MOTOROLA MC141800A

MOTOROLA
SEMICONDUCTOR TECHNICAL DATA
LCD Segment / Common Driver
with Controller
MC141800A
CMOS
MC141800A is a CMOS LCD Driver which consists of 193 high voltage
LCD driving signals to drive 128 Segment and 65 Common display. It has
6800-series parallel, IIC serial interface and Serial Peripheral interface (SPI)
capability for operating with general MCU. Besides the general LCD driver features, it has on chip LCD Smart Bias Divider circuit such that minimize external
component required in applications.
MC141800AT : TAB (Tape Automated Bonding)
MCC141800AZ : Gold Bump Die
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Single Supply Operation, 2.4 V - 3.5 V
Maximum 16.5V LCD Driving Output Voltage
Low Current Stand-by Mode (<1uA)
On Chip Internal DC/DC Converter / External Power Supply
Smart Bias Divider
4X / 5X DC-DC Converter
8 bit 6800-series Parallel Interface, 1MHz IIC Serial Interface and Serial
Peripheral Interface (SPI)
On chip Oscillator
Graphic Mode Operation
On Chip 128 x 65 Display Data RAM
Master Clear RAM
Low Power Smart Icon Mode (128 icons, <25uA)
Display Masks for Implementation of Blinking Effect
2 to 65 Selectable Multiplex Ratio
1:8 / 1:9 Bias Ratio
Re-mapping of Row and Column Drivers
16 level Internal Contrast Control
External Contrast Control
Built-in Temperature Compensation Circuit
Selectable Display Waveform : Type B or Type C Waveform
2V Icon Mode Display On
Vertical Scrolling
Standard TAB Package, Gold Bump Die
MC141800AT
TAB
MCC141800AZ
Gold bump die
ORDERING INFORMATION
MC141800AT TAB
MCC141800AZ Gold BumpDie
REV 2
2/98
MOTOROLA
MC141800A
3–257
Block Diagram
Com0 to
Com64
Seg0~Seg127
Level
Selector
HV Buffer Cell Level Shifter
VLL6
65 Bit
Latch
OSC1
VLL2
128 Bit Latch
VCC
VR
Display
Timing
Generator
OSC2
LCD Driving
Voltage Generator
VF
C1P
4x and 5x
DC/DC Converter,
Voltage Regulator,
Smart Bias Divider,
Contrast Control,
Temperature
Compensation
GDDRAM
65 x 128Bits
C3P
C1N
C3N
AVDD
AVSS
Command Decoder
DVSS
DVDD
Command Interface
RES
MC141800A
3–258
CE
D/C
Parallel / Serial Interface
S/P
R/W
CLK
D0~D7
MOTOROLA
MC141800AT PIN ASSIGNMENT
(COPPER VIEW)
ENCAPSULANT
DIE
MOTOROLA
COPPER
POLYIMIDE
Normal Design TAB
MC141800A
3–259
DUMMY
DVDD
S/P
RES
D/C
R/W
D7/IIC/SPI
D6
D5
D4/Dout
D3/Din
D2/A2
D1/A1
D0/SDA
CLK
CE
VF
VR
C1P
C1N
C2P
C2N
C3P
C3N
NC
NC
VLL2
VLL3
NC
NC
NC
NC
VLL4
VLL5
VLL6
OSC1
DVSS
NC
NC
VCC
AVSS
OSC2
AVDD
DUMMY
39
40
41
42
38
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
DUMMY
COM61
COM62
COM63
COM64A
SEG2
SEG1
SEG0
COM32
COM33
COM34
78
77
76
75
74
73
46
45
44
43
SEG66
SEG65
SEG64
SEG63
SEG62
SEG61
COM2
COM1
COM0
COM64B
SEG127
SEG126
SEG125
SEG124
SEG123
COM31
COM30
COM29
COM28
COM27
DUMMY
142
141
140
139
138
137
207
206
205
204
203
202
201
200
199
236
235
234
233
232
M
COM32
COM33
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COM53
COM54
MC141800A
Mark A
AREA C
Mark B
COM64B
COM0
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COM20
COM21
Die Pad Layout for MC141800A (Gold Bumps face up)
SEG0
SEG1
SEG2
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SEG126
SEG127
MC141800A
3–260
COM55
COM56
.
.
COM63
COM64A
Gold Bump Size :
DVSS
DVSS
DVSS
DVSS
DVSS
DVSS
Alignment Mark:
AVDD
OSC2
AVSS
VCC
VCC
DVSS
DVSS
OSC1
DVSS
VLL6
VLL6
VLL5
VLL5
VLL4
VLL4
VLL3
VLL3
VLL2
VLL2
C3N
C3P
C2N
C2P
C1N
C1P
VR
VF
AVSS
AVSS
AVDD
AVDD
DVSS
DVSS
DVDD
DVDD
CE
CLK
CLK
D0
D0
D1
D2
D3
D4
D5
D6
D7
R/W
DVSS
DVSS
DVSS
DVSS
DVSS
DVSS
DVSS
DVSS
DVSS
DVSS
DVSS
DVSS
DVSS
DVSS
DVSS
DVSS
DVSS
DVSS
DVSS
D/C
RES
S/P
DVDD
COM31
.
.
.
.
.
COM22
Input Pad, 65 x 65 (µm)
Output Pad, 42 x 100 (µm)
AREA
Mark A
Mark B
COORDINATES
X
Y
4366.6
44.2
4466.6
442
4466.6
-5.8
4416.6
-55.8
4366.6
-58.8
4396.6
14.2
4436.6
14.2
4436.6
7.2
4403.6
-25.8
4396.6
-25.8
-4937.6
-221.8
-4937.6
-121.8
-4887.6
-121.8
-4837.6
-171.8
-4837.6
-221.8
-4907.6
-191.8
-4907.6
-151.8
-4900.6
-151.8
-4867.6
-184.8
-4867.6
-191.8
Reserved Area:
AREA
C
COORDINATES
X
Y
-3747.1
-533.9
-3747.1
-638.9
-3852.1
-638.9
-3852.1
-533.9
Dimensions in µm
Note:
1. Reserved area contains dummy bumps for IC bumping process
alignment and IC identifications.
2. No conductive tracks should be laid underneath reserved area to
avoid short circuit.
X
Y
MOTOROLA
MAXIMUM RATINGS* (Voltages Referenced to VSS, TA=25˚C)
Symbol
AVDD,DVDD
Parameter
Supply Voltage
VCC
Vin
Input Voltage
I
Value
Unit
-0.3 to +4.0
V
VSS-0.3 to VSS+16.5
V
VSS-0.3 to VDD+0.3
V
25
mA
Current Drain Per Pin Excluding VDD and VSS
TA
Tstg
Operating Temperature
-30 to +85
˚C
Storage Temperature Range
-65 to +150
˚C
* Maximum Ratings are those values beyond which damage to the device may occur. Functional
operation should be restricted to the limits in the Electrical Characteristics tables or Pin Description section.
VSS = AVSS = DVSS (DVSS = VSS of Digital and DC/DC circuit, AVSS = VSS of Analogue Circuit)
VDD = AVDD = DVDD (DVDD = VDD of Digital and DC/DC circuit, AVDD = VDD of Analogue Circuit)
This device contains circuitry to protect the inputs
against damage due to high static voltages or electric fields; however, it is advised that normal precautions to be taken to avoid application of any voltage
higher than maximum rated voltages to this high
impedance circuit. For proper operation it is recommended that Vin and Vout be constrained to the
range VSS < or = (Vin or Vout) < or = VDD. Reliability
of operation is enhanced if unused input are connected to an appropriate logic voltage level (e.g.,
either VSS or VDD). Unused outputs must be left
open. This device may be light sensitive. Caution
should be taken to avoid exposure of this device to
any light source during normal operation. This
device is not radiation protected.
ELECTRICAL CHARACTERISTICS (Voltage Referenced to VSS, VDD=2.4 to 3.5V, TA=25˚C)
Symbol
Test Condition
Min
Typ
Max
Unit
Logic and DC/DC Circuit Supply Voltage Range
Other Analog Circuit Supply Voltage Range
(Absolute value referenced to VSS)
2.4
2.4
3.0
-
3.5
3.5
V
V
IAC
Access Mode Supply Current Drain
(AVDD + DVDD Pins)
VDD=3.0V, Internal DC/DC Converter On, 5X DC/DC
Converter Enabled, R/W accessing, Tcyc=1MHz,
Osc. Freq.=50KHz, Display On.
-
700
800
µA
IDP1
Display Mode Supply Current Drain
(AVDD + DVDD Pins)
VDD=3.0V, Internal DC/DC Converter On, 5X Converter Enabled, R/W Halt, Osc. Freq.=50KHz, Display On.
-
530
650
µA
IDP2
Display Mode Supply Current Drain
(AVDD + DVDD Pins)
VDD=3.0V, Internal DC/DC Converter On, 4X Converter Enabled, R/W Halt, Osc. Freq.=55KHz, Display On, Set 48Mux, 1:8 bias
-
300
400
µA
ISB
Standby Mode Supply Current Drain
(AVDD + DVDD Pins)
VDD=3.0V, Display off, Oscillator Disabled, R/W halt.
-
200
400
nA
IICON
Icon Mode Supply Current Drain
(AVDD + DVDD Pins)
VDD=3.0V, Internal Oscillator, Oscillator Enabled,
Display On, Icon On, R/W halt, Freq.=50KHz.
