G260JJE-L07 26" Innolux TFT Display for industrial

PRODUCT SPECIFICATION

Doc. Number :

□ Tentative Specification

□ Preliminary Specification

■ Approval Specification

MODEL NO.: G260JJE

SUFFIX: L07

Customer:

APPROVED BY SIGNATURE

Name / Title

Note

Please return 1 copy for your confirmation with your signature and comments.

Approved By

張喻翔 /514

8:40

10922))))

CS

T

Checked By

張喻翔 /514 10922))))

18:38:40 CST

Prepared By

黃名福 /514

10:18:07 CST

- CONTENTS -

Version 2.0 Dec 17, 2013 1/27

The copyright belongs to InnoLux. Any unauthorized use is prohibited.

Provided by www.display-solution.com

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REVISION HISTORY

1. GENERAL DESCRIPTION

1.1 OVERVIEW

1.2 GENERAL SPECIFICATIONS

1.3 MECHANICAL SPECIFICATIONS

2. ABSOLUTE MAXIMUM RATINGS

2.1 ABSOLUTE RATINGS OF ENVIRONMENT

2.2 ELECTRICAL ABSOLUTE RATINGS

2.2.1 TFT LCD MODULE

2.2.2 BACKLIGHT UNIT

3. ELECTRICAL CHARACTERISTICS

3.1 TFT LCD MODULE

3.2 BACKLIGHT UNIT

4. BLOCK DIAGRAM

4.1 TFT LCD MODULE

4.2 BACKLIGHT UNIT

5. INPUT TERMINAL PIN ASSIGNMENT

5.1 TFT LCD MODULE

5.2 BACKLIGHT UNIT

5.3 COLOR DATA INPUT ASSIGNMENT

6. INTERFACE TIMING

6.1 INPUT SIGNAL TIMING SPECIFICATIONS

6.

2 POWER ON/OFF SEQUENCE

6.3 VDD Power DIP Condition

7. OPTICAL CHARACTERISTICS

7.1 TEST CONDITIONS

7.2 OPTICAL SPECIFICATIONS

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3

4

5

7

11

12

15

17

8. Reliability Test Criteria ------------------------------------------------------ 21

9. PACKAGING

9.1 PACKING SPECIFICATIONS

9.2 PACKING METHOD

9.3 UN-PACKING METHOD

10. DEFINITION OF LABELS

10.1 Innolux MODULE LABEL

11. PRECAUTIONS

11.1 ASSEMBLY AND HANDLING PRECAUTIONS

11.2 SAFETY PRECAUTIONS

12. MECHANICAL CHARACTERISTICS

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REVISION HISTORY

Description Version

2.0

Date

Dec 17, 2013

Section

All G260JJE-L07 Approval Spec. was first issued.

Version 2.0 Dec 17, 2013 3/27



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1. GENERAL DESCRIPTION

1.1 OVERVIEW

G260JJE-L07 model is a 25.54” MVA TFT-LCD module with a white LED Backlight Unit and a 30 pins 2 channels LVDS interface. This module supports 1920 x 1200 WUXGA mode and can display up to 16.7 millions colors. The converter for the Backlight Unit is built in.

1.2 GENERAL SPECIFICATIONS

Item

Active Area

Bezel Opening Area

Driver Element

Pixel Number

Pixel Pitch

Pixel Arrangement

Display Colors

Transmissive Mode

Surface Treatment

Specification

550.08 (H) x 343.8 (V) (25.54” diagonal)

554.1 (H) x 347.8 (V) a-Si TFT active matrix

1920 x R.G.B. x 1200

0.2865 (H) x 0.2865 (V)

RGB vertical stripe

16.7M

Normally black

AG type, 3H hard coating,

Unit

mm mm

- pixel mm

- color

-

-

Note

(1)

-

-

-

-

-

-

-

1.3 MECHANICAL SPECIFICATIONS

Item

Horizontal(H)

Module Size

Vertical(V)

Depth(D)

Weight

Min.

581.5

375.1

29.6

-

Typ.

582.0

375.6

30.1

3650

Max.

582.5

376.1

30.6

3850

Unit

mm mm mm g

Note

(1)

-

Note (1) Please refer to the attached drawings for more information of front and back outline dimensions.

