NHD-1.69-160128UGC3 Datasheet by Newhaven Display Intl

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.— .u-r~6.vyt*9.ysn RI???“ Newhaven Display Internationall Inc. www.newhavendisglay.com nhtech@newhavendisplayxom nhsales@newhavendisplayxom
NHD-1.69-160128UGC3
Graphic Color OLED Display Module
NHD- Newhaven Display
1.69- 1.69Diagonal Size
160128- 160 x 128 Pixels
UG- Model
C- Full Color
3- +3V Power Supply
Newhaven Display International, Inc.
2661 Galvin Ct.
Elgin IL, 60124
Ph: 847-844-8795 Fax: 847-844-8796
www.newhavendisplay.com
nhtech@newhavendisplay.com nhsales@newhavendisplay.com
Document Revision History Revision Date Description Changed by 0 3/23/2014 Initial Release AK 1 5/1/2015 Interface Description Updated PB 2 10/20/15 Mechanical Drawing Updated SB 3 2/22/17 Thru-Hole Diameter Increased, Temperature Updated SB
[2]
Document Revision History
Revision
Date
Description
Changed by
0
3/23/2014
Initial Release
AK
1
5/1/2015
Interface Description Updated
PB
2
10/20/15
Mechanical Drawing Updated
SB
3
2/22/17
Thru-Hole Diameter Increased, Temperature Updated
SB
Functions and Features
160 x 128 pixel resolution
Built-in SEPS525 controller
Parallel or Serial MPU interface
Single, low voltage power supply
RoHS compliant
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1 2 3 4 5 6
A
B
C
D
B
C
D
1 2 3 4 5 6
Mechanical Drawing
A
[3]
The information contained herein is the exclusive property of Newhaven Display International, Inc. and shall not be copied, reproduced, and/or disclosed in any format without permission.
NHD-1.69-160128UGC3
02/07/17
Date
Unit
Part Number:
mm
Gen. Tol.
±0.3
Rev Description Date
Newhaven Di spl ay
NHD- 1. 69- 160128UGC3
W
W YY
RevB
PROPRIETARY
Notes:
1. Display Type: 1.69” Color OLED
2. Driver IC: SEPS525
3. Interface: 8-Bit 68XX/80XX Parallel, 3/4-Wire SPI
4. Operating Temp: -40°C - +70°C
5. Storage Temp: -40°C - +85°C
Parallel Interface: PM No. Symbnl External Connectlon Functlon Descrlptlon 1 GNU Power Supply Ground 2 vm, Power Supply Supply Voltage for OLED and logic. 3 NC - N0 Connect 4 U/c MPU Register select signal. D/C:O: Command, D/C:1: Data 5 R/W or /WR MPU 6800-interface: Read/Write sele Rosa-interface: Active LOW Write signal. 6 E or /R0 MPU 6800-interface: Operation enabl Rosa-interface: Active LOW Read signal. 7-14 DE10 , 0317 MPU 8-bit Bi-directional data bus lines. 15 GNU Power Supply Ground 16 /RES MPU Active LOW Reset signal. 17 /CS MPU Active LOW Chip Select signal. 18 GNU Power Supply Ground 19 PS MPU Parallel/Serial select. HIGH: Parallel. LOW: Serial 20 CPU MPU Interface select. HIGH: 6800 interface. LOW: 8080 interface Serial Interface: PM No. Symbnl External Connectlon Functlon Descrlptlon 1 GNU Power Supply Ground 2 vm, Power Supply Supply Voltage for OLED and logic. 3 NC - N0 Connect 4 U/c MPU Register select signal. D/C:O: Command, D/C:1: Data 5-5 VSS Power Supply Ground 7-12 GNU Power Supply Ground 13 SDI MPU Serial Data Input signal. 14 SCL MPU Serial Clock signal. 15 GNU Power Supply Ground 16 /RES MPU Active LOW Reset signal. 17 /CS MPU Active LOW Chip Select signal. 18 GNU Power Supply Ground 19 PS MPU Parallel/Serial select. HIGH: Parallel. LOW: Serial 20 CPU MPU Interface select. HIGH: 6800 interface. LOW: 8080 interface MPU Interface Pin Assignment Summary Bus Data/Command Interface Control Slgnals Interface D17 I U16 I D15 I U14 I D13 I U12 I D11 I D10 E R/W /cs D/C IRES 8-bit 5300 D[17:10] E R/W /cs D/c /RES 8-bit 8080 D[17:10] /RD /WR /cs D/c /RES 4-wireSPl SCL I SDI I TieLOW /cs D/c /RES
[4]
Interface Description
Parallel Interface:
Pin No.
