R1
X64
(X1)
V1L, V1R
M
CL2
FRM
ø1
ø2
VCC
SHL
DS1
DS2
TH
CL1
FS
M/S
FCS
STB
M
CL
FRM
ø1
ø2
HD61202U
V1L, V1R
V3L, V3R
V4L, V4R
V2L, V2R
VCC
GND
VEE
R3 V1
V1
V3
V4
V2
VCC
GND
VEE
+5V (VCC)
R
VCC
R3 = 15 Ω
( ) is at SHL = Low
Note: The values of R1 and R2 vary with the LCD panel used. When bias factor is 1/9, the values of
R1 and R2 should satisfy
R1
1
=
4R1 + R2
9
For example,
R1 = 3 kΩ, R2 = 15 kΩ
Figure 3 Example 1
16
1
V6
V6
*
V5
V1
V1
2
1
*
3
2
V5
V5
3
47
48
1 frame
49
63
( ): at SHL = Low
Note: * Phase difference between DL (DR) and CL2
X2
(X63)
X1
(X64)
M
DR
(DL)
DL
(DR)
FRM
CL2
ø2
ø1
C
64
*
*
V6
V2
1
DL
(DR)
CL2
ø2
V2
V6
2
V6
3
1 frame
63
64
*
*
V5
V1
1
HD61203U
Figure 4 Example 1 Waveform (RAM Type, 1/64 Duty Cycle)
17
HD61203U
Connection Example 2
Use with HD61830 (Display Controller)
Open
VCC
Open
C
CR
R
X1
(X64)
VCC
VCC
X64
(X1)
V1
V1L, V1R
V6
V6L, V6R
V5
V5L, V5R
V2
V2L, V2R
COM1
LCD panel
HD61203U
See connection example
1. 1/64 duty ratio (see Connection List A)
COM64
M
CL2
DL (DR)
DR (DL)
M
CL1
FLM
Open
VCC
VEE
VEE
GND
GND
Open
Open
Open
FRM
ø1
ø2
SHL
DS1
DS2
TH
CL1
FS
M/S
FCS
STB
( ) is at SHL = Low
Figure 5 Example 2 (1/64 Duty Ratio)
18
HD61830
(Display controller)
From HD61830
V2
V6
X2
(X63)
X64 V6
(X1)
V6
X1
(X64)
CL1
FLM
MB
V5
V5
V1
2
V1
3
V5
V5
( ): at SHL = Low
1
4
1 frame
64
V1
1
V6
V6
V2
2
V2
V6
3
V6
1 frame
64
V2
1
V5
V5
V1
HD61203U
Figure 6 Example 2 Waveform (1/64 Duty Ratio)
19
HD61203U
2. 1/100 duty ratio (see Connection List B, C)
R
CR
C
VCC
Open Open
VCC
V1L, V1R
V6L, V6R
V5L, V5R
V2L, V2R
VEE
GND
V1
V6
M
CL2
DL (DR) HD61203U (master)
No. 1
DR (DL)
See Connection Example 1
VCC
V5
V2
VEE
GND
VCC
SHL
DS1
DS2
TH
CL1
FS
M/S
FCS
STB
X1
(X64)
COM1
X64
(X1)
LCD
panel
M
CL2
DL (DR)
DR (DL)
FLM
MA
MB
VCC
V1L, V1R
V6L, V6R
V5L, V5R
V2L, V2R
VEE
GND
Open
VCC
Open
C
CR
R
HD61203U (slave)
No. 2
HD61830
Display controller
Open
COM64
COM65
X1
(X64)
COM100
X36
(X29)
SHL
DS1
DS2
TH
CL1
FS
M/S
FCS
STB
VCC
Note: ( ) is at SHL = Low
Figure 7 Example 2 (1/100 Duty Ratio)
20
HD61830
HD61203U No. 1
HD61203U No. 2
X36
(X29)
X1
(X64)
X64
(X1)
X1
(X64)
V6
DR(DL)
HD61203U
No. 1
MA
FLM
MB
V2
V6
V6
V6
100
V5
V5
V5
V1
1
V5
2
3
V1
64
V1
V5
65
1 frame
V5
66
V1
100
V6
V6
V6
V2
1
V6
2
3
V2
64
V2
65
1 frame
66
V2
100
V5
V5
V5
V1
1
2
HD61203U
Figure 8 Example 2 Waveform (1/100 Duty Ratio)
21
HD61203U
Absolute Maximum Ratings
Item
Symbol
Limit
Unit
Notes
Power supply voltage (1)
VCC
–0.3 to +7.0
V
2
Power supply voltage (2)
VEE
VCC – 17.0 to VCC + 0.3
V
5
Terminal voltage (1)
VT1
–0.3 to VCC + 0.3
V
2, 3
Terminal voltage (2)
VT2
VEE – 0.3 to V CC + 0.3
V
4, 5
Operating temperature
Topr
–30 to +75
°C
Storage temperature
Tstg
–55 to +125
°C
Notes: 1. If LSIs are used beyond absolute maximum ratings, they may be permanently destroyed. We
strongly recommend you to use the LSI within electrical characteristic limits for normal operation,
because use beyond these conditions will cause malfunction and poor reliability.