-
10
20
µA
VCC
LCD Driving Internal DC/DC Converter Output
(VCC Pin)
Display On, DC/DC Converter Enabled, Osc. Freq.=
50KHz, Internal Regulator Enabled, Divider Enabled.
7
15
16.5
V
Internal DC/DC Converter Disabled.
7
15
16.5
V
-
2
-
V
DVDD
AVDD
Parameter
VLCD
LCD Driving Voltage Input (VCC Pin)
VICON
Low Power Icon mode Voltage
VOH1
Output High Voltage
(D0-D7, OSC2)
Iout=100µA
0.9*VDD
-
VDD
V
VOL1
Output Low Voltage
(D0-D7, OSC2)
Iout=100µA
0
-
0.1*VDD
V
VR1
LCD Driving Voltage Source (VR Pin)
Internal Regulator Enabled (VR voltage depends on
Int/Ext Contrast Control )
0
-
VCC-0.5
V
VR2
LCD Driving Voltage Source (VR Pin)
Internal Regulator Disable.
-
Floating
-
V
Note : All above parameter is tested under NO LOADING condition. For detailed testing condition, please refer to the Testing Condition figure on P.31.
MOTOROLA
MC141800A
3–261
ELECTRICAL CHARACTERISTICS (Voltage Referenced to VSS, VDD=2.4 to 3.5V, TA=25˚C)
Symbol
Parameter
VIH1
Input high voltage
(RES, OSC2, CLK, CE, D0-D7,R/W, D/C, S/P,
OSC1)
Input Low voltage
(RES, OSC2, CLK, CE, D0-D7, R/W, D/C, S/P,
OSC1)
VIL1
Test Condition
Min
Typ
Max
Unit
0.8*VDD
-
VDD
V
0
-
0.2*VDD
V
VLL6
VLL5
VLL4
VLL3
VLL2
LCD Display Voltage Output
(VLL6, VLL5, VLL4, VLL3, VLL2 Pins)
Smart Bias Divider Enabled, 1:9 bias ratio
-
VR
8/9*VR
7/9*VR
2/9*VR
1/9*VR
-
V
V
V
V
V
VLL6
VLL5
VLL4
VLL3
VLL2
LCD Display Voltage Output
(VLL6, VLL5, VLL4, VLL3, VLL2 Pins)
Smart Bias Divider Enabled, 1:8 bias ratio
-
VR
7/8*VR
6/8*VR
2/8*VR
1/8*VR
-
V
V
V
V
V
VLL6
VLL5
VLL4
VLL3
VLL2
LCD Display Voltage Input
(VLL6, VLL5, VLL4, VLL3, VLL2 Pins)
External Voltage Generator, Smart Bias Divider Disable
7
0
0
0
0
-
VCC
VLL6
VLL5
VLL4
VLL3
V
V
V
V
V
IOH
Output High Current Source
(D0-D7, OSC2)
Vout=VDD-0.4V
50
-
-
µA
IOL
Output Low Current Drain
(D0-D7, OSC2)
Vout=0.4V
-
-
-50
µA
IOZ
Output Tri-state Current Drain Source
(D0-D7, OSC2)
-1
-
1
µA
Input Current
(RES, OSC2, CLK, D0-D7, R/W, D/C , S/P,
OSC1)
-1
-
1
µA
CIN
Input Capacitance
(OSC1, OSC2, all logic pins)
-
5
7.5
pF
VCN
Internal Contrast Control
(VR Output Voltage)
Internal Regulator Enabled, Internal Contrast control
Enabled. (16 Voltage Levels Controlled by Software.
Each level is typically 1.5% of the Internal Regulator
Output Voltage. )
-
± 12
-
%
(TC1=0, TC2=0, Internal Regulator Disabled.)
(TC1=0, TC2=1, Internal Regulator Enabled.)
(TC1=1, TC2=0, Internal Regulator Enabled.)
(TC1=1, TC2=1, Internal Regulator Enabled.)
-
0.0
-0.18
-0.22
-0.35
-
%
%
%
%
IIL/IIH
Temperature Coefficient Compensation
Flat Temperature Coefficient
Temperature Coefficient 1*
Temperature Coefficient 2*
Temperature Coefficient 3*
PTC0
PTC1
PTC2
PTC3
* The formula for the temperature coefficient is:
TC(%)=
VR at 50˚C - VR at 0˚C
50˚C - 0˚C
MC141800A
3–262
X
1
X100%
VR at 25˚C
MOTOROLA
AC ELECTRICAL CHARACTERISTICS (TA=25˚C, Voltage referenced to VSS, AVDD=DVDD=3V)
Symbol
Parameter
Test Condition
Min
Typ
Max
Unit
45
55
60
KHz
FOSC
Oscillation Frequency of Display timing
generator
60Hz Frame Frequency
Either External Clock Input or Internal Oscillator
Enabled
FFRM
Frame Frequency
Graphic Display Mode, Normal Frequency Mode,
65 - 50 MUX
-
FOSC
15 * MUX
-
Hz
Graphic Display Mode, Half Frequency Mode,
65 - 50 MUX
-
FOSC
30 * MUX
-
Hz
Graphic Display Mode, Normal Frequency Mode,
49 - 34 MUX
-
FOSC
23 * MUX
-
Hz
Graphic Display Mode, Half Frequency Mode,
49 - 34 MUX
-
FOSC
46 * MUX
-
Hz
Graphic Display Mode, Normal Frequency Mode,
33 - 2 MUX
-
FOSC
30 * MUX
-
Hz
Graphic Display Mode, Half Frequency Mode,
33 -2 MUX
-
FOSC
60 * MUX
-
Hz
6-Phase Low Power Icon Mode, Normal Frequency
Mode
-
FOSC
960
-
Hz
6-Phase Low Power Icon Mode, Half Frequency
Mode
-
FOSC
1920
-
Hz
4-Phase Low Power Icon Mode, Normal Frequency
Mode
-
FOSC
1024
-
Hz
4-Phase Low Power Icon Mode, Half Frequency
Mode
-
FOSC
2048
-
Hz
OSC
Internal Oscillation Frequency with different Internal Oscillator Enabled, VDD within operation
range
value of feedback resistor
See Figure 1 for the relationship
400k
350k
250k
200k
Oscillation
Frequency
(Hz)
150k
100k
50k
100k
500k
1.0M
1.5M
2.0M
Resistor Value between OSC1 and OSC2 (Ω)
Figure 1. Internal Oscillator Frequency Relationship with External Resistor Value
MOTOROLA
MC141800A
3–263
TABLE 3. Parallel Timing Characteristics (TA=-30 to 85˚C, DVDD=2.4 to 3.5V, VSS=0V)
Symbol
Parameter
tcycle
Clock Cycle Time
Min
Typ
Max
Unit
1000
-
-
ns
tAS
Address Setup Time
90
-
-
ns
tAH
Address Hold Time
60
-
-
ns
tDSW
Write Data Setup Time
210
-
-
ns
tDHW
Write Data Hold Time
75
-
-
ns
tDSR
Read Data Setup Time
250
-
-
ns
tDHR
Read Data Hold Time
75
-
-
ns
tACC
Access Time
-
-
250
ns
PWEL
Enable Low Pulse Width
390
-
-
ns
PWEH
Enable High Pulse Width
390
-
-
ns
tR
Rise Time
-
-
45
ns
tF
Fall Time
-
-
45
ns
R/W
D/C
CE
tAS
tAH
tcycle
PWEL
CLK
PWEH
tR
tF
tDHW
D0-D7
(Write data to driver)
Valid Data
tACC
D0-D7
(Read data from driver)
tDSW
tDSR
tDHR
Valid Data
Figure 2. Parallel 6800-series Interface Timing Characteristics
MC141800A
3–264
MOTOROLA
TABLE 4. IIC Serial Timing Characteristics (TA=-30 to 85˚C, DVDD=2.4 to 3.5V, VSS=0V)
100kHz
Symbol
Parameter
Min
Typ
400kHz
Max
Min
Typ
1MHz
Max
Min
Typ
Max
Unit
Clock Cycle Time
10
-
-
2.5
-
-
1
-
-
µs
Start condition Hold Time
4.0
-
-
0.6
-
-
0.3
-
-
µs
tHD
Data Hold Time
500
-
-
300
-
-
150
-
-
ns
tSD
Data Setup Time
250
-
-
100
-
-
50
-
-
ns
tSSTART
Start condition Setup Time (Only relevant for a repeated Start condition)
4.7
-
-
0.6
-
-
0.3
-
-
µs
tSSTOP
Stop condition Setup Time
4.0
-
-
0.6
-
-
0.3
-
-
µs
-
-
1000
-
-
300
-
-
150
ns
-
-
300
-
-
300
-
-
150
ns
4.7
-
-
1.3
-
-
0.6
-
-
µs
tcycle
tHSTART
tR
Rise Time for data and clock pin
tF
Fall Time for data and clock pin
tIDLE
Idle Time before a new transmission
can start
((
))
SDA
tIDLE
tHD
tHSTART
tR
((
))
tF
tSD
tSSTART
tSSTOP
CLK
tcycle
Figure 3. IIC Serial Interface Timing Characteristics
MOTOROLA
MC141800A
3–265
MC141800A
3–266
((
))
((
))
SDA
(From controller)
((
))
((
))
SDA
(From Driver)
CLK
S
1
2
3
4
START
CONDITION
5
6
A2
A1
7
D/C
(A0)
8
R/W
9
ACK
((
))
1-8
9
DATA
ACK
((
))
P
ACK
STOP
CONDITION
ADDRESS
Figure 4. IIC Serial Interface Input Protocol (Write Data to Driver)
((
))
((
))
SDA
(From controller)
((
))
((
))
SDA
(From Driver)
CLK
S
1
2
3
4
START
CONDITION
5
6
A2
A1
7
D/C
(A0)
8
R/W
9
ACK
((
))
1-8
9
DATA
ACK
ADDRESS
MOTOROLA
Figure 5. IIC Serial Interface Output Protocol (Read Data from Driver)
((
))
P
ACK
STOP
CONDITION
TABLE 5. SPI Timing Characteristics (TA=-30 to 85˚C, DVDD=2.4 to 3.5V, VSS=0V)
Symbol
Parameter
Min
Typ
Max
Unit
tcycle
Clock Cycle Time
1000
-
-
ns
tLEAD
Enable Lead Time
500
-
-
ns
tLAG
Enable Lag Time
500
-
-
ns
tDSW
Write Data Setup Time
100
-
-
ns
tDHW
Write Data Hold Time
100
-
-
ns
tDVR
Read Data Valid Time
-
-
240
ns
tDHR
Read Data Hold Time
10
-
-
ns
tACC
Access Time
-
-
120
ns
tDIS
Disable Time
-
-
240
ns
tCLKL
Clock Low Time
380
-
-
ns
tCLKH
Clock High Time
380
-
-
ns
tR
Rise Time
-
-
100
ns
tF
Fall Time
-
-
100
ns
CE
((
))
tLEAD
tR
tF
tcyc
CLK
tLAG
((
))
tCLKH
tCLKL
tDVR
((
))
Dout
MSB
tDHW
MSB
tDHR
((
))
((
))
Din
tDSW
((
))
tACC
LSB
tDIS
LSB
Figure 6. SPI Timing Characteristics
MOTOROLA
MC141800A
3–267
PIN DESCRIPTIONS
S/P (Serial / Parallel Interface)
This pin is an input pin. The pin is sampled out when reset to
determine what type of interface is desired. The S/P pin input HIGH
for serial interface while input LOW for parallel interface.