External Connection
Function Description
1
Power Supply
Ground
2
Power Supply
Supply Voltage for OLED and logic.
3
-
No Connect
4
MPU
Register select signal. D/C=0: Command, D/C=1: Data
5
MPU
6800-interface:
Read/Write select signal, R/W=1: Read R/W: =0: Write
8080-interface:
Active LOW Write signal.
6
MPU
6800-interface:
Operation enable signal. Falling edge triggered.
8080-interface:
Active LOW Read signal.
7-14
MPU
8-bit Bi-directional data bus lines.
15
Power Supply
Ground
16
MPU
Active LOW Reset signal.
17
MPU
Active LOW Chip Select signal.
18
Power Supply
Ground
19
MPU
Parallel/Serial select. HIGH: Parallel. LOW: Serial
20
MPU
Interface select. HIGH: 6800 interface. LOW: 8080 interface
Serial Interface:
Pin No.
External Connection
Function Description
1
Power Supply
Ground
2
Power Supply
Supply Voltage for OLED and logic.
3
-
No Connect
4
MPU
Register select signal. D/C=0: Command, D/C=1: Data
5-6
Power Supply
Ground
7-12
Power Supply
Ground
13
MPU
Serial Data Input signal.
14
MPU
Serial Clock signal.
15
Power Supply
Ground
16
MPU
Active LOW Reset signal.
17
MPU
Active LOW Chip Select signal.
18
Power Supply
Ground
19
MPU
Parallel/Serial select. HIGH: Parallel. LOW: Serial
20
MPU
Interface select. HIGH: 6800 interface. LOW: 8080 interface
MPU Interface Pin Assignment Summary
Bus
Interface
Data/Command Interface
Control Signals
D17
D16
D15
D14
D13
D12
D11
D10
E
R/W
/CS
D/C
/RES
8-bit 6800
D[17:10]
E
R/W
/CS
D/C
/RES
8-bit 8080
D[17:10]
/RD
/WR
/CS
D/C
/RES
4-wire SPI
SCL
SDI
Tie LOW
/CS
D/C
/RES
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[5]
Wiring Diagrams
Electrical Characteristics Item Symbol Cnndltlnn Mln. Typ. Max. Unlt Operating Temperature Range Tap Absolute Max -40 - +70 “0 Storage Temperature Range 15, Absolute Max -40 - +85 “0 Supply Voltage vDD - 2.5 2.8 3.3 v Supply Current llogio) lDD - 5 12 mA Supply Current ldlsplayl lCC - 180 330 mA Sleep Mode Current IDDHK my - 2 10 mA “H“ Level input v.H 0.3 *vDD - vm, v “L“ Level input v.L GND - 0.4 v “H“ Level output vuH vDD -o.4 - vm, v “L“ Level output v0L GND - 0.4 v Optical Characteristics Item Symbol Cnndltlnn Mln. Typ. Max. Unlt Top wV+ 30 - - ° Bottom (pV- 30 - - ° Left 8X- 80 - - 9 Right ex+ 30 - - ° Contrast Ratio CR - - 2000:1 - - Rise TW - 1o - us Fall TF - 1o - us Brightness LV 50% Checkerboard 70 90 - cd/m Lifetime - 90 WW rTop :25“Cr 10,000 - - Hrs. 50% Checkerboard www ewhavendis Ia om a notes SEPSSZS df
[6]
Electrical Characteristics
Item
Symbol
Condition
Min.
Typ.
Max.
Unit
Operating Temperature Range
TOP
Absolute Max
-40
-
+70
C
Storage Temperature Range
TST
Absolute Max
-40
-
+85
C
Supply Voltage
VDD
-
2.6
2.8
3.3
V
Supply Current (logic)
IDD
VDD=2.8V
TOP = 25°C
-
6
12
mA
Supply Current (display)
ICC
-
180
330
mA
Sleep Mode Current
IDD+ICC_SLEEP
-
2
10
mA
H Level input
VIH
0.8 * VDD
-
VDD
V
L Level input
VIL
GND
-
0.4
V
H” Level output
VOH
VDD - 0.4
-
VDD
V
L Level output
VOL
GND
-
0.4
V
Optical Characteristics
Item
Symbol
Condition
Min.
Typ.
Max.