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2. ABSOLUTE MAXIMUM RATINGS

2.1 ABSOLUTE RATINGS OF ENVIRONMENT

Item

Storage Temperature

Operating Ambient Temperature

Shock (Non-Operating)

Vibration (Non-Operating)

Symbol

T

ST

T

OP

S

NOP

V

NOP

Min.

-20

0

-

-

Value

Max.

60

50

40

1.5

Note (1) Temperature and relative humidity range is shown in the figure below.

(a) 90 %RH Max. (Ta < 40 ºC).

Unit

(b) Wet-bulb temperature should be 39 ºC Max. (Ta < 40 ºC).

(c) No condensation.

Note (2) The temperature of panel display surface area should be 0 ºC Min. and 60 ºC Max

-40

Relative Humidity (%RH)

100

80

60

40

Operating Range

20

10

Storage Range

-20 0 20

Temperature (ºC)

40 60

ºC

ºC

G

G

80

Note

(1)

(1), (2)

(3), (5)

(4), (5)

Note (3) 1 time for ± X, ± Y, ± Z. for Condition (40G / 11ms) is half Sine Wave.

Note (4) f＝10～300Hz, 1.5G, 10min/cycles,3cycles each X, Y, Z

Note (5) At testing Vibration and Shock, the fixture in holding the module has to be hard and rigid enough so that the module would not be twisted or bent by the fixture.

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The fixing condition is shown as below:

At room Temperature

LCD Module

Side Mount Fixing

Side Mount Fixing

Stage

Gap=2mm

Bracket

LCD Module

2.2 ELECTRICAL ABSOLUTE RATINGS

2.2.1 TFT LCD MODULE

Y Direction

Value

Item Symbol

X Direction

Power Supply Voltage Vcc

Min.

-0.3

Max.

+6.0

Stage

Bracket

Gap=2mm

Unit

V

Note

(1)

2.2.2 BACKLIGHT UNIT

Item

Value

Typ.

37.2

720

Max.

40.8

780

Unit Note

LED Light Bar Input voltage

LED Light Bar Input Current

Min

-

-

V

DC

A

DC

(1), (2)

Note (1) Permanent damage to the device may occur if maximum values are exceeded. Function operation should be restricted to the conditions described under Normal Operating Conditions.

Note (2) Specified values are for LED (Refer to Section 3.2 for further information).

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3. ELECTRICAL CHARACTERISTICS

3.1 TFT LCD MODULE

Ta = 25 ± 2 ºC

Parameter

Power Supply Voltage

Symbol

Vcc

Min.

4.5

Value

Typ.

5.0

Max.

5.50

Unit

V

Note

-

Ripple Voltage

Rush Current

Power Supply Current

White

Black

Vertical Stripe

V

RP

I

RUSH

-

-

-

-

-

-

-

-

-

-

1.36

0.9

1.4

100

3.8

1.9

1.26

1.96 mV

A

A

A

A

-

(2)

(3)a

(3)b

(3)c

LVDS Differential Input High Threshold VTH(LVDS) - - +100 mV Vic=1.2V

-

600

-

0.8 mV Vic=1.2V mV

V

V

LVDS Differential Input Low Threshold VTL(LVDS) -100 -

LVDS differential input voltage

LVDS common input voltage

Logic “L” input voltage

Vid

Vic

Vil

100

-

Vss

Note (1) The assembly should be always operated within above ranges.

Note (2) Measurement Conditions:

+5.0V

Q1 2SK1475

FUSE

R1

47K

(High to Low)

(Control Signal)

SW

R2

Q2

2SK1470

+12V

1K

VR1

47K

C2

C1

0.01uF

1uF

-

1.2

-

C3

1uF

Vcc

(LCD Module Input)

VCC

0.9Vcc

0.1Vcc

GND

470µs

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Note (3) The specified power supply current is under the conditions at Vcc = 5.0 V, Ta = 25 ± 2 ºC, f v

= 60

Hz, whereas a power dissipation check pattern below is displayed. a. White Pattern b. Black Pattern

Active Area c. Vertical Stripe Pattern

Active Area

B

R

R

Active Area

G B

G B

R G B

R G B R

B R G B R G B R

R G B R G B

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3.2 BACKLIGHT UNIT

Parameter

Converter Power Supply Voltage

Converter Power Supply Current

LED Power Consumption

EN Control Level

PWM Control Level

Backlight on

Backlight off

PWM High Level

PWM Low Level

PWM Control Duty Ratio

PWM Control Frequency

LED Life Time

Symbol

V i

I i

P

O

EN1,

EN2

PWM1,

PWM2 f

PWM

L

L

Ta = 25 ± 2 ºC

Min.

