F-51852GNFJ-SLW-AEN (AE) No. 2005-0461 OPTREX CORPORATION Page 1/23
LCD Module Technical Specification
F-51852GNFJ-SLW-AEN
Table of Contents
1. General Specifications..................................................................................................................................2
2. Electrical Specifications...............................................................................................................................3
3. Optical Specifications .................................................................................................................................13
4. I/O Terminal....................................................................................................................................................15
5. Test...................................................................................................................................................................17
6. Appearance Standards................................................................................................................................18
7. Code System of Production Lot...............................................................................................................21
8. Type Number..................................................................................................................................................21
9. Applying Precautions ..................................................................................................................................21
10. Precautions Relating Product Handling................................................................................................22
11. Warranty........................................................................................................................................................23
Revision History
Rev. Date Page Comment
Type No.
Dec 6, 2005
First Edition
Final Revision
******
Checked by (ACI Engineering Division)
)
Approved by (Quality Assurance Division)
)
Prepared by (ACI Engineering Division)
T.Yuchi
F-51852GNFJ-SLW-AEN (AE) No. 2005-0461 OPTREX CORPORATION Page 2/23
1. General Specifications
Operating Temp. :min. -20°C ~max. 70°C
Storage Temp. :min. -30°C ~max. 80°C
Dot Pixels :128 (W) × 64 (H) dots
Dot Size :0.484 (W) × 0.484 (H) mm
Dot Pitch :0.499 (W) × 0.499 (H) mm
Viewing Area :69.0 (W) × 36.5 (H) mm
Outline Dimensions :89.7 (W) × 49.8* (H) × 11.8 (D) mm
* Without Flat Cable and LED Cable
Weight :41.2g max.
LCD Type :NSD-22662
( F-STN / Black &White-mode / Transflective )
Viewing Angle :6:00
Data Transfer :8-bit parallel data transfer
Serial data transfer
Backlight :LED Backlight / White
Additional Spec. :Winter White Display
(Highly Reflective Type Transflective Display)
Drawing :Dimensional Outline UE-312414
RoHS regulation :To our best knowledge, this product satisfies material
requirement of RoHS regulation.
Our company is doing the best efforts to obtain
the equivalent certificate from our suppliers.
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2. Electrical Specifications
2.1. Absolute Maximum Ratings VSS=0V
Parameter Symbol Conditions Min. Max. Units
Supply Voltage
(Logic)
VDD-VSS --0.3 7.0 V
Supply Voltage VSS2 With Double *1 -7.0 +0.3 V
(Booster Circuit) With Triple *1 -6.0 +0.3
With Quad *1 -4.5 +0.3
Supply Voltage 1
(LCD Drive)
V5,VOUT *1 -18.0 +0.3 V
Supply Voltage 2
(LCD Drive)
V1, V 2, V 3, V
4
*1 V5+0.3 V
Input Voltage VIN --0.3 VDD+0.3 V
Output Voltage VO--0.3 VDD+0.3 V
*1 Relative to VDD.
The relation of VDD≥V1≥V2≥V3≥V4≥V5>VOUT ;VDD>VSS≥VOUT must be maintained.
In case of inputting external LCD driving voltage, LCD drive voltage should start supplying toNJU6676
at the mean time of turning on VDD power supply or after turned on VDD.
In use of the voltage boost circuit, the condition that the supply voltage : 18V≥ VDD-VOUT is necessary.
Decoupling capacitor should be connected between VDD and VSS due to the stabilized operation for
the voltage converter.