D/C (Data / Command)
If parallel interface is selected, this input pin acknowledges the
LCD driver the input at D0-D7 is data or command. Input High for
data while input Low for command. If serial interface is selected, float
this pin.
CLK (Input Clock)
This pin is normal Low clock input. If parallel interface is selected,
data on D0-D7 are latched at the falling edge of CLK. If IIC serial
interface is selected, data on SDA is latched at the falling edge of
CLK. If SPI is selected, data on Din and Dout are latched at the falling edge of CLK.
RES (Reset)
A Low input pulse to this pin resets the internal status of the driver
(same as power on reset). The minimum pulse width is 10 µs.
CE (Chip Enable)
If parallel interface is selected, this input pin is used for chip
enable. If IIC serial interface is selected, leave this pin float and it will
be internally tied to VDD.
D0 - D7 (Data)
This bi-directional bus is used for data / command transferring. If
parallel interface is selected, D0 - D7 are connected directly to MCU
for data transfer. When serial interface is selected, D7 (IIC/SPI) is an
input pin to determine which type of serial interface is desired. The
IIC/SPI pin HIGH indicates IIC interface is used. The IIC/SPI pin
LOW indicates SPI is used.
When IIC serial interface is selected, D0 (SDA) is connected
directly to MCU for data transfer, D1 (A1) and D2 (A2) are used to
define the 2 bit programmable address. The address of this device is
0111xyab where x, y, a, b represent A2, A1, D/C and R/W respectively.
When SPI is selected, D3 (Din) is used to write data / command
from MCU to driver and D4 (Dout) is used to read data / command to
MCU from driver.
Note that if the serial interface is used, float other data pins.
R/W (Read / Write)
If parallel interface is selected, this is an input pin. To read the display data RAM or the internal status (Busy / Idle), pull this pin High.
The R/W input Low indicates a write operation to the display data
RAM or to the internal setup registers. If serial interface is selected,
let this pin float.
OSC1 (Oscillator Input)
For internal oscillator mode, this is an input for the internal low
power RC oscillator circuit. In this mode, an external resistor of certain value should be connected between the OSC1 and OSC2 pins
for a range of internal operating frequencies (refer to Figure 1). For
external oscillator mode, OSC1 should be left open.
MC141800A
3–268
OSC2 (Oscillator Output / External Oscillator Input)
For internal oscillator mode, this is an output for the internal low
power RC oscillator circuit. For external oscillator mode, OSC2 will
be an input pin for external clock and no external resistor is needed.
VLL6 - VLL2
Group of voltage level pins for driving the LCD panel. They can
either be connected to external driving circuit for external bias supply
or connected internally to built-in divider circuit if internal divider is
enable.
C1N and C1P, C2N and C2P, C3N and C3P
If Internal DC/DC Converter is enabled, a capacitor is required to
connect these three pair of pins.
VR and VF
This is a feedback path for the gain control (external contrast control) of VLL1 to VLL6. For adjusting the LCD driving voltage, it
requires a feedback resistor placed between VR and VF, a gain control resistor placed between VF and AVSS, a 10 µF capacitor placed
between VR and AVSS. (Refer to the Application Circuit)
COM0-COM63, COM64A and COM64B (Row Drivers)
These pins provide the row driving signal to LCD panel. Output is
0V during display off. COM64A and COM64B are icon lines with
same signal output so as to provide the flexability to have the icon
line on top or bottom of panel, or both top and bottom of the panel.
COM64A/B also serves as the common driving signal in the icon
mode.
COM64A/B is special design icon line (128 icons). There are some
special commands to program it separately (e.g. Set Icon Mask,
Smart Icon Mode, Low Power Icon Mode)
SEG0-SEG127 (Column Drivers)
These 128 pins provide LCD column driving signal to LCD panel.
They output 0V during display off.
AVDD and AVSS
AVDD is the positive supply to the LCD driver analog circuit. AVSS
is ground. AVDD and DVDD should be at the same level.
VCC
For using the Internal DC/DC Converter, a 0.1 µF capacitor from
this pin to AVSS is required. It can also be an external bias input pin
if Internal DC/DC Converter is not used. Power is supplied to the
LCD Driving Level Selector and HV Buffer Cell with this pin. Normally, this pin is not intended to be a power supply to other component.
DVDD and DVSS
DVDD is supplied to the digital control and DC/DC circuit of the
driver using these two pins. DVSS is ground. AVDD and DVDD
should be at the same level.
MOTOROLA
OPERATION OF LIQUID CRYSTAL DISPLAY DRIVER
Description of Block Diagram Module
Command Decoder and Command Interface
This module determines whether the input data is interpreted as
data or command. Data is directed to this module based upon the
input of the D/C pin. If D/C high, data is written to Graphic Display
Data RAM (GDDRAM). D/C low indicates that the input at D0-D7 is
interpreted as a Command.
Reset is of same function as Power ON Reset (POR). Once RES
received the reset pulse, all internal circuitry will back to its initial status. Refer to Command Description section for more information.
MPU Parallel 6800-series Interface
The parallel interface consists of 8 bi-directional data pins (D0D7), R/W, D/C, CE and the CLK. The R/W input High indicates a
read operation from the Graphic Display Data RAM (GDDRAM). R/
W input Low indicates a write operation to Display Data RAM or
Internal Command Registers depending on the status of D/C input.
The CLK input serves as data latch signal (clock). Refer to AC operation conditions and characteristics section for Parallel Interface Timing Description.
MPU Serial Peripheral Interface
The SPI consists of 4 communication bus : data input pin Din, data
output pin Dout, clock pin CLK and chip enable pin CE. The CLK
input serves as data latch signal (clock).
Data is transferred serially with most significant bit first, least significant bit last. During the communication, the controller must input
Low CE before data transactions and must stay low for the rest of the
transaction. By default, the LCD driver will receive command from
MCU. If messages on the data pin are data rather than command,
MCU should send Data Direction command (0100100X0) to control
the data direction and then one more command to define the number
of data bytes will be read / write. After these two continuous commands are send, the following messages will be data rather than
command. For read operation (X0 = 1), MCU reads a group of data
from LCD driver through Dout pin. For write opearion (X0 = 0), MCU
writes a group of data to the LCD driver through Din pin. Refer to AC
operation conditions and characteristics section for Serial Peripheral
Interface Timing Description.
MPU Serial IIC Interface
The IIC interface consists of two communication bus : data pin
SDA and clock pin CLK. The CLK input serves as data latch signal
(clock). Before communication begins, a start condition must be
setup on the bus by the controller. To establish a start condition, the
controller must pull the data pin low while the clock pin is high.
After the start condition has been established for tHSTART, an
eight-bit address should be sent. The six most significant bits of the
address (0111xy) are used to uniquely define devices on the bus, the
7th bit is used as a data / command control: if it is 0, then the signal
on SDA is interpreted as a command; if it is 1, then data SDA is written to GDDRAM. The least significant bit is a data direction read /
write control; if it is 0, then the controller writes data / command to the
driver; if it is 1, then the controller reads data / command from LCD
driver.
Data is transferred with the most significant bit first. Each byte has
to be followed by an acknowledge bit. The transmitter releases the
SDA high during the acknowledge clock pulse. The receiver has to
pull down the SDA during the acknowledge clock pulse.