21.6

---

---

2

0

2.0

0

1

100

50,000

Value

Typ. Max.

Unit

24.0 26.4 V

1.2

30

3.3

1.5

35

5.0

A

W

V

Note

(Duty 100%)

@ Vi = 24V

(Duty 100%)

@ Vi = 24V

(Duty 100%),(3)

0

3.3

0

0.8

5.0

0.8

V

V

V

200

100 %

210 Hz

Hrs (1), (2)

Note (1) LED current is measured by utilizing a high frequency current meter as shown below:

Note (2) The lifetime of LED is defined as the time when it continues to operate under the conditions at

Ta = 25±2 ℃ and I

LED

= 60mA

DC

(LED forward current) until the brightness becomes

≦

50% of its original value.

Note (3) P

O

= I o

×V o

EN,_E_PWM

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Power sequence and control signal timing are shown in the following figure

+24V

EN

E_PWM

0

0

0

Tr<200ms

>50ms

T>=10ms

>10ms

Note ：While system is turned ON or OFF, the power sequences must follow as below descriptions:

Turn ON sequence: Vi(+24V) → EN → E_PWM signal

Turn OFF sequence: E_PWM signal → EN → Vi(+24V)

INPUT TERMINAL PIN ASSIGNMENT

Pin Name

1 Vi

2 Vi

3 Vi

4 Vi

5 Vi

6 GND

7 GND

8 GND

9 GND

10 GND

11 NC

12 EN

13 NC

14 E_PWM

Description

Converter Power Supply(+24V)





Ground

Ground

Ground

Ground

Ground

No connection

Enable Control (for light Bar)

No connection

Dimming Control (for light Bar)

Note (1) Connector Part No.: CvILux CI0114M1HR0-LA or FCN_JH2-D4-143N or equivalent.

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4. BLOCK DIAGRAM


RXO0(+/-)

RXO1(+/-)

RXO2(+/-)

RXO3(+/-)

RXOC(+/-)

RXE0(+/-)

RXE1(+/-)

RXE2(+/-)

RXE3(+/-)

RXEC(+/-)

NC

Vcc

GND

V

L

LED Converter

LVDS INPUT /

TIMING CONTROLLER

DC/DC CONVERTER &

REFERENCE VOLTAGE

TFT LCD PANEL

(1920x3x1200)

DATA DRIVER IC

BACKLIGHT UNIT

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5. INPUT TERMINAL PIN ASSIGNMENT


Pin Name

1 RXO0-

Description

Negative LVDS differential data input. Channel O0 (odd)

2 RXO0+ Positive LVDS differential data input. Channel O0 (odd)

3 RXO1-

4 RXO1+

5 RXO2-

6 RXO2+

7 GND

8 RXOC-

9 RXOC+

10 RXO3-

11 RXO3+

12 RXE0-

13 RXE0+

14 GND

15 RXE1-

16 RXE1+

17 GND

18 RXE2-

19 RXE2+

20 RXEC-

21 RXEC+

22 RXE3-

23 RXE3+

24 GND

25 NC

26 NC

27 VCC

28 VCC

29 VCC

30 VCC


Positive LVDS differential data input. Channel O1 (odd)



Ground

Negative LVDS differential clock input. (odd)

Positive LVDS differential clock input. (odd)

Negative LVDS differential data input. Channel O3(odd)


Negative LVDS differential data input. Channel E0 (even)

Positive LVDS differential data input. Channel E0 (even)

Ground



Ground



Negative LVDS differential clock input. (even)

Positive LVDS differential clock input. (even)



Ground

No connection, this pin should be opened.

No connection, this pin should be opened.