2.2. DC Characteristics Ta=25°C, VSS=0V
Parameter Symbol Conditions Min. Typ. Max. Units
Supply Voltage
(Logic) *1 VDD-VSS -2.2 -5.5 V
Supply Voltage
(Booster Circuit) VSS2 *2-6.0 --2.5 V
Supply Voltage V5*2-18.0 - -6.0 V
(LCD Drive) V1, V 2 *20.4×V5-VDD V
V 3, V 4 *2V5-0.6×V5V
Supply Voltage VSS2 With Triple *2-6.0 - -2.5 V
(Booster Circuit) With Quad *2-4.5 --2.5
Booster Output
Voltage VOUT *2-18.0 - - V
Voltage Regulator
Operating Voltage VOUT2Voltage converter off
External power supply -18.0 --6.0 V
Voltage Follower
Operating Voltage V5Voltage regulator off
External power supply -18.0 - -6.0 V
Base Voltage VREG% VDD=3.0V- - 3.0 %
"High" Level
Input Voltage VIH -0.8×VDD -VDD V
"Low" Level
Input Voltage VIL -VSS -0.2×VDD V
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"High" Level
Output Voltage VOH IOH=-0.5mA 0.8×VDD -VDD V
"Low" Level
Output Voltage VOL IOL=0.5mA VSS -0.2×VDD V
Supply Current IDD VDD-VSS=5.0V-1.06 1.60 mA
*1 Although the NJU6676 can operate in wide range of the operation voltage, it shall not be guaranteed in
a sudden voltage fluctuation during the access with MPU.
*2 Relative to VDD.
Note The internal charge pump circuit of the booster for LCD PNL drive does not have enough power
to drive this module. We highly recommend using an external power supply to drive this module.
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2.3. AC Characteristics
2.3.1. Read/Write Operation Sequence (80 series CPU) VDD=4.5~5.5V
Parameter Symbol Min. Max. Units
Address Hold Time tAH8 0-ns
Address Setup Time tAW8 0-ns
System Cycle Time tCYC8 166 -ns
Control Low Pulse Width(Write) tCCLW 30 -ns
Control Low Pulse Width(Read) tCCLR 70 -ns
Control High Pulse Width(Write) tCCHW 30 -ns
Control High Pulse Width(Read) tCCHR 30 -ns
Data Setup Time tDS8 30 -ns
Data Hold Time tDH8 10 -ns
RD Access Time tACC8 -70 ns
Output Disable Time tOH8 10 50 ns
Input Signal Rise/Fall Time tr, tf-15 ns
VDD=2.7~4.5V
Parameter Symbol Min. Max. Units
Address Hold Time tAH8 0-ns
Address Setup Time tAW8 0-ns
System Cycle Time tCYC8 300 -ns
Control Low Pulse Width(Write) tCCLW 60 -ns
Control Low Pulse Width(Read) tCCLR 120 -ns
Control High Pulse Width(Write) tCCHW 60 -ns
Control High Pulse Width(Read) tCCHR 60 -ns
Data Setup Time tDS8 40 -ns
Data Hold Time tDH8 15 -ns
RD Access Time tACC8 -140 ns
Output Disable Time tOH8 10 100 ns
Input Signal Rise/Fall Time tr, tf-15 ns
VDD=2.2~2.7V
Parameter Symbol Min. Max. Units
Address Hold Time tAH8 0-ns
Address Setup Time tAW8 0-ns
System Cycle Time tCYC8 1000 -ns
Control Low Pulse Width(Write) tCCLW 120 -ns
Control Low Pulse Width(Read) tCCLR 240 -ns
Control High Pulse Width(Write) tCCHW 120 -ns
Control High Pulse Width(Read) tCCHR 120 -ns
Data Setup Time tDS8 80 -ns
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Data Hold Time tDH8 30 -ns
RD Access Time tACC8 -280 ns
Output Disable Time tOH8 10 200 ns
Input Signal Rise/Fall Time tr, tf-15 ns
(READ)
(WRITE)
D0〜
D7
D0〜
D7
WR, RD
t
ACC8
t
OH8
t
AH8
t
DH8
t
DS8