To end communication, a stop condition should be set up on the
bus. A low to high transition of data pin while the clock pin is high
defines a stop condition. However, if a master still wishes to communicate on the bus, another start condition and address can be generated without a stop condition. Refer to AC operation conditions and
characteristics section for IIC Serial Interface Timing Description.
MOTOROLA
MC141800A
3–269
Column address 00H
Row 0
Column address 7FH
Com0
(Com63)
LSB
Page 1
MSB
LSB
Page 2
MSB
LSB
Page 8
MSB
Row 63
Seg127
Com64 (icon)
Seg0
Row 64 LSB
Page 9
Com63
(Com0)
Note : The configuration in parentheses represent the remapping of Rows and Columns in 65 MUX mode
Figure 7. Graphic Display Data RAM (GDDRAM) Address Map
MC141800A
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MOTOROLA
Graphic Display Data RAM (GDDRAM)
The GDDRAM is a bit mapped static RAM holding the bit pattern
to be displayed. The size of the RAM is determined by number of
row times the number of column (128x65 = 8320 bits). Figure 7 is a
description of the GDDRAM address map. For mechanical flexibility,
re-mapping on both Segment and Common outputs are provided.
Display Timing Generator
This module is an on chip low power RC oscillator circuitry (Figure 8). The oscillator frequency can be selected in the range of
15kHz to 250kHz by external resistor. One can enable the circuitry
by software command. For external clock provided, feed the clock to
OSC2 and leave OSC1 open.
Oscillator enable
Internal Oscillator selected
enable1 enable2
Oscillation Circuit
enable
Buffer
MC141800A
OSC2
OSC1
External component
Feedback for internal oscillator
For external CLK input
Figure 8. Oscillator Circuitry
LCD Driving Voltage Generator and Internal Regulator
This module generates the LCD voltage needed for display output.
It takes a single supply input and generate necessary bias voltages.
It consists of :
1. 4X and 5X DC-DC Converter
To generate the Vcc voltage. 4X DC-DC converter is used for LCD
panel which needs lower driving voltage for less power consumption. 5X DC-DC converter is used for LCD panel which needs
higher driving voltage.
2. Internal Regulator
Feedback gain control for initial LCD voltage. it can also be used
with external contrast control.
3. Smart Bias Divider
Divide the LCD display voltage (VLL2-VLL6) from the Internal Regulator output. This is a low power consumption circuit which can
save the most display current compare with traditional resistor ladder method.
4. Contrast Control Block
Software control of 16 voltage levels of LCD voltage.
All blocks can be individually turned off if external voltage generator is employed
5. Bias Ratio Selection circuitry
Software control of 1/8 and 1/9 bias ratio to match the characteristic of LCD panel.
6. Self adjust temperature compensation circuitry
Provide 4 different compensation grade selections to satisfy the
various liquid crystal temperature grades. The grading can be
selected by software control.
65 Bit Latch / 128 Bit Latch
A register carries the display signal information. First 65 bits are
Common driving signals and other 128 bits are Segment driving signals. Data will be input to the HV-buffer Cell for bumping up to the
required level.
Level Selector
Level Selector is a control of the display synchronization. Display
voltage can be separated into two sets and used with different
cycles. Synchronization is important since it selects the required LCD
voltage level to the HV Buffer Cell for output signal voltage pump.
HV Buffer Cell (Level Shifter)
HV Buffer Cell works as a level shifter which translates the low
voltage output signal to the required driving voltage. The output is
shifted out with an internal FRM clock which comes from the Display
Timing Generator. The voltage levels are given by the level selector
which is synchronized with the internal M signal.
LCD Panel Driving Waveform
COM0
COM1
COM2
COM3
COM4
COM5
COM6
COM7
SEG0
SEG1
SEG2
SEG3
SEG4
The following is an example of how the Common and Segment
drivers may be connected to a LCD panel. The waveforms shown in
Figure 9a, 9b and 9c illustrate the desired multiplex scheme.
In order to reduce the crosstalk effect, invert the polarities of the
pixel-driving waveforms every 2 or 4 or 8 or 65 lines according to the
selected waveforms. In the power-up state, the default waveform will
be type “B”.
Figure 9a. LCD Display Example “0”
MOTOROLA
MC141800A
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TIME SLOT
1 2 3 4 5 6 7 8 9
...
65 1 2 3 4 5 6 7 8 9
...
65 1 2 3 4 5 6 7 8 9
...
65 1 2 3 4 5 6 7 8 9
...
65
VLL6
VLL5
VLL4
COM0
VLL3
VLL2
VLL1
VLL6
VLL5
VLL4
COM1
VLL3
VLL2
VLL1
VLL6
VLL5
VLL4
SEG0
VLL3
VLL2
VLL1
VLL6
VLL5
VLL4
SEG1
VLL3
VLL2
VLL1
M
Figure 9b. LCD Driving Signal from MC141800A (Waveform B)
MC141800A
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MOTOROLA
TIME SLOT
1 2 3 4 5 6 7 8 9
...
65 1 2 3 4 5 6 7 8 9
...
65 1 2 3 4 5 6 7 8 9
...
65 1 2 3 4 5 6 7 8 9
...
Polarities inverted every 2 lines
65
VLL6
VLL5
VLL4
COM0
VLL3
VLL2
VLL1
VLL6
Polarities inverted every 2 lines
VLL5
VLL4
COM1
VLL3
VLL2
VLL1
VLL6
VLL5
VLL4
SEG0
VLL3
VLL2
VLL1
VLL6
VLL5
VLL4
SEG1
VLL3
VLL2
VLL1
M
...
...
...
...
Figure 9c. LCD Driving Signal from MC141800A (Waveform C with polarity inversion every 2 lines)
MOTOROLA
MC141800A
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Command Description
Set Display On / Off (Display Mode / Stand-by Mode)
The Display On command turns the LCD Common and Segment outputs on. This command starts the conversion of data in GDDRAM to
necessary waveforms on the Common and Segment driving outputs.
The on-chip bias generator is also turned on by this command. (Note :
“Oscillator On” should be sent before “Display On”.)
The Display Off command turn the display off and the states of the
LCD driver are as follow during display off :
1. All the Common and Segment outputs are fixed at VLL1 (VSS).
2. The bias Internal DC/DC Converter is turned off.
3. The RAM and content of all registers are retained.
4. IC will accept new commands and data.
The Oscillator is not affected by this command.
Set GDDRAM Column Address
This command positions the address pointer on a column location.
The address can be set to location 00H-7FH (128 columns). The column address will be increased automatically after a read or write operation. Refer to “Address Increment Table” and command “Set GDDRAM
Page Address” for further information.
Set GDDRAM Page Address
This command positions the row address to 1 of 9 possible positions
in GDDRAM. Refer to figure 7.
Master Clear GDDRAM
This command is to clear the content of the Display Data RAM to
zero. Issue this command followed by a dummy write command. The
RAM for icon line will not be affected by this command.
Master Clear Icon
This command is a MASTER clear of the Icon Data RAM. After setting the page pointer to icon page (page 9), the internal icon RAM data
will be set to Zero after the command is issued. Before using this command, set the page address to page 9 by the command “Set GDDRAM
Page Address”. A dummy write data is also needed after the “Master
Clear Icon” command to make the clear icon action effective.
Set Page Mask (Display Mask)
The following command will be written to the Page Mask Register.
Page Mask is an 8-bit register. Each bit represents one of the 8 pages :
page mask bit 0 represents Page 1, page mask bit 1 represents Page
2,...etc.
Com0 and Row 1 through Row 63 are mapped to Com1 through
Com63 respectively. With scroll value equal to 1, Row 1 of GDDRAM is
mapped to Com0, then Row 2 through Row 63 will be mapped to Com1
through Com62 respectively and Row 0 will be mapped to Com63.
Com64 is not affected by this command. This command need a following Command word define the scrolling value.
Set Display Frequency
In half display frequency mode, the display frame frequency will be
halved. Also, the operation frequency of analog circuitries will be halved
for power saving purpose.
Save / Restore Column Address
Save Column Address command saves a copy of the Column
Address of GDDRAM. Restore Column Address command restores the
copy obtained from the previous execution of saving column address.
This instruction is very useful for writing full graphics characters that are
larger than 8 pixels vertically.
Set Column Mapping
This instruction selects the mapping of Display Data RAM to Segment drivers for mechanical flexibility. There are 2 mappings to select:
1. Column 0 - Column 127 of GDDRAM mapped to Seg0-Seg127
respectively;
2. Column 0 - Column 127 of GDDRAM mapped to Seg127-Seg0
respectively.
COM64 will not be affected by this command. Detail information
please refer to section “Display Output Description”.
Set Row Mapping
This instruction selects the mapping of Display Data RAM to Common Drivers for mechanical flexibility. There are 2 selected mappings:
1. Row 0 - Row x of GDDRAM to Common 0 - Common x respectively;
2. Row 0 - Row x of GDDRAM to Common x - Common 0 respectively.
(x+2 is the multiplex ratio)
COM64 will not be affected by this command. See section “Display
Output Description” for related information.
Page Mask
When the Page Mask is enabled, the display of those pages, with
page mask bit set, will be cleared. Meanwhile, the data in the display
RAM is retained.
Set MUX Ratio
This command is to select any a ratio from 2 to 65. Row 64 (icon line)
is not affected by this command and it would be turned on for normal
display. This command contain two commands bytes, the first byte
inform the driver that the second byte will be the no. of mux ratio.
e.g. second byte = 0H to turn on Row 0 and 64 (2 MUX)
second byte = 63H to turn on Row 0 to 64 (65 MUX)
The unused common pins output non-scanning signals.