Unit
Optimal
Viewing
Angles
Top
ϕY+
-
80
-
-
Bottom
ϕY-
80
-
-
Left
θX-
80
-
-
Right
θX+
80
-
-
Contrast Ratio
CR
-
-
2000:1
-
-
Response Time
Rise
TR
TOP = 25°C
-
10
-
µs
Fall
TF
-
10
-
µs
Brightness
LV
50% Checkerboard
70
90
-
cd/m2
Lifetime
-
90 cd/m², T
OP
=25°C,
50% Checkerboard
10,000
-
-
Hrs.
Note: Lifetime at typical temperature is based on accelerated high-temperature operation. Lifetime is tested at
average 50% pixels on and is rated as Hours until Half-Brightness. The Display OFF command can be used to
extend the lifetime of the display.
Luminance of active pixels will degrade faster than inactive pixels. Residual (burn-in) images may occur. To avoid
this, every pixel should be illuminated uniformly.
Controller information
Built-in SEPS525 Controller.
Please download specification at www.newhavendisplay.com/app_notes/SEPS525.pdf
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[7]
Table of Commands
T 680015eries MCU Parallel Interfage: (Wllle Tvmmmg) us- um csB RS R‘NB lWREl "may DE[I?0] lsxwt lost (m lcvcl ITEM SYMBOL CONDITION MIN MAX UNIT PORT Address hold timing Lu I4. 5 ns CSB Address setup timing Lw. - 5 - n5 RS System cycle liming tcu’n 100 115 Write “L" pulse width tn m. - 45 - n5 E Write ”H” pulse width mum 45 115 Data setup timing haw. 40 ns 7 7 DB[17:()] Data hold liming [um 10 ns
[8]
Timing Characteristics
6800-Series MCU Parallel Interface:
(Read Timming) 1m (:53 Ms RS RWB (WEB) (RDB) , r mus km E mm n B [1 7 -o] i Innn‘ (CV05 ITEM SYMBOL CONDITION MIN MAX UNIT PORT Address hold timing lAHfi 10 ns CSB Address setup timing tag. 10 ns RS System cycle timing tun. 200 us Read ”L" pulse width trm - 90 - ns E Read “H" pulse width [mm 90 ns Read data output delay time (Rum ns CL = 15 PF 0 70 DB[17:0] Data hold timing ham-1e. n5
[9]
8080-Series MCU Parallel Interface: ( Wnle Tlmmmg ) lass Inn 038 RS WRB / MW IWRLWB F L I last 0m ‘ DB“? 0] lam ITEM SYMBOL CONDITION MIN MAX UNIT PORT Address hold timing Mm 5 ns CSB Address setup timing tASU 5 ns RS System cycle liming 1cm 100 ns Write "L" pulse Width [\‘VKLWh - 45 - ns WRB Write "H" pulse width lwmnvs 45 ns Data setup timing tnsw 30 ns _ — DB[17:0] Data hold timing tnux 10 ns
[10]
8080-Series MCU Parallel Interface:
(Read Timmlng) w [AM CSB R8 RDB % : \ mm — Imam: L hm: DE[17 0] — i Inoosa lcvcs ITEM SYMBOL CONDITION MIN MAX UNIT PORT Address hold timing tAHs 5 ns CSB Address setup timing (mm 5 ns RS System cycle timing tum 200 ns Read "L” pulse width tknuzx - 90 - ns RDB Read "H" pulse width txnnxs 90 ns Read data output delay time [wax - ns CL =15 FF 60 DB[17:0] Data hold timing [mm 0 ns
[11]
4-wire SPI: IN .... v; M SD‘ I I I l ITEM SYMBOL CONDITION MIN MAX UNIT PORT Serial clock cycle tare 100 ns SCL "H" pulse width tus - 45 - ns SCL SCL ”L" pulse width is! w 45 ns D l t f ‘ l . I 5 a a se up lmlng ms _ _ ns SDI Data hold liming [DI IS 5 n9 CSB-SCL timing tcs< 5="" ns="" -="" -="" csb="" csb-hold="" liming="" ((511="" 5="" n5="" rsscl="" timing="" tkss="" 5="" ns="" rs="" rs-hold="" liming="" trsh="" 5="" ns="">
[12]
4-wire SPI:
[13]
Example Initialization Sequence:
void oled_Data_160128RGB(unsigned char Data)
{
GPIO_ResetBits(GPIOC, CS1);
GPIO_SetBits(GPIOC, RS);
GPIO_Write(GPIOB, Data);
GPIO_ResetBits(GPIOC, RW);
GPIO_SetBits(GPIOC, E1);
GPIO_ResetBits(GPIOC, E1);
}
void oled_Command_160128RGB(unsigned char Data)
{