t
AW 8
t
CCL
t
CYC
8
A0, CS
1
t
CCH
t
f
t
r
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2.3.2. Read/Write Operation Sequence (68 series CPU)
VDD=4.5~5.5V
Parameter Symbol Min. Max. Units
Address Hold Time tAH6 0-ns
Address Setup Time tAW60-ns
System Cycle Time tCYC6 166 -ns
Enable High Pulse Width (Read) tEWHR 70 -ns
Enable High Pulse Width (Write) tEWHW 30 -ns
Enable Low Pulse Width (Read) tEWLR 30 -ns
Enable Low Pulse Width (Write) tEWLW 30 -ns
Data Setup Time tDS6 30 -ns
Data Hold Time tDH6 10 -ns
Access Time (CL=100pF) tACC6 -70 ns
Output Disable Time tOH6 10 50 ns
Input Signal Rise/Fall Time tr, tf-15 ns
VDD=2.7~4.5V
Parameter Symbol Min. Max. Units
Address Hold Time tAH6 0-ns
Address Setup Time tAW60-ns
System Cycle Time tCYC6 300 -ns
Enable High Pulse Width (Read) tEWHR 120 -ns
Enable High Pulse Width (Write) tEWHW 60 -ns
Enable Low Pulse Width (Read) tEWLR 60 -ns
Enable Low Pulse Width (Write) tEWLW 60 -ns
Data Setup Time tDS6 40 -ns
Data Hold Time tDH6 15 -ns
Access Time (CL=100pF) tACC6 -140 ns
Output Disable Time tOH6 10 100 ns
Input Signal Rise/Fall Time tr, tf-15 ns
VDD=2.2~2.7V
Parameter Symbol Min. Max. Units
Address Hold Time tAH6 0-ns
Address Setup Time tAW60-ns
System Cycle Time tCYC6 1000 -ns
Enable High Pulse Width (Read) tEWHR 240 -ns
Enable High Pulse Width (Write) tEWHW 120 -ns
Enable Low Pulse Width (Read) tEWLR 120 -ns
Enable Low Pulse Width (Write) tEWLW 120 -ns
Data Setup Time tDS6 80 -ns
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Data Hold Time tDH6 30 -ns
Access Time (CL=100pF) tACC6 -280 ns
Output Disable Time tOH6 10 200 ns
Input Signal Rise/Fall Time tr, tf-15 ns
(READ)
(WRITE)
D0〜D7
D0〜D7
A0, CS
1
WR
(R/W)
t
ACC
6
t
OH
6
t
DH
6
t
DS
6
t
CYC6
RD
(E)
t
AH
6
t
AW 6
t
r
t
f
t
EWH
t
EW
L
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2.3.3. Serial Interface Sequence VDD=4.5~5.5V
Parameter Symbol Min. Max. Units
Serial Clock Cycle tSCYC 200 -ns
Serial Clock High Pulse Width tSHW 75 -ns
Serial Clock Low Pulse Width tSLW 75 -ns
Address Setup Time tSAS 50 -ns
Address Hold Time tSAH 100 -ns
Data Setup Time tSDS 50 -ns
Data Hold Time tSDH 50 -ns
CS-SCL Time tCSS 100 -ns
tCSH 100 -ns
Input Signal Rise/Fall Time tr, tf-15 ns
VDD=2.7~4.5V
Parameter Symbol Min. Max. Units
Serial Clock Cycle tSCYC 250 -ns
Serial Clock High Pulse Width tSHW 100 -ns
Serial Clock Low Pulse Width tSLW 100 -ns
Address Setup Time tSAS 150 -ns
Address Hold Time tSAH 150 -ns
Data Setup Time tSDS 100 -ns
Data Hold Time tSDH 100 -ns
CS-SCL Time tCSS 150 -ns
tCSH 150 -ns
Input Signal Rise/Fall Time tr, tf-15 ns
VDD=2.2~2.7V
Parameter Symbol Min. Max. Units
Serial Clock Cycle tSCYC 400 -ns
Serial Clock High Pulse Width tSHW 150 -ns
Serial Clock Low Pulse Width tSLW 150 -ns
Address Setup Time tSAS 250 -ns
Address Hold Time tSAH 250 -ns
Data Setup Time tSDS 150 -ns
Data Hold Time tSDH 150 -ns
CS-SCL Time tCSS 250 -ns
tCSH 250 -ns
Input Signal Rise/Fall Time tr, tf-15 ns
Each timing is specified based on 0.2×VDD and 0.8×VDD.