+5.0V power supply

+5.0V power supply

+5.0V power supply

+5.0V power supply

Note (1) Connector Part No.: P2 187114-30091 or equivalent.

Note (2) The first pixel is odd.

Note (3) Input signal of even and odd clock should be the same timing.

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5.2 The Input Data Format

LVDS Channel O0

LVDS Channel O1

LVDS Channel O2

LVDS Channel O3

LVDS Channel E0

LVDS Channel E1

LVDS Channel E2

LVDS Channel E3

LVDS output

Data order

LVDS output

Data order

LVDS output

Data order

LVDS output

Data order

LVDS output

Data order

LVDS output

Data order

LVDS output

Data order

LVDS output

Data order

D7

OG0

D18

OB1

D26

DE

D23

NA

D7

EG0

D18

EB1

D26

DE

D23

NA

D6

OR5

D15

OB0

D25

NA

D17

OB7

D6

ER5

D15

EB0

D25

NA

D17

EB7

D3

OR3

D13

OG4

D22

OB5

D11

OG7

D3

ER3

D13

EG4

D22

EB5

D11

EG7

D4

OR4

D14

OG5

D24

NA

D16

OB6

D4

ER4

D14

EG5

D24

NA

D16

EB6

D1

OR1

D9

OG2

D20

OB3

D5

OR7

D1

ER1

D9

EG2

D20

EB3

D5

ER7

D2

OR2

D12

OG3

D21

OB4

D10

OG6

D2

ER2

D12

EG3

D21

EB4

D10

EG6

D0

OR0

D8

OG1

D19

OB2

D27

OR6

D0

ER0

D8

EG1

D19

EB2

D27

ER6

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5.3 COLOR DATA INPUT ASSIGNMENT

The brightness of each primary color (red, green and blue) is based on the 8-bit gray scale data input for the color. The higher the binary input, the brighter the color. The table below provides the assignment of color versus data input.

Color

Basic

Colors

Gray

Scale

Of

Red

Black

Red

Green

Blue

Cyan

Magenta

Yellow

White

Red(0) / Dark

Red(1)

Red(2)

:

:

Red(253)

Red(254)

Red(255)

Data Signal

Red Green Blue

R7 R6 R5 R4 R3 R2 R1 R0 R7 R6 G5 G4 G3 G2 G1 G0 R7 R6 B5 B4 B3 B2 B1 B0

1

1

1

0

0

:

:

0

1

1

1

0

1

0

0

0

1

1

1

0

0

:

:

0

1

1

1

0

1

0

0

0

1

1

1

0

0

:

:

0

1

1

1

0

1

0

0

0

0

1

0

0

0

1

1

1

0

0

0

:

:

1

1

1

0

1

0

0

0

1

1

1

0

0

0

:

:

1

1

1

0

1

0

0

0

1

1

1

0

0

0

:

:

1

1

1

0

1

0

0

0

1

1

1

0

0

1

:

:

0

1

1

0

1

0

0

0

1

1

1

0

1

0

:

:

1

0

1

0

0

1

0

1

0

1

1

0

0

0

:

:

0

0

0

0

0

1

0

1

0

1

1

0

0

0

:

:

0

0

0

0

0

1

0

1

0

1

1

0

0

0

:

:

0

0

0

0

0

1

0

1

0

1

1

0

0

0

:

:

0

0

0

0

0

1

0

1

0

1

1

0

0

0

:

:

0

0

0

0

0

1

0

1

0

1

1

0

0

0

:

:

0

0

0

0

0

1

0

1

0

1

1

0

0

0

:

:

0

0

0

0

0

1

0

1

0

1

1

0

0

0

:

:

0

0

0

0

0

0

1

1

1

0

1

0

0

0

:

:

0

0

0

0

0

0

1

1

1

0

1

0

0

0

:

:

0

0

0

0

0

0

1

1

1

0

1

0

0

0

:

:

0

0

0

0

0

0

1

1

1

0

1

0

0

0

:

:

0

0

0

0

0

0

1

1

1

0

1

0

0

0

:

:

0

0

0

0

0

0

0

0

:

:

1

1

0

1

0

0

0

1

0

0

0

0

0

0

:

:

1

1

0

1

0

0

0

1

0

0

0

0

0

0

:

:

1

1

0

1

0

0

0

1

0

Gray

Scale

Of

Green

Gray

Scale

Of

Blue

Green(0) / Dark

Green(1)

Green(2)

:

:

Green(253)

Green(254)

Green(255)

Blue(0) / Dark

Blue(1)

Blue(2)

:

:

Blue(253)

Blue(254)

Blue(255)

0

0

0

0

0

:

:

:

0

0

0

0

0

0

:

0

0

0

0

0

0

:

:

:

0

0

0

0

0

0

:

0

0

0

0

:

:

0

0

0

0

0

0

:

:

0

0

0

0

0

0

:

:

0

0

0

0

0

0

:

:

0

0

0

0

0

0

0

0

:

:

:

0

0

0

0

0

0

:

0

0

0

0

0

0

:

:

:

0

0

0

0

0

0

:

0

0

0

0

0

0

:

:

:

0

0

0

0

0

0

:

0

Note (1) 0: Low Level Voltage, 1: High Level Voltage

0

0

0

0

0

:

:

:

1

1

1

0

0

0

:

0

0

0

0

0

0

:

:

:

1

1

1

0

0

0

:

0

0

0

0

0

0

:

:

:

1

1

1

0

0

0

:

0

0

0

0

0

0

:

:

:

0

0

0

0

0

0

:

0

0

0

0

0

0

:

:

:

1

1

1

0

0

0

:

0

0

0

0

0

0

:

:

:

1

1

1

0

0

0

:

0

0

0

0

0

0

:

:

:

0

1

1

0

0

1

:

0

0

0

0

0

0

:

:

:

1

1

1

0

0

0

:

0

1

1

1

0

0

:

:

:

0

0

0

0

0

0

:

0

1

1

1

0

0

:

:

:

0

0

0

0

0

0

:

0

0

0

0

0

0

:

:

:

1

0

1

0

1

0

:

0

1

1

1

0

0

:

:

:

0

0

0

0

0

0

:

0

1

1

1

0

0

:

:

:

0

0

0

0

0

0

:

0

1

0

1

1

0

:

:

:

0

0

0

0

0

0

:

0

0

1

1

0

1

:

:

:

0

0

0

0

0

0

:

0

1

1

1

0

0

:

:

:

0

0

0

0

0

0

:

0

1

1

1

0

0

:

:

:

0

0

0

0

0

0

:

0

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6. INTERFACE TIMING

6.1 INPUT SIGNAL TIMING SPECIFICATIONS

The input signal timing specifications are shown as the following table and timing diagram.

Signal

LVDS Clock

LVDS Data

Vertical Active Display Term

Horizontal Active Display Term

Item

Frequency

Period

High Time

Symbol Min.

Fc 50.0

Tc

Tch

-

-

Low Time Tcl

Setup Time Tlvs

Hold Time Tlvh

-

600

600

Frame Rate

Total

Display

Blank

Total

Display

Blank

Fr

Tv

Tvd

Tvb

Th

Thd

Thb

40

1209

1200

9

1030

960

70

Typ.

77

13.0

4/7

3/7

-

-

60

1235

Max. Unit

83.0 MHz

-

-

-

-

-

63

1245 ns

Tc

Tc ps ps

Note

-

-

-

-

-

Hz Tv=Tvd+Tvb

Th -

1200 1200

35 Tv-Tvd

Th

Th

1040

960

80

1060

960

Th-Thd

Tc

Tc

Tc

-

-

Th=Thd+Thb

-

-

Note: Because this module is operated by DE only mode, Hsync and Vsync input signals should be set to low logic level or ground. Otherwise, this module would operate abnormally.

INPUT SIGNAL TIMING DIAGRAM

T v

DE

DCLK

DE

DATA

T

C

T

Vd

T hb

T h

T hd

T

Vb

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6.2 POWER ON/OFF SEQUENCE

To prevent a latch-up or DC operation of LCD module, the power on/off sequence should be as the diagram below.