Icon Mask
When the Icon Mask is enabled, the display of the icons will be
cleared. Meanwhile, the data in the icon display RAM is retained.
Set Bias Ratio
This command sets the 1/8 bias or 1/9 bias for the divider output.
The selection should match the characteristic of LCD Panel.
Set Display Mode
This command switch the driver to full display mode or icon display
mode. In low power icon mode, only icons (driven by COM64) are displayed. Display on row 0 to row 63 will be disabled. The DC-DC converter and the Internal Regulator are off. All VCC, VLLs pins do not have
external bias voltage supply in the low power icon mode. In normal display mode, COM0 to COM64 will be turned on.
Set Oscillator Disable / Enable
This command is used to either turn on / off Oscillator. For using
internal or external oscillator, this command should be executed. The
setting for this command is not affected by command “Set Display On/
Off”. See command “Ext/Int Oscillator” for more information.
Set Vertical Scroll Value
This command is used to scroll the screen vertically with scroll value 0
to 63. With scroll value equals to 0, Row 0 of GDDRAM is mapped to
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Set Internal / External Oscillator
This command is used to select either internal or external oscillator.
When internal oscillator is selected, feedback resistor between OSC1
and OSC2 is needed. For external oscillation circuit, feed clock input
signal to OSC2 and leave OSC1 open.
MOTOROLA
Set Internal DC/DC Converter Enable
Use this command to select the Internal DC/DC Converter to generate the VCC from AVDD. Disable the Internal DC/DC Converter if external Vcc is provided.
End of Command
This command is used as extra write end command follows the last
byte of data / command written. This command is not available if serial
mode is selected.
Set 4X / 5X DC/DC Converter
This command selects the usage of 4X or 5X Converter when the
Internal DC/DC Converter is enabled.
Increase / Decrease Contrast Level
If the internal contrast control is enabled, this command is used to
increase or decrease the contrast level within the 16 contrast levels.
The contrast level starts from lowest value after POR.
Set Temperature Coefficient
A temperature gradient selector circuit controlled by two control bits
TC1 and TC2. This command can select 4 different LCD driving voltage
temperature coefficients to match various liquid crystal temperature
grades.
Set Contrast Level
This command is to select one of the 16 contrast levels when internal
contrast control circuitry is in use. After power-on reset, the contrast
level is lowest.
Set Internal Regulator On/Off
Choose bit option 0 to disable the on chip Internal Regulator. Choose
bit option 1 to enables Internal Regulator which consists of the internal
contrast control circuits.
Set Smart Icon Mode
This command is to set 4-Phase or 6-Phase smart icon modes which
for lower VDD or higher Von of panel. Refer to Smart Icon Mode Output
Description for detail.
Set Smart Bias Divider On/Off
If the Smart Bias Divider is disabled, external bias can be used for
VLL6 to VLL2. If the Smart Bias Divider is enabled, the internal circuit will
generated the 1:8 or 1:9 bias driving voltage.
Set Display Waveform Type
This command will select the number of lines for the polarity inversion of the driving waveform. Four types of waveform types are available. Refer to Figure 9.
Set Internal Contrast Control Enable
This command is used to adjust the delta voltage of the bias voltages. With bit option = 1, the software selection for delta bias voltage
control is enabled. With bit option = 0, internal contrast control is disabled.
Set Data Direction
This command is used in SPI mode only. It will be two continuous
commands, the first byte control the data direction and inform the LCD
driver the second byte will be number of data bytes will be read / write.
After these two commands sending out, the following messages will be
data.
COMMAND TABLE
Bit Pattern
Command
Comment
0000X3X2X1X0
Set GDDRAM Page Address
Set GDDRAM Page Address using X3X2X1X0 as address bits.
X3X2X1X0=0000 : page 1 (POR)
X3X2X1X0=0001 : page 2
X3X2X1X0=0010 : page 3
X3X2X1X0=0011 : page 4
X3X2X1X0=0100 : page 5
X3X2X1X0=0101 : page 6
X3X2X1X0=0110 : page 7
X3X2X1X0=0111 : page 8
X3X2X1X0=1000 : page 9
0001X3X2X1X0
Set Contrast Level
With R/W pin input low, set one of the 16 available values to the
internal contrast register, using X3X2X1X0 as data bits.
The contrast register is reset to 0000 during POR.
0010000X0
Set 4X / 5X DC-DC Converter
X0=0: enable 4X Converter (POR)
X0=1: enable 5X Converter
0010001X0
Set Segment Mapping
X0=0: Col0 to Seg0 (POR)
X0=1: Col0 to Seg127
0010010X0
Set Common Mapping
X0=0: Row0 to Com0 (POR)
X0=1: Row0 to Com63
0010100X0
Set Display on/off
X0=0: display off (POR)
X0=1: display on
0010101X0
Set Internal DC/DC Converter On/Off
X0=0: Internal DC/DC Converter Off (POR)
X0=1: Internal DC/DC Converter On
0010110X0
Set Internal Regulator On/Off
X0=0: Internal Regulator Off(POR)
X0=1: Internal Regulator On
0010111X0
Set Smart Bias Divider On/Off
X0=0: Smart Bias Divider Off (POR)
X0=1: Smart Bias Divider On
When an external bias network is preferred, the Smart Bias
Divider should be disabled.
MOTOROLA
MC141800A
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COMMAND TABLE
Bit Pattern
Command
Comment
0011000X0
Set Internal Contrast Control On/Off
X0=0: Internal Contrast Control Off(POR)
X0=1: Internal Contrast Control On
Internal contrast circuits can be disabled if external contrast circuits is preferred.
0011001X0
Set Display Frequency
X0=0 : normal display frequency (POR)
X0=1 : half display frequency
0011010X0
Save/Restore GDDRAM Column
Address
X0=0 : restore address
X0=1 : save address
00110110
Master Clear GDDRAM
Master clear GDDRAM (64 x 128 bits), row 64 (icon line) will not
be cleared
00110111
Master Clear Icons
Master Clear of Icons
0011100X0
Set Bias Ratio
X0=0 : bias = 1 : 9 (POR)
X0=1 : bias = 1 : 8
0011101X0
Reserved
X0=0 : Normal Operation (POR)
X0=1 : Test Mode 1 Select
(Note : Make sure to set X0=0 during application)
00111100
End of Command
Write commnd to identify end of data frame
0011111X0
Set Display Mode
X0=0 : low power icon display mode
X0=1 : normal display mode (POR)
01000000
Set Multiplex Ratio
next command will define no. of MUX, 00X5X4X3X2X1X0
no. of mux=00111111 upon POR (65 MUX)
01000001
Set Page Mask
next command will be written to page mask register
page mask register=0 upon POR
01000010
Set Vertical Scrolling Value
Next Command word defines the scrolling value (Scroll=0 at POR)
0100010X0
Page Mask
X0=0 : disable page mask (POR)
X0=1 : enable page mask
0100011X0
Icon Mask
X0=0 : disable icon mask (POR)
X0=1 : enable icon mask
0100100X0
Set Data Direction
(for SPI mode only)
X0=0 : Write Data (POR)
X0=1 : Read Data
next command will define the total number of data bytes will be
read / write
e.g. no. of data bytes = 01111111 for 128 bytes
0100101X0
Reserved
X0=0 : Select Switch Resistor as HV divider (POR)
X0=1 : Select Buffer as HV dividier
0100110X0
Reserved
X0=0 : Select 1.5kohm in switch resistor divider (POR)
X0=1 : Select 1kohm in switch resistor divider
01010100
Reserved
next command will define Smart Divider value, 000X4X3X2X1X0
0101001X0
Reserved
X0=0 : Use diode approach for temperature compensation (POR)
X0=1 : Use band gap technique for temperature compensation
011001X1X0
Set Display Waveform Type
X1X0=00 : Waveform Type B (POR)
X1X0=01 : Waveform Type C with polarity inversion every 8 lines
X1X0=10 : Waveform Type C with polarity inversion every 4 lines
X1X0=11 : Waveform Type C with polarity inversion every 2 lines
0110100X0
Set Smart Icon Mode
X0=1 : 4-Phase Smart Icon
X0=0 : 6-Phase Smart Icon (POR)
011011X1X0
Set Temperature Coefficient
X1X0=00 : 0.00% (POR)
X1X0=01 : -0.18%
X1X0=10 : -0.22%
X1X0=11 : -0.35%
0111000X0
Increase / Decrease Contrast Level
X0=0: Decrease by one level
X0=1: Increase by one level
(Note: increment/decrement wraps round among the 16 contrast
levels. Start at the lowest level when POR.
MC141800A
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MOTOROLA
COMMAND TABLE
Bit Pattern
Command
Comment
0111011X0
Reserved
X0=0: Normal Operation (POR)
X0=1: Test Mode 2 Select
(Note : Make sure to set X0=0 during application)
0111101X0
Set Internal / External Oscillator
X0=0: Internal oscillator (POR)
X0=1: External oscillator.
For internal oscillator place a resistor between OSC1 and OSC2.
For external oscillator mode, feed clock input to OSC2.
0111111X0
Set Oscillator On/Off
X0=0: oscillator Off (POR)
X0=1: oscillator On.
This is the master control for oscillator circuitry. This command
should be issued after the “Set Internal / External Oscillator” command.
1X6X5X4X3X2X1X0
Set GDDRAM Column Address
Set GDDRAM Column Address.
Use X6X5X4X3X2X1X0 as address bits.