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D7(SI)
D6(SCL)
A0
t
CSH
t
CSS
CS1
t
SHW
t
SLW
t
SCYC
t
SAS
t
SAH
t
SDH
t
SDS
t
f
t
r
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2.3.4. Display Control Timing Characteristics
Reset Input Timing VDD=4.5∼5.5V
Parameter Symbol Min. Typ. Max. Units
Reset time tR- - 0.5
Reset ”L” Pulse Width tRW 0.5 - - µs
Reset Input Timing VDD=4.5∼5.5V
Parameter Symbol Min. Typ. Max. Units
Reset time tR- - 1
Reset ”L” Pulse Width tRW 1- - µs
Reset Input Timing VDD=4.5∼5.5V
Parameter Symbol Min. Typ. Max. Units
Reset time tR- - 1.5
Reset ”L” Pulse Width tRW 1.5 - - µs
Each timing is specified based on 0.2×VDD and 0.8×VDD.
Internal
states Reset completeDuring reset
RES
t
RW
t
R
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2.4. Lighting Specifications
2.4.1. Absolute Maximum Ratings Ta=25°C
Parameter Symbol Conditions Min. Typ. Max. Units
Foward Current IFNote 1 - - 120 mA
Reverse Voltage VR- - - 5V
LED Power Dissipation PD- - - 480 mW
Note 1 : Refer to the foward current derating curve.
2.4.2. Operating Characteristics
Parameter Symbol Conditions Min. Typ. Max. Units
Foward Voltage VFIF=60mA -3.5 4.0 V
Luminance of
Module Surface
LIF=60mA 28 48 -cd/m2
7025-20Ta (°C)
48
120
IF (mA)
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3. Optical Specifications
3.1. LCD Driving Voltage
Parameter Symbol Conditions Min. Typ. Max. Units
Recommended Ta= -20°C- - 13.9 V
LCD Driving Voltage VDD-V5Ta=25°C12.2 13.2 14.1 V
Note 1 Ta=70°C11.8 - - V
Note 1 : Voltage (Applied actual waveform to LCD Module) for the best contrast. The
range of minimum and maximum shows tolerance of the operating voltage. The
specified contrast ratio and response time are not guaranteed over the entire range.
3.2. Optical Characteristics Ta=25°C, 1/65 Duty, 1/9 Bias, VOD=13.2V (Note 4), θ= 0°, φ=-°
Parameter Symbol Conditions Min. Typ. Max. Units
Contrast Ratio Note 1 CR θ= 0°C , φ=-°-4.5 -
Viewing Angle Shown in 3.3
Response Rise Note 2 TON - - 150 230 ms
Time Decay Note 3 TOFF - - 200 300 ms
Note 1 :Contrast ratio is definded as follows. (CR = LON / LOFF)
LON :Luminance of the ON segments
LOFF:Luminance of the OFF segments
Measuring Spot : 3.0mmφ
Note 2 :The time that the luminance level reaches 90% of the saturation level from 0%
when ON signal is applied.
Note 3 :The time that the luminance level reaches 10% of the saturation level from
100% when OFF signal is applied.
Note 4 :Definition of Driving Voltage VOD
VOD=VCC-VADJ-VBE
Assuming that the typical driving waveforms shown below are applied to the LCD
Panel at 1/A Duty - 1/B Bias (A: Duty Number, B: Bias Number). Driving voltage
VOD is definded as follows.
VOD = (Vth1+Vth2) / 2
Vth1: The voltage VO-P that should provide 70% of the saturation level in the
luminance at the segment which the ON signal is applied to.
Vth2: The voltage VO-P that should provide 20% of the saturation level in the
luminance at the segment which the OFF signal is applied to.