GPIO_ResetBits(GPIOC, CS1);
GPIO_ResetBits(GPIOC, RS);
GPIO_Write(GPIOB, Data);
GPIO_ResetBits(GPIOC, RW);
GPIO_SetBits(GPIOC, E1);
GPIO_ResetBits(GPIOC, E1);
}
void OLED_Init_160128RGB(void)
{
int i,j;
GPIO_ResetBits(GPIOC, RES);
graphic_delay(500000);
GPIO_SetBits(GPIOC, RES);
graphic_delay(500000);
oled_Command_160128RGB(0x04);// Set Normal Driving Current
oled_Data_160128RGB(0x03);// Disable Oscillator Power Down
graphic_delay(2000);
oled_Command_160128RGB(0x04); // Enable Power Save Mode
oled_Data_160128RGB(0x00); // Set Normal Driving Current
graphic_delay(2000); // Disable Oscillator Power Down
oled_Command_160128RGB(0x3B);
oled_Data_160128RGB(0x00);
oled_Command_160128RGB(0x02);
oled_Data_160128RGB(0x01); // Set EXPORT1 Pin at Internal Clock
// Oscillator operates with external resister.
// Internal Oscillator On
oled_Command_160128RGB(0x03);
oled_Data_160128RGB(0x90); // Set Frame Rate as 120Hz
[14]
oled_Command_160128RGB(0x80);
oled_Data_160128RGB(0x01); // Set Reference Voltage Controlled by External Resister
oled_Command_160128RGB(0x08);// Set Pre-Charge Time of Red
oled_Data_160128RGB(0x04);
oled_Command_160128RGB(0x09);// Set Pre-Charge Time of Green
oled_Data_160128RGB(0x05);
oled_Command_160128RGB(0x0A);// Set Pre-Charge Time of Blue
oled_Data_160128RGB(0x05);
oled_Command_160128RGB(0x0B);// Set Pre-Charge Current of Red
oled_Data_160128RGB(0x9D);
oled_Command_160128RGB(0x0C);// Set Pre-Charge Current of Green
oled_Data_160128RGB(0x8C);
oled_Command_160128RGB(0x0D);// Set Pre-Charge Current of Blue
oled_Data_160128RGB(0x57);
oled_Command_160128RGB(0x10);// Set Driving Current of Red
oled_Data_160128RGB(0x56);
oled_Command_160128RGB(0x11);// Set Driving Current of Green
oled_Data_160128RGB(0x4D);
oled_Command_160128RGB(0x12);// Set Driving Current of Blue
oled_Data_160128RGB(0x46);
oled_Command_160128RGB(0x13);
oled_Data_160128RGB(0xa0); // Set Color Sequence
oled_Command_160128RGB(0x14);
oled_Data_160128RGB(0x01); // Set MCU Interface Mode
oled_Command_160128RGB(0x16);
oled_Data_160128RGB(0x76);
oled_Command_160128RGB(0x20);
oled_Data_160128RGB(0x00); // Shift Mapping RAM Counter
oled_Command_160128RGB(0x21);
oled_Data_160128RGB(0x00); // Shift Mapping RAM Counter
oled_Command_160128RGB(0x28);
oled_Data_160128RGB(0x7F); // 1/128 Duty (0x0F~0x7F)
oled_Command_160128RGB(0x29);
oled_Data_160128RGB(0x00); // Set Mapping RAM Display Start Line (0x00~0x7F)
oled_Command_160128RGB(0x06);
oled_Data_160128RGB(0x01); // Display On (0x00/0x01)
oled_Command_160128RGB(0x05); // Disable Power Save Mode
oled_Data_160128RGB(0x00); // Set All Internal Register Value as Normal Mode
[15]
oled_Command_160128RGB(0x15);
oled_Data_160128RGB(0x00); // Set RGB Interface Polarity as Active Low
}
int oled_160128RGB(void)
{
oled_Command_160128RGB(0x17); //set column start address
oled_Data_160128RGB(0x00); //
oled_Command_160128RGB(0x18); //set column end address
oled_Data_160128RGB(0x9F); //
oled_Command_160128RGB(0x19); //set row start address
oled_Data_160128RGB(0x00); //
oled_Command_160128RGB(0x1A); //set row end address
oled_Data_160128RGB(0x7F); //
oled_Command_160128RGB(0x22); //write to RAM command
for (i=0;i<20480;i++) //for each 24-bit pixel...160*128=20480
{
oled_Data_160128RGB(red);
oled_Data_160128RGB(green);
oled_Data_160128RGB(blue);
}
/*if(image==screenSaverRequired){ //screen saver example--!