Data Read / Write
To read data from the GDDRAM, input High to R/W pin and D/C pin in parallel mode or pull high at the 7th and 8th bit of the address in IIC
serial mode or send Data Direction command 01001001 in SPI mode. Data is valid at the falling edge of CLK. And the GDDRAM column
address pointer will be increased by one automatically.
To write data to the GDDRAM, input Low to R/W pin and High to D/C pin in parallel mode or pull low 7th bit and high 8th bit of the address in
IIC serial mode or send Data Direction command 01001000 in SPI mode. Data is latched at the falling edge of CLK. And the GDDRAM column
address pointer will be increased by one automatically. If parallel interface is selected, End of command should be followed after all data are
send out.
No auto address pointer increment will be performed for the Dummy Write Data after Master Clear GDDRAM. (Refer to the “Commands
Required for R/W Actions on RAM” Table)
Address Increment Table (Automatic)
D/C
R/W
Comment
Address Increment
0
0
Write Command
No
Remarks
0
1
Read Command
No (invalid mode)
*1
1
0
Write Data
Yes
*2
1
1
Read Data
Yes
Address Increment is done automatically data read write. The column address pointer of GDDRAM*3 is affected.
Remarks : *1. Only data is read from RAM.
*2. If write data is issued after Command Clear RAM, Address increase is not applied.
*3. Column Address will wrap round when overflow.
Commands Required for R/W Actions on RAM
R/W Actions on RAMs
Commands Required
Read/Write Data from/to GDDRAM.
Set GDDRAM Page Address
Set GDDRAM Column Address
Read/Write Data
End of command
(0000X3X2X1X0)*
(1X6X5X4X3X2X1X0)*
(X7X6X5X4X3X2X1X0)
(00111100)
Save/Restore GDDRAM Column Address.
Save/Restore GDDRAM Column Address
End of command
(0011010X0)
(00111100)
Master Clear GDDRAM
Set Clear Page GDDRAM (64 x 128 bits)
Dummy Write Data
(00110110)
(X7X6X5X4X3X2X1X0)
Master Clear Icon RAM
Set GDDRAM Page Address to Page 9
Master Clear Icon RAM (128 bits, row 64)
Dummy Write Data
(00001000)
(00110111)
(X7X6X5X4X3X2X1X0)
* No need to resend the command again if it is set previously.
The read / write action to the Display Data RAM does not depend on the display mode. This means the user can change the RAM content
whether the target RAM content is being displayed.
MOTOROLA
MC141800A
3–277
Display Output Description
This is an example of output pattern on the LCD panel. Figure 10b and 10c are data map of GDDRAM and the output pattern on the LCD
display with different command enabled.
COM0
Content of GDDRAM
PAGE 1 Upper Nibble 5 A 5 A 5 A 5 A 5 A - - - - - - - - - 5 A 5 A 5 A 5 A 5 A
Lower Nibble 5 A 5 A 5 A 5 A 5 A - - - - - - - - - 5 A 5 A 5 A 5 A 5 A
PAGE 2 Upper Nibble 3 3 C C 3 3 C C 3 3 - - - - - - - - - C C 3 3 C C 3 3 C C
Lower Nibble 3 3 C C 3 3 C C 3 3 - - - - - - - - - C C 3 3 C C 3 3 C C
PAGE 3 Upper Nibble 0 0 0 0 F F F F 0 0 - - - - - - - - - F F 0 0 0 0 F F F F
Lower Nibble F F F F 0 0 0 0 F F - - - - - - - - - 0 0 F F F F 0 0 0 0
PAGE 4 Upper Nibble F F F F F F F F 0 0 - - - - - - - - - F F 0 0 0 0 0 0 0 0
Lower Nibble F F F F F F F F 0 0 - - - - - - - - - F F 0 0 0 0 0 0 0 0
.
.
.
COM63
COM64
.
.
.
.
.
.
PAGE 9 Upper Nibble 0 0 0 0 0 0 0 0 0 0 - - - - - - - - - 0 0 0 0 0 0 0 0 0 0
Lower Nibble 0 0 0 1 1 1 0 0 0 0 - - - - - - - - - 0 0 0 0 1 1 1 0 0 0
SEG0
SEG127
Figure 10b
Figure 10a
Icon Line
Column remap disable
Row re-map disable
Column remap enable
Row re-map disable
Column remap disable
Row re-map enable
Figure 10c. Examples of LCD display with different command enabled
MC141800A
3–278
MOTOROLA
Power Up Sequence (Commands Required)
Command Required
POR Status
Set Display Frequency
Set Oscillator Enable
Set MUX Ratio
Set Bias Ratio
Set Internal DC/DC Converter
Set Internal Regulator On
Set Temperature Coefficient
Set Internal Contrast Control On
Set Contrast Level
Set Smart Bias Divider On
Set Segment Mapping
Set Common Mapping
Set Display On
Normal
Disable
65 MUX
1/9 bias
4X Converter
Off
TC=0%
Off
Contrast Level = 0
Off
Seg. 0 = Col. 0
Com. 0 = Row 0
Off
Remarks
*1
*1
*1
*1
*1
*1
*1, *3
*1, *3
*1, *2, *3
*1
Remarks :
*1 -- Required only if desired status differ from POR.
*2 -- Effective only if Internal Contrast Control is enabled.
*3 -- Effective only if Internal Regulator is enabled.
Smart Icon Mode Output Description
There are two driving schemes of Smart Icon Mode for panel with different Von/Voff or VDD :
1) 4 - Phase Smart Icon : 1/4 ~ 3/4
Voff > VDD * sqrt (1/4)
Von < VDD * sqrt (3/4)
2) 6 - Phase Smart Icon : 1/6 ~ 3/6
Voff > VDD * sqrt (1/6)
Von < VDD * sqrt (3/6)
COM (non icon)
DVDD
DVSS
COM64(icon)
DVDD
DVSS
SEG(on)
DVDD
DVSS
SEG(off)
DVDD
DVSS
Figure 11a. LCD Driving Signal for 4 - Phase Smart Icon Mode
DVDD
COM (non icon)
DVSS
DVDD
COM64(icon)
SEG(on)
DVSS
DVDD
DVSS
SEG(off)
DVDD
DVSS
Figure 11b. LCD Driving Signal for 6 - Phase Smart Icon Mode
MOTOROLA
MC141800A
3–279
Application Circuit:
All Internal Analog Circuitry disabled at IIC Serial mode operation
DVDD
AVDD
0.1µF
VDD
DVSS
VCC
0.1µF
DVDD
AVDD
AVSS
VLL2 VLL3
VLL4
VLL5
VLL6
VCC
D1/A1
CMOS
MPU/MCU
R
D2/A2
R
SCL
CLK
SDA
D0/SDA
COM0 to
COM64
MC141800A
RES
IIC Address
To LCD
Panel
SEG0 to
SEG127
VDD
D7/IIC/SPI
S/P
EPROM
OSC2 OSC1
VF
VR
C3P C3N
C2P C2N C1P C1N
2MΩ
R3
RAM
Remark :
1. R3 can be omitted for external oscillator.
2. RES should be at a known state.
3. VLL2 - VLL6 can be left open for internal divider is enable.
4. R/W, CE, D/C and D3-D6 can be open for IIC serial mode.
5. D1/A1 and D2/A2 should be at predefined state for device identification.
tr
6. R is pull up resistance, R <
(R = 300 ohm for 1MHz, assume Cbus = 200pF)
2 * Cbus
7. AVDD and DVDD should be at the same level.
8. The component values stated above are for reference only. Adjustment is needed for different applications.
MC141800A
3–280
MOTOROLA
IIC Serial mode operation with minimum external components
DVDD
AVDD
0.1µF
VDD
DVSS
DVDD
VCC
0.1µF
AVDD
AVSS
VLL2 VLL3
VLL4
VLL5
VLL6
VCC
D1/A1
CMOS
MPU/MCU
R
D2/A2
R
COM0 to
COM64
SCL
CLK
SDA
D0/SDA
MC141800A
RES
IIC Address
To LCD
Panel
SEG0 to
SEG127
VDD
D7/IIC/SPI
S/P
OSC2 OSC1
VF
VR
C3P C3N
C2P C2N C1P C1N
EPROM
Ext Osc.
RAM
Remark :
1. RES should be at a known state.
2. R/W, CE, D/C and D3-D6 can be open for IIC serial mode.
3. D1/A1 and D2/A2 should be at predefined state for device identification.
tr
4. R is pull up resistance, R <
(R = 300 ohm for 1MHz, assume Cbus = 200pF)
2 * Cbus
5. AVDD and DVDD should be at the same level.
6. External high voltage and internal divider are used.
7. The component values stated above are for reference only. Adjustment is needed for different applications.
MOTOROLA
MC141800A
3–281
All Internal Analog Circuitry enabled at IIC Serial mode operation
DVDD
0.1µF
AVDD
0.1µF
0.1µF
DVSS
DVDD
AVDD
AVSS
VCC
VLL2
VLL3
VDD
CMOS
MPU/MCU
VLL4
VLL5
VLL6
D1/A1
D2/A2
R
IIC Address
R
COM0 to
COM64
SCL
CLK
SDA
D0/SDA
To LCD
Panel
MC141800A
RES
SEG0 to
SEG127
VDD
D7/IIC/SPI
S/P
EPROM
OSC2 OSC1
VF
2MΩ
VR
C3P C3N
C2P C2N C1P C1N
2MΩ
R3
2MΩ
0.1µF
4.7µF
0.1µF
0.1µF
0.1µF
RAM
Remark :
1. R3 can be omitted for external oscillator.
2. VR and VF can be left open for Internal Regulator disable and Contrast Disable.
3. RES should be at a known state.
4. R/W, CE, D/C and D3-D6 can be open for IIC serial mode.
5. D1/A1 and D2/A2 should be at predefined state for device identification.
tr
6. R is pull up resistance, R <
(R = 300 ohm for 1MHz, assume Cbus = 200pF)
2 * Cbus
7.AVDD and DVDD should be at the same level.