Vo-p
1 /fF
( B-2 ) ×Vo-p/B
1/( fF×A )
( OFF SIGNAL )
( ON SIGNAL )
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3.3. Definition of Viewing Angle and Optimum Viewing Area
*Point • shows the point where contrast ratio is measured. : θ= 0°, φ=-°
*Driving condition: 1/65 Duty, 1/9 Bias, VOD=13.2V, fF=84.6Hz
270°
0
°
90
°
180°
270°
θ
φ
135°
315°225°
45°
180°
90°
(φ = 0°)
φ
10
20
30
40
50
θ
*Area shows typ. CR≥2(Measuring Spot : 3.0mmφ)
3.4. System Block Diagram
Halogen bulb
Computer
Rotation Table ( θ,φ )
Temperature Chamber
LCD
Optical Fiber
Waveform Generator
Control Unit &
#1980A WB
Photometer φ
θ
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4. I/O Terminal
4.1. Pin Assignment
CN1
No. Symbol Function
1CS1Chip Select Signal L : Active
2RES Reset Signal L : Reset
3A0 H : D0~D7 are Display Data L : D0~D7 are Instructions
4WR 80 family CPU : Write Signal L : Active
5RD 80 family CPU : Read Signal L : Active
6D0 Display Data
7D1 Display Data
8D2 Display Data
9D3 Display Data
10 D4Display Data
11 D5Display Data
12 D6(SCL) Display Data(Serial Data Clock Signal Input)
13 D7(SI) Display Data(Serial Data Input)
14 VDD Power Supply for Logic
15 VSS Power Supply ( 0V, GND )
16 VOUT DC/DC Voltage Converter Output
17 C3-DC/DC Voltage Converter Negative Connection
18 C1+ DC/DC Voltage Converter Positive Connection
19 C1- DC/DC Voltage Converter Negative Connection
20 C2- DC/DC Voltage Converter Negative Connection
21 C2+ DC/DC Voltage Converter Positive Connection
22 V1Power Supply for LCD Drive V1 = 1/9⋅V5
23 V2Power Supply for LCD Drive V2 = 2/9⋅V5
24 V3Power Supply for LCD Drive V3 = 7/9⋅V5
25 V4Power Supply for LCD Drive V4 = 8/9⋅V5
26 V5Power Supply for LCD Drive V5,VOUT
27 VR Voltage Adjustment Pin
Applies voltage between VCC and V5 using a resistive divider.
28 C86 Interface Mode Select Signal H : 68 series L : 80 series
29 P/S Parallel/Serial Data Select Signal H : Parallel L : Serial
30 NC Non-connection
CN2
No. Symbol Function
1LED A LED Anode Terminal
2LED K LED Cathode Terminal
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4.2. Block Diagram
V2
V3
Control LSI
NJU6676
L C D P
128 × 64 dots
SEG 128
COM 64
C2-
C2+
C3-
C1+
C1-
CS1
RES
VR
C86
V5
P/S
V4
V1
A0
WR
RD
D0∼
D7
VDD
VSS
VOUT
8
LED Backlight
LED K
LED A
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5. Test
No change on display and in operation under the following test condition.
Conditions: Unless otherwise specified, tests will be conducted under the following condition.
Temperature: 20±5°C
Humidity : 65±5%RH
tests will be not conducted under functioning state.
No. Parameter Conditions Notes
1High Temperature Operating 70°C±2°C, 96hrs (operation state)
2Low Temperature Operating -20°C±2°C, 96hrs (operation state) 1
3High Temperature Storage 80°C±2°C, 96hrs 2
4Low Temperature Storage -30°C±2°C, 96hrs 1,2
5Damp Proof Test 40°C±2°C,90~95%RH, 96hrs 1,2
6Vibration Test Total fixed amplitude : 1.5mm 3
Vibration Frequency : 10~55Hz
One cycle 60 seconds to 3 directions of X, Y, Z for
each 15 minutes
7Shock Test To be measured after dropping from 60cm high on
the concrete surface in packing state.
Note 1 :No dew condensation to be observed.
Note 2 :The function test shall be conducted after 4 hours storage at the normal
Temperature and humidity after removed from the test chamber.
Note 3 :Vibration test will be conducted to the product itself without putting it in a container.
E
A
G
D
C
F
60cm
Concrete Surface
Dropping method corner dropping
E,F,G face : once
B,C,D edge : once
A corner : once
Face dropping
Edge dropping
B
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6. Appearance Standards
6.1. Inspection conditions
The LCD shall be inspected under 40W white fluorescent light.