2. Based on GND = 0V.
3. Applies to input terminals (except V1L, V1R, V2L, V2R, V5L, V5R, V6L, and V6R) and I/O
terminals at high impedance.
4. Applies to V1L, V1R, V2L, V2R, V5L, V5R, V6L, and V6R.
5. Apply the same value of voltages to V1L and V1R, V2L and V2R, V5L and V5R, V6L and V6R,
VEE (23 pin) and VEE (58 pin) respectively.
Maintain V CC ≥ V1L = V1R ≥ V6L = V6R ≥ V5L = V5R ≥ V2L = V2R ≥ VEE
22
HD61203U
Electrical Characteristics
DC Characteristics (VCC = 2.7V to 5.5V, GND = 0V, VCC –VEE = 8.0 to 16.0V, Ta = –30 to +75°C)*14
Specifications
Test Item
Symbol
Min
Typ
Max
Unit
Input high voltage
VIH
0.7 × V CC
—
VCC
V
1
Input low voltage
VIL
GND
—
0.3 × V CC
V
1
Output high voltage
VOH
VCC – 0.4
—
—
V
I OH = –0.4 mA
2
Output low voltage
VOL
—
—
0.4
V
I OL = 0.4 mA
2
Vi–Xj on resistance
RON
—
—
1.5
kΩ
VCC–VEE = 10V
Load current
±150 µA
13
Input leakage current
I IL1
–1.0
—
1.0
µA
Vin = 0 to VCC
3
Input leakage current
I IL2
–2.0
—
2.0
µA
Vin = VEE to V CC
4
Operating frequency
f opr1
50
—
600
kHz
In master mode
external clock
operation
5
Operating frequency
f opr2
0.5
—
1500
kHz
In slave mode shift 6
register
Oscillation frequency
f osc
315
450
585
kHz
Cf = 20 pF ± 5%
Rf = 39 kΩ ± 2%
7, 12
Dissipation current (1) I GG1
—
—
1.0
mA
In master mode
1/128 duty cycle
Cf = 20 pF
Rf = 39 kΩ
8, 9
Dissipation current (2) I GG2
—
—
200
µA
In slave mode
1/128 duty cycle
8, 10
Dissipation current
—
—
100
µA
In master mode
1/128 duty cycle
8, 11
I EE
Test Conditions
Notes
Notes: 1. Applies to input terminals FS, DS1, DS2, CR, SHL, M/S, and FCS and I/O terminals DL, M, DR
and CL2 in the input state.
2. Applies to output terminals, ø1, ø2, and FRM and I/O common terminals DL, M, DR, and CL2 in
the output status.
3. Applies to input terminals FS, DS1, DS2, CR, STB, SHL, M/S, FCS, CL1, and TH, I/O terminals
DL, M, DR, and CL2 in the input state and NC terminals.
4. Applies to V1L, V1R, V2L, V2R, V5L, V5R, V6L, and V6R. Don’t connect any lines to X1 to X64.
23
HD61203U
5. External clock is as follows.
TH
External clock
waveform
TL
Duty cycle =
0.7 VCC
0.5 VCC
0.3 VCC
tfcp
trcp
External clock
Open Open
CR
R
C
TH
× 100%
TH + TL
Min
Typ
Max
Unit
Duty
cycle
45
50
55
%
trcp
—
—
50
ns
tfcp
—
—
50
ns
6. Applies to the shift register in the slave mode. For details, refer to AC characteristics.
7. Connect oscillation resistor (Rf) and oscillation capacitance (Cf) as shown in this figure.
Oscillation frequency (f OSC) is twice as much as the frequency (fø) at ø1 or ø2.
Cf
Rf
CR
R
C
ø1, ø2
Cf = 20 pF
Rf = 39 kΩ
fOSC = 2 × fø
8. No lines are connected to output terminals and current flowing through the input circuit is
excluded. This value is specified at VIH = VCC and VIL = GND.
9. This value is specified for current flowing through GND in the following conditions: Internal
oscillation circuit is used. Each terminal of DS1, DS2, FS, SHL, M/S, STB, and FCS is connected
to VCC and each of CL1 and TH to GND. Oscillator is set as/ described in note 7.