8. The component values stated above are for reference only. Adjustment is needed for different applications.
MC141800A
3–282
MOTOROLA
All Internal Analog Circuitry disabled at SPI Serial mode operation
DVDD
AVDD
0.1µF
DVSS
VCC
0.1µF
DVDD
AVDD
AVSS
VLL2 VLL3
VLL4
VLL5
VLL6
VCC
CMOS
MPU/MCU
RES
CE
CLK
SCK
MOSI
D3/Din
MISO
D4/Dout
COM0 to
COM64
MC141800A
To LCD
Panel
SEG0 to
SEG127
D7/IIC/SPI
S/P
OSC2 OSC1
VF
VR
C3P C3N
C2P C2N C1P C1N
VDD
EPROM
2MΩ
R3
RAM
Remark :
1. R3 can be omitted for external oscillator.
2. RES should be at a known state.
3. VLL2 - VLL6 can be left open for internal divider is enable.
4. R/W, D/C, D0-2 and D5-6 can be open for SPI serial mode.
5. AVDD and DVDD should be at the same level.
6. The component values stated above are for reference only. Adjustment is needed for different applications.
MOTOROLA
MC141800A
3–283
All Internal Analog Circuitry enabled at SPI Serial mode operation
DVDD
AVDD
0.1µF
0.1µF
0.1µF
DVSS
DVDD
AVDD
AVSS
VCC
VLL2
VLL3
VLL4
VLL5
VLL6
CMOS
MPU/MCU
RES
CE
CLK
SCK
MOSI
D3/Din
MISO
D4/Dout
COM0 to
COM64
MC141800A
To LCD
Panel
SEG0 to
SEG127
D7/IIC/SPI
S/P
OSC2 OSC1
VF
VR
C3P C3N
C2P C2N C1P C1N
VDD
EPROM
2MΩ
2MΩ
R3
2MΩ
0.1µF
4.7µF
0.1µF
0.1µF
0.1µF
RAM
Remark :
1. R3 can be omitted for external oscillator.
2. VR and VF can be left open for Internal Regulator disable and Contrast Disable.
3. RES should be at a known state.
4. R/W, D/C, D0-2 and D5-6 can be open for SPI serial mode.
5. AVDD and DVDD should be at the same level.
6. The component values stated above are for reference only. Adjustment is needed for different applications.
MC141800A
3–284
MOTOROLA
All Internal Analog Circuitry disabled at Parallel mode operation
DVDD
AVDD
0.1µF
DVSS
VCC
0.1µF
DVDD
AVDD
AVSS
VLL2 VLL3
VLL4
RES
CE
D/C
CMOS
MPU/MCU
with
Parallel
Interface
VLL5
VLL6
VCC
COM0 to
COM64
R/W
CLK
MC141800A
To LCD
Panel
SEG0 to
SEG127
D0 .. D7
S/P
EPROM
OSC2 OSC1
VF
VR
C3P C3N
C2P C2N C1P C1N
2MΩ
R3
RAM
Remark :
1. R3 can be omitted for external oscillator.
2. RES should be at a known state.
3. VLL2 - VLL6 can be left open for internal divider is enable.
4. AVDD and DVDD should be at the same level.
5. The component values stated above are for reference only. Adjustment is needed for different applications.
MOTOROLA
MC141800A
3–285
All Internal Analog Circuitry enabled at Parallel mode operation
DVDD
AVDD
0.1µF
0.1µF
0.1µF
DVSS
DVDD
AVDD
AVSS
VCC
VLL2
VLL3
VLL4
RES
CE
D/C
CMOS
MPU/MCU
with
Parallel
Interface
VLL5
VLL6
COM0 to
COM64
R/W
CLK
MC141800A
To LCD
Panel
SEG0 to
SEG127
D0 .. D7
S/P
EPROM
OSC2 OSC1
VF
2MΩ
VR
C3P C3N
C2P C2N C1P C1N
2MΩ
R3
2MΩ
0.1µF
4.7µF
0.1µF
0.1µF
0.1µF
RAM
Remark :
1. R3 can be omitted for external oscillator.
2. VR and VF can be left open for Internal Regulator disable and Contrast Disable.
3. RES should be at a known state.
4. AVDD and DVDD should be same level
5. The component values stated above are for reference only. Adjustment is needed for different applications.
MC141800A
3–286
MOTOROLA
Testing Condition:
DVDD
AVDD
0.1µF
0.1µF
0.1µF
DVSS
DVDD
AVDD
VCC
AVSS
VLL2
VLL3
VLL4
RES
CE
D/C
Tester
VLL5
VLL6
COM0 to
COM64
R/W
CLK
MC141800A
No Load
SEG0 to
SEG127
D0 .. D7
S/P
OSC2 OSC1
VF
2.1MΩ
C3P C3N
C2P C2N C1P C1N
2MΩ
R3
470KΩ
MOTOROLA
VR
680pF
4.7µF
0.1µF
0.1µF
0.1µF
MC141800A
3–287
PACKAGE DIMENSIONS
MC141800AT
TAB PACKAGE DIMENSION - 1
(DO NOT SCALE THIS DRAWING)
COPPER SIDE
Reference : 98ASL00269A
MC141800A
3–288
Issue “0” released on 11 Feb 97
MOTOROLA
PACKAGE DIMENSIONS
MC141800AT
TAB PACKAGE DIMENSION - 2
(DO NOT SCALE THIS DRAWING)
Reference : 98ASL00269A
MOTOROLA
Issue “0” released on 11 Feb 97
MC141800A
3–289
Die Pad Coordinate of MC141800A
Pad Name
Pad Name
X(um)
Y(um)
Pad Name
X(um)
Y(um)
Pad Name
X(um)
Y(um)
Pad Name
1
COM(22) -4826.0 -807.6
X(um)
Y(um)
61
C3P
1198.4
-857.8
121 SEG(0)
4826.0
807.6
181 SEG(60)
266.0
807.6
241 SEG(120) -4294.0 807.6
X(um)
Y(um)
2
COM(23) -4750.0 -807.6
62
C3N
1304.4
-857.8
122 SEG(1)
4750.0
807.6
182 SEG(61)
190.0
807.6
242 SEG(121) -4370.0 807.6
3
COM(24) -4674.4 -811.8
63
VLL2:
1410.4
-857.8
123 SEG(2)
4674.0
807.6
183 SEG(62)
114.0
807.6
243 SEG(122) -4446.0 807.6
4
COM(25) -4598.0 -807.6
64
VLL2:
1516.4
-857.8
124 SEG(3)
4598.0
807.6
184 SEG(63)
38.0
807.6
244 SEG(123) -4522.0 807.6
5
COM(26) -4522.0 -807.6
65
VLL3:
1622.4
-857.8
125 SEG(4)
4522.0
807.6
185 SEG(64)
-38.0
807.6
245 SEG(124) -4598.0 807.6
6
COM(27) -4446.0 -807.6
66
VLL3:
1728.4
-857.8
126 SEG(5)
4446.0
807.6
186 SEG(65)
-114.0
807.6
246 SEG(125) -4674.0 807.6
7
COM(28) -4370.0 -807.6
67
VLL4:
1834.4
-857.8
127 SEG(6)
4370.0
807.6
187 SEG(66)
-190.0
807.6
247 SEG(126) -4750.0 807.6
8
COM(29) -4294.0 -807.6
68
VLL4:
1940.4
-857.8
128 SEG(7)
4294.0
807.6
188 SEG(67)
-266.0
807.6
248 SEG(127) -4826.0 807.6
9
COM(30) -4218.0 -807.6
69
VLL5:
2046.4
-857.8
129 SEG(8)
4218.0
807.6
189 SEG(68)
-342.0
807.6
249 COM64B
-5328.4 835.4
10
COM(31) -4142.0 -807.6
70
VLL5:
2152.4
-857.8
130 SEG(9)
4142.0
807.6
190 SEG(69)
-418.0
807.6
250 COM(0)
-5328.4 759.4
11
DVDD:
-4042.2 -857.8
71
VLL6:
2258.4
-857.8
131 SEG(10)
4066.0
807.6
191 SEG(70)
-494.0
807.6
251 COM(1)
-5328.4 683.4
12
S/P
-3940.6 -857.8
72
VLL6:
2364.4
-857.8
132 SEG(11)
3990.0
807.6
192 SEG(71)
-570.0
807.6
252 COM(2)
-5328.4 607.4
13
RES
-3839.0 -857.8
73
DVSS:
2470.4
-857.8
133 SEG(12)
3914.0
807.6
193 SEG(72)
-646.0
807.6
253 COM(3)
-5328.4 531.4
14
D/C
-3737.4 -857.8
74
OSC1
2576.4
-857.8
134 SEG(13)
3838.0
807.6
194 SEG(73)
-722.0
807.6
254 COM(4)