The distance between the eyes and the sample shall be more than 30cm.
All directions for inspecting the sample should be within 45°against perpendicular line.
6.2. Definition of applicable Zones
A Zone : Active display area
B Zone : Out of active display area ~ Maximum seal line
C Zone : Rest parts
A Zone + B Zone = Validity viewing area
45
°
X : Maximum Seal Line
X
X
X
X
A Zone
B Zone
C Zone
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6.3. Standards(middle scale, LED) D = ( Long + Short ) / 2 * : Disregard Units : mm
No. Parameter Criteria
1The Shape of Dot (1) Pin Hole
Dimension Acceptable Number
D ≤ 0.10 *
1 pc / dot or less
0.10 < D ≤ 0.20 5 pcs / cell or less
(2) Breakage or Chips / Deformation
1.Dot Type
Dimension Acceptable Number
A≤0.10*
(Should not be connected to next dot)
1 pc / dot(only segment)or less
5 pcs / cell or less0.10<A≤0.15
(Should not be connected to next dot)
B ≤ 0.15 *
2.Defective type extends over multiple numbers of dots
Dimension Acceptable Number
D≤0.10*
1 pc / dot(only segment)or less
5 pcs / cell or less
(Individual dot must secure 1/2 area
0.10<D≤0.20
or more)
A
B
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D = ( Long + Short ) / 2 * : Disregard Units : mm
No. Parameter Criteria
2Black and (1) Round Shape
White Spots, Zone Acceptable Number
Foreign Substances Dimension A B C
D ≤ 0.10 * * *
0.10< D ≤ 0.20 6 6 *
0.20< D ≤ 0.30 4 4 *
Individual dot must secure 1/2 area or more.
(2) Line Shape
Zone Acceptable Number
Length Width A B C
* W≤0.03 * * *
L ≤2.0 0.03<W≤0.05 5 5 *
L ≤1.0 ≤0.10 4 4 *
* 0.10<W In the same way (1) *
No more than 9pcs as total.
(Refer to “Complex Foreign Substance Defects”)
3Color Variation Not to be conspicuous defects.
4Air Bubbles
(between glass Zone Acceptable Number
& polarizer) Dimension A B C
D ≤ 0.30 * * *
0.30< D ≤ 0.40 3* *
0.40< D ≤ 0.60 2 3 *
No more than 3pcs as total.
(Refer to “Complex Foreign Substance Defects”)
5Polarizer Scratches Not to be conspicuous defects.
6Polarizer Dirts If the stains are removed easily from LCDP surface, the module is
not defective.
7Complex Foreign Black spots, line shaped foreign substances or air bubbles between
Substance Defects glass & polarizer should be 9pcs maximum in total.
8Distance between 20mm or more
Different Foreign
Substance Defects
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7. Code System of Production Lot
The production lot of module is specified as follows.
Factory Control Number (0~99)
Date of the week (A~G)
Factory Number (0~9)
Factory Code (Alphabet)
Production Week (1~5)
Production Month (1~9, X, Y, Z)
Production Year (Lower 2 digits)
8. Type Number
The type number of module is specified as follows.
F-51852GNFJ-SLW-AEN
9. Applying Precautions
Please contact us when questions and/or new problems not specified in this
Specifications arise.
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10. Precautions Relating Product Handling
The Following precautions will guide you in handling our product correctly.
1) Liquid crystal display devices
1. The liquid crystal display device panel used in the liquid crystal display module is
made of plate glass. Avoid any strong mechanical shock. Should the glass break
handle it with care.
2. The polarizer adhering to the surface of the LCD is made of a soft material.
Guard against scratching it.
2) Care of the liquid crystal display module against static electricity discharge.
1. When working with the module, be sure to ground your body and any electrical
equipment you may be using. We strongly recommend the use of anti static mats
( made of rubber ), to protect work tables against the hazards of electrical shock.
2. Avoid the use of work clothing made of synthetic fibers. We recommend cotton
clothing or other conductivity-treated fibers.