Power On Power Off Restart

- Power Supply for LCD, Vcc

- Interface Signal

(LVDS Signal of

Transmitter), V

I

- Power for LED

0V

0V

10%

90% t1

OFF t2 t5

50%

Valid Data

ON

90% t6 t3

50%

OFF t4

10%

Timing Specifications:

0.5< t1 ≦ 10 msec

0 < t2 ≦ 50 msec

0 < t3 ≦ 50 msec t4 ≧ 500 msec t5 ≧ 500 msec t6 ≧ 90 msec

6.3 VDD Power DIP Condition

Td

4.0V

4.5V

Vcc

Dip condition:

4 .

0

V

≤

Vcc

≤ 4 .

5

V

,

Td

≤ 20

ms

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7. OPTICAL CHARACTERISTICS

7.1 TEST CONDITIONS

Item

Ambient Temperature

Ambient Humidity

Supply Voltage

Input Signal

Converter PWM duty

Symbol

Ta

Value

25±2

Unit

o

C

Ha

V

CC

50±10

5

%RH

V

According to typical value in "3. ELECTRICAL CHARACTERISTICS"

100%

7.2 OPTICAL SPECIFICATIONS

The relative measurement methods of optical characteristics are shown in 7.2. The following items should be measured under the test conditions described in 7.1 and stable environment shown in Note (5).

Item

Contrast Ratio

Response Time

Center Luminance of White

White Variation

Color

Chromaticity

Viewing Angle

Red

Green

Blue

White

Horizontal

Vertical

Symbol

CR

Gx

Gy

Bx

By

T

R

T

F

L

C

δW

Rx

Ry

Wx

Wy

θ x

+

θ x

-

θ

Y

+

θ

Y

-

Condition

θ x

=0°,θ

Y

=0°

Viewing Normal

Angle

CR≥10

Min.

1000

-

-

300

-

Typ.-

0.05

80

80

80

80

Typ.

1500

15

5

350

1.4

0.638

0.342

0.310

0.616

0.153

0.055

0.313

0.329

88

88

88

88

-

-

-

-

Max.

-

-

-

-

1.5

Typ.+

0.05

Unit Note

- (2), (5)

-

-

-

-

-

-

-

- ms

(3) ms cd/m

2

(4), (5)

- (5), (6)

(1),

(5)

Deg.

(1),

(5)

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Note (1) Definition of Viewing Angle (θx, θy):

Normal

θx = θy = 0º

θ

X-

= 90º

6 o’clock

θ y-

= 90º y- x-

θy-

θx−

θ y+

θx+ y+

12 o’clock direction

θ y+

= 90º x+

θ

X+

= 90º

Note (2) Definition of Contrast Ratio (CR):

The contrast ratio can be calculated by the following expression.

Contrast Ratio (CR) = L255 / L0

L255: Luminance of gray level 255

L 0: Luminance of gray level 0

CR = CR (5)

CR (X) is corresponding to the Contrast Ratio of the point X at Figure in Note (6).

Note (3) Definition of Response Time (T

R

, T

F

) and measurement method:

100%

90%

Optical

Response

10%

0%

Gray Level 255

T

F

Gray Level 0

T

R

Gray Level 255

Time

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Note (4) Definition of Luminance of White (L

C

):

L

C

= L (1), where L (X) is corresponding to the luminance of the point X at the figure in Note (6)

Note (5) Measurement Setup:

The LCD module should be stabilized at given temperature for 20 minutes to avoid abrupt temperature change during measuring. In order to stabilize the luminance, the measurement should be executed after lighting Backlight for 20 minutes in a windless room.

LCD Module

LCD Panel

USB2000

Center of the Screen

500 mm

CS-1000T

Light Shield Room

(Ambient Luminance < 2 lux)

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Note (6) Definition of White Variation (δW):

Measure the luminance of gray level 255 at 13 points

Maximum [L (1), L (2), L (3), L (4), L (5),L (6),L (7),L (8),L (9),L (10),L (11),L (12),L (13)]

δW =

Minimum [L (1), L (2), L (3), L (4), L (5) ,L (6),L (7),L (8),L (9),L (10),L (11),L (12),L (13)]

6

2

7

3

8

9

11

1 0m m

D /4

4

1

12

D /4 D /4

D

H o rizo ntal L ine

5

D /4

10

13

10 m m

X

: T est P o in t

X = 1 to 1 3

Active Area

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8. Reliability Test Criteria