-5328.4 455.4
15
DVSS:
-3569.0 -857.8
75
DVSS:
2682.4
-857.8
135 SEG(14)
3762.0
807.6
195 SEG(74)
-798.0
807.6
255 COM(5)
-5328.4 379.4
16
DVSS:
-3467.4 -857.8
76
DVSS:
2788.4
-857.8
136 SEG(15)
3686.0
807.6
196 SEG(75)
-874.0
807.6
256 COM(6)
-5328.4 303.4
17
DVSS:
-3365.8 -857.8
77
VCC:
2894.4
-857.8
137 SEG(16)
3610.0
807.6
197 SEG(76)
-950.0
807.6
257 COM(7)
-5328.4 227.4
18
DVSS:
-3264.2 -857.8
78
VCC:
3000.4
-857.8
138 SEG(17)
3534.0
807.6
198 SEG(77)
-1026.0 807.6
258 COM(8)
-5328.4 151.4
19
DVSS:
-3162.6 -857.8
79
AVSS:
3106.4
-857.8
139 SEG(18)
3458.0
807.6
199 SEG(78)
-1102.0 807.6
259 COM(9)
-5328.4 75.4
20
DVSS:
-3061.0 -857.8
80
OSC2
3212.4
-857.8
140 SEG(19)
3382.0
807.6
200 SEG(79)
-1178.0 807.6
260 COM(10)
-5328.4 -0.6
21
DVSS:
-2959.4 -857.8
81
AVDD:
3318.4
-857.8
141 SEG(20)
3306.0
807.6
201 SEG(80)
-1254.0 807.6
261 COM(11)
-5328.4 -76.6
22
DVSS:
-2857.8 -857.8
82
DVSS:
3493.0
-857.8
142 SEG(21)
3230.0
807.6
202 SEG(81)
-1330.0 807.6
262 COM(12)
-5328.4 -152.6
23
DVSS:
-2756.2 -857.8
83
DVSS:
3594.6
-857.8
143 SEG(22)
3154.0
807.6
203 SEG(82)
-1406.0 807.6
263 COM(13)
-5328.4 -228.6
24
DVSS:
-2654.6 -857.8
84
DVSS:
3696.2
-857.8
144 SEG(23)
3078.0
807.6
204 SEG(83)
-1482.0 807.6
264 COM(14)
-5328.4 -304.6
25
DVSS:
-2553.0 -857.8
85
DVSS:
3797.8
-857.8
145 SEG(24)
3002.0
807.6
205 SEG(84)
-1558.0 807.6
265 COM(15)
-5328.4 -380.6
26
DVSS:
-2451.4 -857.8
86
DVSS:
3899.4
-857.8
146 SEG(25)
2926.0
807.6
206 SEG(85)
-1634.0 807.6
266 COM(16)
-5328.4 -456.6
27
DVSS:
-2349.8 -857.8
87
DVSS:
4001.0
-857.8
147 SEG(26)
2850.0
807.6
207 SEG(86)
-1710.0 807.6
267 COM(17)
-5328.4 -532.6
28
DVSS:
-2248.2 -857.8
88
COM64A 4142.0
-807.6
148 SEG(27)
2774.0
807.6
208 SEG(87)
-1786.0 807.6
268 COM(18)
-5328.4 -608.6
29
DVSS:
-2146.6 -857.8
89
COM(63) 4217.0
-806.2
149 SEG(28)
2698.0
807.6
209 SEG(88)
-1862.0 807.6
269 COM(19)
-5328.4 -684.6
30
DVSS:
-2045.0 -857.8
90
COM(62) 4293.0
-806.2
150 SEG(29)
2622.0
807.6
210 SEG(89)
-1938.0 807.6
270 COM(20)
-5328.4 -760.6
31
DVSS:
-1943.4 -857.8
91
COM(61) 4369.0
-806.2
151 SEG(30)
2546.0
807.6
211 SEG(90)
-2014.0 807.6
271 COM(21)
-5328.4 -836.6
32
DVSS:
-1841.8 -857.8
92
COM(60) 4445.0
-806.2
152 SEG(31)
2470.0
807.6
212 SEG(91)
-2090.0 807.6
33
DVSS:
-1740.2 -857.8
93
COM(59) 4521.0
-806.2
153 SEG(32)
2394.0
807.6
213 SEG(92)
-2166.0 807.6
34
R/W
-1638.6 -857.8
94
COM(58) 4597.0
-806.2
154 SEG(33)
2318.0
807.6
214 SEG(93)
-2242.0 807.6
35
D7
-1537.0 -857.8
95
COM(57) 4673.0
-806.2
155 SEG(34)
2242.0
807.6
215 SEG(94)
-2318.0 807.6
36
D6
-1435.4 -857.8
96
COM(56) 4749.0
-806.2
156 SEG(35)
2166.0
807.6
216 SEG(95)
-2394.0 807.6
37
D5
-1333.8 -857.8
97
COM(55) 4826.0
-807.6
157 SEG(36)
2090.0
807.6
217 SEG(96)
-2470.0 807.6
38
D4
-1232.2 -857.8
98
COM(54) 5328.4
-836.6
158 SEG(37)
2014.0
807.6
218 SEG(97)
-2546.0 807.6
39
D3
-1130.6 -857.8
99
COM(53) 5328.4
-760.6
159 SEG(38)
1938.0
807.6
219 SEG(98)
-2622.0 807.6
40
D2
-1029.0 -857.8
100 COM(52) 5328.4
-684.6
160 SEG(39)
1862.0
807.6
220 SEG(99)
-2698.0 807.6
41
D1
-927.4
-857.8
101 COM(51) 5328.4
-608.6
161 SEG(40)
1786.0
807.6
221 SEG(100) -2774.0 807.6
42
D0
-825.8
-857.8
102 COM(50) 5328.4
-532.6
162 SEG(41)
1710.0
807.6
222 SEG(101) -2850.0 807.6
43
D0
-724.2
-857.8
103 COM(49) 5328.4
-456.6
163 SEG(42)
1634.0
807.6
223 SEG(102) -2926.0 807.6
44
CLK
-622.6
-857.8
104 COM(48) 5328.4
-380.6
164 SEG(43)
1558.0
807.6
224 SEG(103) -3002.0 807.6
45
CLK
-521.0
-857.8
105 COM(47) 5328.4
-304.6
165 SEG(44)
1482.0
807.6
225 SEG(104) -3078.0 807.6
46
CE
-419.6
-857.8
106 COM(46) 5328.4
-228.6
166 SEG(45)
1406.0
807.6
226 SEG(105) -3154.0 807.6
47
DVDD:
-317.8
-857.8
107 COM(45) 5328.4
-152.6
167 SEG(46)
1330.0
807.6
227 SEG(106) -3230.0 807.6
48
DVDD:
-216.2
-857.8
108 COM(44) 5328.4
-76.6
168 SEG(47)
1254.0
807.6
228 SEG(107) -3306.0 807.6
49
DVSS:
-114.6
-857.8
109 COM(43) 5328.4
-0.6
169 SEG(48)
1178.0
807.6
229 SEG(108) -3382.0 807.6
50
DVSS:
-13.0
-857.8
110 COM(42) 5328.4
75.4
170 SEG(49)
1102.0
807.6
230 SEG(109) -3458.0 807.6
51
AVDD:
138.4
-857.8
111 COM(41) 5328.4
151.4
171 SEG(50)
1026.0
807.6
231 SEG(110) -3534.0 807.6
52
AVDD:
244.4
-857.8
112 COM(40) 5328.4
227.4
172 SEG(51)
950.0
807.6
232 SEG(111) -3610.0 807.6
53
AVSS:
350.4
-857.8
113 COM(39) 5328.4
303.4
173 SEG(52)
874.0
807.6
233 SEG(112) -3686.0 807.6
54
AVSS:
456.4
-857.8
114 COM(38) 5328.4
379.4
174 SEG(53)
798.0
807.6
234 SEG(113) -3762.0 807.6
55
VF
562.4
-857.8
115 COM(37) 5328.4
455.4
175 SEG(54)
722.0
807.6
235 SEG(114) -3838.0 807.6
56
VR
668.4
-857.8
116 COM(36) 5328.4
531.4
176 SEG(55)
646.0
807.6
236 SEG(115) -3914.0 807.6
57
C1P
774.4
-857.8
117 COM(35) 5328.4
607.4
177 SEG(56)
570.0
807.6
237 SEG(116) -3990.0 807.6
58
C1N
880.4
-857.8
118 COM(34) 5328.4
683.4
178 SEG(57)
494.0
807.6
238 SEG(117) -4066.0 807.6
59
C2P
986.4
-857.8
119 COM(33) 5328.4
759.4
179 SEG(58)
418.0
807.6
239 SEG(118) -4142.0 807.6
60
C2N
1092.4
-857.8
120 COM(32) 5328.4
835.4
180 SEG(59)
342.0
807.6
240 SEG(119) -4218.0 807.6
Note :
*Power and ground die pads should be bonded correspondingly in COG application
Die Pad 15 - 33, 43, 45, 47 -54, 64, 66, 68, 70, 72 - 73, 76, 78 and 82 - 87 are multiple pads of critical signal
(Basically, these are D0, CLK, DVDD, DVSS, AVDD, AVSS, VCC and VLL2-VLL6 which special design for COG)
Bump Size :
MC141800A
3–290
Pad
X(um)
Y(um)
1-10
49
107
11-87
77
77
88-97
49
107
98-120
107
49
121-248
49
107
249-271
107
49
Die Size (including scribe) :
11226.8 x 2286 (um)
MOTOROLA