//First Screen
oled_Command_160128RGB(0x2E); //first screen horizontal address
oled_Data_160128RGB(0x00); //
oled_Command_160128RGB(0x2F); //first screen vertical address
oled_Data_160128RGB(0x00); //
oled_Command_160128RGB(0x33); //first screen start column
oled_Data_160128RGB(0x00); //
oled_Command_160128RGB(0x34); //first screen end column
oled_Data_160128RGB(0x9F); //
oled_Command_160128RGB(0x35); //first screen start row
oled_Data_160128RGB(0x00); //
oled_Command_160128RGB(0x36); //first screen end row
oled_Data_160128RGB(0x36); //
//Second_Screen(0x00,0x9F,0x3C,0x7F,0x20,0x7F,0x3C,0x5F);
oled_Command_160128RGB(0x31); //second screen horizontal address
oled_Data_160128RGB(0x00); //
oled_Command_160128RGB(0x32); //second screen vertical address
oled_Data_160128RGB(0x37); //
[16]
oled_Command_160128RGB(0x37); //second screen start column
oled_Data_160128RGB(0x00); //
oled_Command_160128RGB(0x38); //second screen end column
oled_Data_160128RGB(0x9F); //
oled_Command_160128RGB(0x39); //second screen start row
oled_Data_160128RGB(0x37); //
oled_Command_160128RGB(0x3A); //second screen end row
oled_Data_160128RGB(0x7F); //
oled_Command_160128RGB(0x47); //second screen box start column
oled_Data_160128RGB(0x60); //
oled_Command_160128RGB(0x48); //second screen box end column
oled_Data_160128RGB(0x7F); //
oled_Command_160128RGB(0x49); //second screen box start row
oled_Data_160128RGB(0x37); //
oled_Command_160128RGB(0x4A); //second screen box end row
oled_Data_160128RGB(0x37); //
oled_Command_160128RGB(0x3E);//first screen update timer
oled_Data_160128RGB(0x04);
oled_Command_160128RGB(0x3F);//horizontal step
oled_Data_160128RGB(0x01);
oled_Command_160128RGB(0x40);//second screen update timer
oled_Data_160128RGB(0x01);
oled_Command_160128RGB(0x41);//second screen vertical and horizontal step
oled_Data_160128RGB(0x11);
oled_Command_160128RGB(0x42);//moving direction
oled_Data_160128RGB(0x00);
oled_Command_160128RGB(0x3C);//sleep timer
oled_Data_160128RGB(0xF0);
oled_Command_160128RGB(0x3D);//Screen saver mode
oled_Data_160128RGB(0x01);
oled_Command_160128RGB(0x13);
oled_Data_160128RGB(0xa4);
oled_Command_160128RGB(0x3B);//Screen saver control
oled_Data_160128RGB(0x0D);
} */
/*else { //Screen Saver example #2--!
oled_Command_160128RGB(0x2E); //First Screen First_Screen(0x00,0x9F,0x00,0x7F);
oled_Data_160128RGB(0x00); //
oled_Command_160128RGB(0x2F); //
oled_Data_160128RGB(0x00); //
oled_Command_160128RGB(0x33); //
oled_Data_160128RGB(0x00); //
oled_Command_160128RGB(0x34); //
oled_Data_160128RGB(0x9F); //
oled_Command_160128RGB(0x35); //
oled_Data_160128RGB(0x00); //
oled_Command_160128RGB(0x36); //
oled_Data_160128RGB(0x7F); //
oled_Command_160128RGB(0x13);
[17]
oled_Data_160128RGB(0xa0);
//Screen_Saver_(full screen to the right)
oled_Command_160128RGB(0x3E);//Screen saver
oled_Data_160128RGB(0x01);
oled_Command_160128RGB(0x3F);//Screen saver
oled_Data_160128RGB(0x01);
oled_Command_160128RGB(0x40);//Screen saver
oled_Data_160128RGB(0x01);
oled_Command_160128RGB(0x41);//Screen saver
oled_Data_160128RGB(0x01);
oled_Command_160128RGB(0x42);//Screen saver
oled_Data_160128RGB(0x10);
oled_Command_160128RGB(0x3C);//Screen saver timer
oled_Data_160128RGB(0x80);
oled_Command_160128RGB(0x3D);//Screen saver timer
oled_Data_160128RGB(0x32);
oled_Command_160128RGB(0x3B);//Screen saver
oled_Data_160128RGB(0x05);
}*/
/* //turn off screen saver example --!