Test Item

High Temperature Storage Test

Low Temperature Storage Test

Test Condition

60ºC,240 hours

-20ºC, 240 hours

Thermal Shock Storage Test -20ºC, 0.5hour←→60 ºC, 0.5hour; 1hour/cycle,100cycles

High Temperature Operation Test 50ºC, 240 hours

Low Temperature Operation Test 0ºC, 240 hours

High Temperature & High Humidity

Operation Test

Shock (Non-Operating)

50ºC,80%RH, 240hours

40g, half sine, duration: 11ms,1times for ±X, ±Y, ±Z

Vibration (Non-Operating) f＝10～300Hz, 1.5G, 10min/cycles,3cycles each X, Y, Z,

Note

(1)(2)(4)

(3)(4)

(3)(4)

Note (1) There should be no condensation on the surface of panel during test.

Note (2) Temperature of panel display surface area should be 70 ºC Max.

Note (3) At testing Vibration and Shock, the fixture in holding the module has to be hard and rigid enough so that the module would not be twisted or bent by the fixture.

Note (4) In the standard conditions, there is no function failure issue occurred. All the cosmetic specification

is judged before reliability test.

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9. PACKAGING

9.1 PACKING SPECIFICATIONS

(1) 5 LCD modules / 1 Box

(2) Box dimensions: 713(L)x429(W)x453(H)mm

(3) Weight: approximately 21.1Kg (5 modules per box)

9.2 PACKING METHOD

Figure. 9-1 Packing method

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9.3 UN-PACKING METHOD

Figure. 9-2 Packing method

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10. DEFINITION OF LABELS

10.1 Innolux MODULE LABEL

The barcode nameplate is pasted on each module as illustration, and its definitions are as following explanation.

G260JJE -L07 Rev.XX

X X X X X X X Y M D L N N N N

(a) Model Name: G260JJE -L07

(b) Revision: Rev. XX, for example: A1, B1,C1, C2 …etc.

(c) Serial ID: X X X X X X X Y M D X N N N N

Serial No.

InnoLux Internal Use

Year, Month, Date


Revision


Serial ID includes the information as below:

(a) Manufactured Date: Year: 1~9, for 2011~2019

Month: 1~9, A~C, for Jan. ~ Dec.

Day: 1~9, A~Y, for 1 st

to 31 st

, exclude I , O and U

(b) Revision Code: cover all the change

(c) Serial No.: Manufacturing sequence of product

E207943

MADE IN TAIWAN

﹡﹡﹡﹡

RoHS

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11. PRECAUTIONS

11.1 ASSEMBLY AND HANDLING PRECAUTIONS

(1) Do not apply rough force such as bending or twisting to the module during assembly.

(2) To assemble or install module into user’s system can be only in clean working areas. The dust and oil may cause electrical short or worsen the polarizer.

(3) It’s not permitted to have pressure or impulse on the module because the LCD panel and Backlight will be damaged.

(4) Always follow the correct power sequence when LCD module is connecting and operating. This can prevent damage to the CMOS LSI chips during latch-up.

(5) Do not pull the I/F connector in or out while the module is operating.

(6) Do not disassemble the module.

(7) Use a soft dry cloth without chemicals for cleaning, because the surface of polarizer is very soft and easily scratched.

(8) It is dangerous that moisture come into or contacted the LCD module, because moisture may damage

LCD module when it is operating.

(9) High temperature or humidity may reduce the performance of module. Please store LCD module within the specified storage conditions.

(10) When ambient temperature is lower than 10ºC may reduce the display quality. For example, the response time will become slowly, and the starting voltage of backlight will be higher than room temperature.

(11) Do not keep same pattern in a long period of time. It may cause image sticking on LCD.

11.2 SAFETY PRECAUTIONS

(1) Do not disassemble the module or insert anything into the Backlight unit.

(2) If the liquid crystal material leaks from the panel, it should be kept away from the eyes or mouth. In case of contact with hands, skin or clothes, it has to be washed away thoroughly with soap.

(3) After the module’s end of life, it is not harmful in case of normal operation and storage.

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12. MECHANICAL CHARACTERISTICS


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