10. This value is specified for current flowing through GND under the following conditions: Each
terminals of DS1, DS2, FS, SHL, STB, FCS and CR is connected to V CC, CL1, TH, and M/S to
GND and the terminals CL2, M, and DL are respectively connected to terminals CL2, M, and DL
of the HD61203U under the condition described in note 9.
11. This value is specified for current flowing through V EE under the condition described in note 9.
Don’t connect any lines to terminal V.
12. This figure shows a typical relation among oscillation frequency, Rf and Cf. Oscillation frequency
may vary with the mounting conditions.
fOSC (kHz)
600
Cf = 20 pF
400
200
0
50
Rf (kΩ)
24
100
HD61203U
13. Resistance between terminal X and terminal V (one of V1L, V1R, V2L, V2R, V5L, V5R, V6L, and
V6R) when load current flows through one of the terminals X1 to X64. This value is specified
under the following conditions:
VCC–VEE = 10V
V1L = V1R, V6L = V6R = VCC – 1/7 (VCC–VEE)
V2L = V2R, V5L = V5R = VEE + 1/7 (VCC–VEE)
RON
V1L, V1R
V6L, V6R
Terminal X
(X1 to X64)
V5L, V5R
V2L, V2R
Connect one of the lines
The following is a description of the range of power supply voltage for liquid crystal display drive.
Apply positive voltage to V1L = V1R and V6L = V6R and negative voltage to V2L = V2R and V5L
= V5R within the ∆V range. This range allows stable impedance on driver output (RON). Notice
that ∆V depends on power supply voltage VCC–VEE.
VCC
V1 (V1L = V1R)
Range of power supply
voltage for liquid crystal
display drive
V6 (V6L = V6R)
∆V (V)
∆V
3.5
2
∆V
V5 (V5L = V5R)
V2 (V2L = V2R)
VEE
,,,,,,,,,,,,,,
,,,,,,,,,,,,,,
,,,,,,,,,,,,,,
,,,,,,,,,,,,,,
,,,,,,,,,,,,,,
,,,,,,,,,,,,,,
,,,,,,,,,,,,,,
,,,,,,,,,,,,,,
,,,,,,,,,,,,,,
,,,,,,,,,,,,,,
,,,,,,,,,,,,,,
,,,,,,,,,,,,,,
,,,,,,,,,,,,,,
8
16
VCC–VEE (V)
Correlation between driver output
waveform and power supply voltage
for liquid crystal display drive
Correlation between power supply
voltage VCC–VEE and ∆V
14. Specified at +75°C for die products.
25
HD61203U
Terminal Configuration
Input Terminal
Applicable terminals:
CR, M/S, SHL, FCS, DS1, DS2, FS
VCC
PMOS
NMOS
I/O Terminal
Applicable terminals: DL, DR, CL2, M
VCC
(Input circuit)
PMOS
VCC
Enable
NMOS
PMOS
Data
NMOS
Output circuit
(tristate)
Output Terminal
VCC
Applicable terminals: ø1, ø2, FRM
PMOS
NMOS
Applicable terminals:
X1 to X64
Output Terminal
PMOS
V1L, V1R
VCC
PMOS
V6L, V6R
VCC
NMOS
V5L, V5R
VEE
NMOS
VEE
26
V2L, V2R
HD61203U
AC Characteristics (VCC = 2.7V to 5.5V, GND = 0V, Ta = –30 to +75°C) *2
In the Slave Mode (M/S = GND)
0.7 VCC
CL2
(FCS = GND)
(Shift clock)
tWLCL2L
0.3 VCC
tf
tr
tr
CL2
(FCS = VCC)
(Shift clock)
tf
tWLCL2H
tDS
0.7 VCC
tWHCL2H
tWHCL2L
0.3 VCC
tDH
tDD
DL (SHL = VCC)
DR (SHL = GND)
Input data
0.7 VCC
0.3 VCC
tDHW
DR (SHL = VCC)
DL (SHL = GND)
Output data
0.7 VCC
0.3 VCC
Item
Symbol
Min
Typ
Max
Unit
CL2 low level width (FCS = GND)
t WLCL2L
450
—
—
ns
CL2 high level width (FCS = GND)
t WLCL2H
150
—
—
ns
CL2 low level width (FCS = VCC)
t WHCL2L
150
—
—
ns
CL2 high level width (FCS = VCC)
t WHCL2H
450
—
—
ns
Data setup time
t DS
100
—
—
ns
Data hold time
t DH
100
—
—
ns
Data delay time
t DD
—
—
200
ns
Data hold time
t DHW
10
—
—
ns
CL2 rise time
tr
—
—
30
ns
CL2 fall time
tf
—
—
30
ns
Note
1
Notes: 1. The following load circuit is connected for specification.