oled_Command_160128RGB(0x3D);//Screen saver timer
oled_Data_160128RGB(0x00);
oled_Command_160128RGB(0x3C);//Screen saver timer
oled_Data_160128RGB(0x00);
oled_Command_160128RGB(0x3B);//Screen saver
oled_Data_160128RGB(0x00);
oled_Command_160128RGB(0x42);//Screen saver
oled_Data_160128RGB(0x00);
*/
}return 1;}
///////////////////////////////////////////////////////
Quality Information Test Item Content of Test Test Condition Note High Temperature storage Test the endurance ofthe display at high +80%, 96nrs 2 storage temperature Low Temperature storage Test the endurance ofthe display at low -40%, 96hrs 1,2 storage temperature, High Temperature Test the endurance ofthe display by +70%, 96nrs 2 applying electric stres at high temperature, Low Temperature Test the endurance ofthe display by -30%, 96hrs 1,2 applying electric stre at low temperature. High Temperature/ Test the endurance ofthe display by +50%, 90% RH, 96hrs 1,2 applying electric stress (voltage a; curren at high temperature with high humidity. Thermal Shock resistance Test the endurance of the dlspiay by 60°C, 30min -> 25°C, 5min -> applying electric durlng a cycle o temperatures. vibration test Test the endurance ofthe display by 10-22Hz,1.5mm amplitude. 3 22-500 30min x,v,2 Atmospheric Pressure test Test the endurance ofthe display by 115mbar, 40hrs 3 applying atmospheric transportation by air. Static electricity test Test the endurance ofthe display by applying electric static discharge. V5:800V, RS:1.5kfl, CS:100pF One time Not P for using OLEDs/LCDs/LCMs S www.newhavendisglay.com[sgecs[grecautionsgdf Warranty Information and Terms & Conditio http: /www.newhavendispiav.c0m index.php?main page=terms
[18]
Quality Information
Test Item
Content of Test
Test Condition
Note
High Temperature storage
Test the endurance of the display at high
storage temperature.
+80C , 96hrs
2
Low Temperature storage
Test the endurance of the display at low
storage temperature.
-40C , 96hrs
1,2
High Temperature
Operation
Test the endurance of the display by
applying electric stress (voltage & current)
at high temperature.
+70C , 96hrs
2
Low Temperature
Operation
Test the endurance of the display by
applying electric stress (voltage & current)
at low temperature.
-30C , 96hrs
1,2
High Temperature /
Humidity Operation
Test the endurance of the display by
applying electric stress (voltage & current)
at high temperature with high humidity.
+60C , 90% RH , 96hrs
1,2
Thermal Shock resistance
Test the endurance of the display by
applying electric stress (voltage & current)
during a cycle of low and high
temperatures.
-30C, 30min -> 25⁰C, 5min ->
70C, 30min = 1 cycle
For 100 cycles
Vibration test
Test the endurance of the display by
applying vibration to simulate
transportation and use.
10-22Hz, 1.5mm amplitude.
22-500Hz, 1.5G
30min in each of 3 directions
X,Y,Z
3
Atmospheric Pressure test
Test the endurance of the display by
applying atmospheric pressure to simulate
transportation by air.
115mbar, 40hrs
3
Static electricity test
Test the endurance of the display by
applying electric static discharge.
VS=800V, RS=1.5kΩ, CS=100pF
One time
Note 1: No condensation to be observed.
Note 2: Conducted after 2 hours of storage at 25C, 0%RH.
Note 3: Test performed on product itself, not inside a container.
Evaluation Criteria:
1: Display is fully functional during operational tests and after all tests, at room temperature.
2: No observable defects.
3: Luminance >50% of initial value.
4: Current consumption within 50% of initial value
Precautions for using OLEDs/LCDs/LCMs
See Precautions at www.newhavendisplay.com/specs/precautions.pdf
Warranty Information and Terms & Conditions
http://www.newhavendisplay.com/index.php?main_page=terms

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