3. Slowly and carefully remove the protective film from the LCD module, since this
operation can generate static electricity.
3) When the LCD module alone must be stored for long periods of time:
1. Protect the modules from high temperature and humidity.
2. Keep the modules out of direct sunlight or direct exposure to ultraviolet rays.
3. Protect the modules from excessive external forces.
4) Use the module with a power supply that is equipped with an overcurrent protector
circuit,since the module is not provided with this protective feature.
5) Do not ingest the LCD fluid itself should it leak out of a damaged LCD module. Should
hands or clothing come in contact with LCD fluid, wash immediately with soap.
6) Conductivity is not guaranteed for models that use metal holders where solder
connections between the metal holder and the PCB are not used. Please contact us
to discuss appropriate ways to assure conductivity.
7) For models which use CFL:
1. High voltage of 1000V or greater is applied to the CFL cable connector area.
Care should be taken not to touch connection areas to avoid burns.
2. Protect CFL cables from rubbing against the unit and thus causing the wire jacket to
become worn.
3. The use of CFLs for extended periods of time at low temperatures will significantly
shorten their service life.
8) For models which use touch panels:
1. Do not stack up modules since they can be damaged by components on neighboring
modules.
2. Do not place heavy objects on top of the product. This could cause glass breakage.
9) For models which use COG,TAB,or COF:
1. The mechanical strength of the product is low since the IC chip faces out unprotected
from the rear. Be sure to protect the rear of the IC chip from external forces.
2. Given the fact that the rear of the IC chip is left exposed, in order to protect the unit
from electrical damage, avoid installation configurations in which the rear of the IC
chip runs the risk of making any electrical contact.
F-51852GNFJ-SLW-AEN (AE) No. 2005-0461 OPTREX CORPORATION Page 23/23
10) Models which use flexible cable, heat seal, or TAB:
1. In order to maintain reliability, do not touch or hold by the connector area.
2. Avoid any bending, pulling, or other excessive force, which can result in broken
connections.
11) In case of buffer material such as cushion / gasket is assembled into LCD module,
it may have an adverse effect on connecting parts ( LCD panel-TCP / HEAT SEAL / FPC /
etc., PCB-TCP / HEAT SEAL / FPC etc., TCP-HEAT SEAL, TCP-FPC, HEAT SEAL-FPC,
etc.,) depending on its materials.
Please check and evaluate these materials carefully before use.
12) In case of acrylic plate is attached to front side of LCD panel, cloudiness ( very small
cracks ) can occur on acrylic plate, being influenced by some components generated
from polarizer film..
Please check and evaluate those acrylic materials carefully before use.
11. Warranty
This product has been manufactured to your company’s specifications as a part for use in
your company’s general electronic products. It is guaranteed to perform according to
delivery specifications. For any other use apart from general electronic equipment, we
cannot take responsibility if the product is used in medical devices, nuclear power control
equipment, aerospace equipment, fire and security systems, or any other applications in
which there is a direct risk to human life and where extremely high levels of reliability are
required. If the product is to be used in any of the above applications, we will need to enter
into a separate product liability agreement.
1. We cannot accept responsibility for any defect, which may arise from additional
manufacturing of the product (including disassembly and reassembly), after
product delivery.
2. We cannot accept responsibility for any defect, which may arise after the application
of strong external force to the product.
3. We cannot accept responsibility for any defect, which may arise due to the application
of static electricity after the product has passed your company’s acceptance inspection
procedures.
4. When the product is in CFL models, CFL service life and brightness will vary
According to the performance of the inverter used, leaks, etc. We cannot accept
responsibility for product performance, reliability, or defect, which may arise.
5. We cannot accept responsibility for intellectual property of a third party, which may
arise through the application of our product to your assembly with exception to those
issues relating directly to the structure or method of manufacturing of our product.
6. Optrex will not be held responsible for any quality guarantee issue for defect products
judged as Optrex-origin longer than 2 (two) years from Optrex production or 1(one)
year from Optrex, Optrex America, Optrex Europe delivery which ever comes later.