Output terminal
30 pF (includes jig capacitance)
2. Specified at +75°C for die products.
27
HD61203U
3. In the master mode (M/S = VCC, FCS = VCC, Cf = 20 pF, Rf = 39 kΩ)
CL2
0.7 VCC
tWCL2L
tWCL2H
0.3 VCC
tDH
tDS
tDH
tDS
0.7 VCC
DL (SHL = VCC)
DR (SHL = GND)
0.3 VCC
tDD
tDD
0.7 VCC
DR (SHL = VCC)
DL (SHL = GND)
0.3 VCC
tDFRM
tDFRM
0.7 VCC
FRM
0.3 VCC
tDM
0.7 VCC
M
0.3 VCC
tf
tr
tWø1H
0.7 VCC
ø1
0.3 VCC
tWø1L
tD12
tD21
0.7 VCC
ø2
tWø2H
tf tWø2L tr
28
0.3 VCC
HD61203U
Item
Symbol
Min
Typ
Max
Unit
Data setup time
t DS
20
—
—
µs
Data hold time
t DH
40
—
—
µs
Data delay time
t DD
5
—
—
µs
FRM delay time
t DFRM
–2
—
+2
µs
M delay time
t DM
–2
—
+2
µs
CL2 low level width
t WCL2L
35
—
—
µs
CL2 high level width
t WCL2H
35
—
—
µs
ø1 low level width
t Wø1L
700
—
—
ns
ø2 low level width
t Wø2L
700
—
—
ns
ø1 high level width
t Wø1H
2100
—
—
ns
ø2 high level width
t Wø2H
2100
—
—
ns
ø1–ø2 phase difference
t D12
700
—
—
ns
ø2–ø1 phase difference
t D21
700
—
—
ns
ø1, ø2 rise time
tr
—
—
150
ns
ø1, ø2 fall time
tf
—
—
150
ns
29
HD61203U
Cautions
1. Hitachi neither warrants nor grants licenses of any rights of Hitachi’s or any third party’s patent,
copyright, trademark, or other intellectual property rights for information contained in this document.
Hitachi bears no responsibility for problems that may arise with third party’s rights, including
intellectual property rights, in connection with use of the information contained in this document.
2. Products and product specifications may be subject to change without notice. Confirm that you have
received the latest product standards or specifications before final design, purchase or use.
3. Hitachi makes every attempt to ensure that its products are of high quality and reliability. However,
contact Hitachi’s sales office before using the product in an application that demands especially high
quality and reliability or where its failure or malfunction may directly threaten human life or cause risk
of bodily injury, such as aerospace, aeronautics, nuclear power, combustion control, transportation,
traffic, safety equipment or medical equipment for life support.
4. Design your application so that the product is used within the ranges guaranteed by Hitachi particularly
for maximum rating, operating supply voltage range, heat radiation characteristics, installation
conditions and other characteristics. Hitachi bears no responsibility for failure or damage when used
beyond the guaranteed ranges. Even within the guaranteed ranges, consider normally foreseeable
failure rates or failure modes in semiconductor devices and employ systemic measures such as failsafes, so that the equipment incorporating Hitachi product does not cause bodily injury, fire or other
consequential damage due to operation of the Hitachi product.
5. This product is not designed to be radiation resistant.
6. No one is permitted to reproduce or duplicate, in any form, the whole or part of this document without
written approval from Hitachi.
7. Contact Hitachi’s sales office for any questions regarding this document or Hitachi semiconductor
products.
Hitachi, Ltd.
Semiconductor & Integrated Circuits.
Nippon Bldg., 2-6-2, Ohte-machi, Chiyoda-ku, Tokyo 100-0004, Japan
Tel: Tokyo (03) 3270-2111 Fax: (03) 3270-5109
URL
NorthAmerica
: http:semiconductor.hitachi.com/
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: http://www.has.hitachi.com.sg/grp3/sicd/index.htm
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: http://www.hitachi.com.tw/E/Product/SICD_Frame.htm
Asia (HongKong) : http://www.hitachi.com.hk/eng/bo/grp3/index.htm
Japan
: http://www.hitachi.co.jp/Sicd/indx.htm
For further information write to:
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(America) Inc.
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San Jose,CA 95134
Tel: <1> (408) 433-1990
Fax: <1>(408) 433-0223
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Germany
Tel: <49> (89) 9 9180-0
Fax: <49> (89) 9 29 30 00
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Copyright © Hitachi, Ltd., 1998. All rights reserved. Printed in Japan.
30