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General Information Items | Specification | Unit | Note |
Main Panel | |||
Display area(AA) | 95.04(H) * 53.86(V) (4.3 inch ) | mm | - |
Driver element | a-Si TFT active matrix | - | - |
Display colors | 16.7M | colors | - |
Color Gamut | 50 | % | - |
Number of pixels | 480(RGB) *272 | dots | - |
Pixel arrangement | RGB vertical stripe | - | - |
Pixel pitch | 0.198(H) *0.198(V) | mm | - |
Viewing angle | 6:00 | o'clock | - |
Drive IC | ILI6480Q | - | - |
Display mode | Transmissive/ Normally White | - | - |
Operating temperature | -20~+70 | ℃ | - |
Storage temperature | -30~+80 | ℃ | - |
* Mechanical Information
Item | Min. | Typ. | Max. | Unit | Note | |
Module size | Horizontal(H) | - | 105.5 | - | mm | - |
Vertical(V) | - | 67.2 | - | mm | - | |
Depth(D) | 4.15 | mm | - | |||
Weight | - | TBD | - | g | - | |
1. Our standard TFT LCD Module size:
1.44'', 1.77", 2.0", 2.4", 2.8", 3.2", 3.5",
4"(3.97"), 4.3", 5", 7", 8", 9'', 10.1".
2. Developed 4.0''(3.97'') LCD module with IPS glass.
3. Developed 2.4'' to 7.0'' TFT LCD with ZIF FPC connection.
4. Standard CTP for 3.2'', 3.5'', 4.3", 5.0", 7'', 8'', 10.1''.
5. High transmittance RTP for 4.3" and 7".
6. Can make customized CTP.
4.3'' TFT LCD Display
TFT-lcd (Color thin Film Transistor liquid Crystal display) is mainly used in computer, video terminal, communication and instrument industry. Major applications include notebook computers, desktop computer monitors, workstations, industrial monitors, GPS (gps), personal data processing, game consoles, video phones, portable vcd,dvd and other portable devices.
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Knowledge point:
Furthermore, MicroLED screens have a longer lifespan compared to LCD screens, as they do not suffer from burn-in issues that can occur over time. This makes them suitable for applications where screens are constantly on, such as digital signage or smart home devices.
In addition to OLED and MicroLED technologies, there are ongoing research and development efforts exploring other potential alternatives to LCD screens. One such example is the use of Quantum Dot technology. Quantum Dots are tiny semiconductor particles that can emit light of different colors when stimulated by an external light source. This technology can enhance color accuracy and improve overall picture quality.
Moreover, researchers are also exploring the possibilities of holographic displays, which could potentially revolutionize the way we view and interact with screens. Holographic displays use light diffraction to create three-dimensional images that can be viewed from multiple angles without the need for special glasses.
OLED Screens in Healthcare and Medical Applications
OLED screens have found applications in the healthcare and medical industry as well. OLED displays are used in medical imaging devices such as X-ray machines and ultrasound systems, providing high-resolution images for accurate diagnosis. The high contrast ratio of OLED screens helps healthcare professionals identify subtle details and anomalies. Additionally, the flexibility of OLED technology allows for curved and conformable displays, enabling the creation of wearable medical devices and flexible medical monitors.
Subheading : Conclusion
The application range of OLED screens is vast and diverse, spanning across smartphones, televisions, automotive displays, wearables, virtual reality devices, and even healthcare applications. The exceptional image quality, vibrant colors, and energy efficiency of OLED technology have made it a preferred choice for manufacturers across various industries. As OLED technology continues to evolve, we can expect to see even more innovative applications and advancements in display technology.
In conclusion, the LCD screen, which has been a dominant technology for many years, may soon be replaced by more advanced and innovative alternatives. OLED, MicroLED, Quantum Dot, and holographic technologies are all potential contenders to revolutionize the way we view and interact with screens in the future.
With ongoing research and development, we can expect even more exciting advancements in display technology that will enhance our visual experiences and redefine the way we engage with digital content.
General Information Items | Specification | Unit | Note |
Main Panel | |||
Display area(AA) | 95.04(H) * 53.86(V) (4.3 inch ) | mm | - |
Driver element | a-Si TFT active matrix | - | - |
Display colors | 16.7M | colors | - |
Color Gamut | 50 | % | - |
Number of pixels | 480(RGB) *272 | dots | - |
Pixel arrangement | RGB vertical stripe | - | - |
Pixel pitch | 0.198(H) *0.198(V) | mm | - |
Viewing angle | 6:00 | o'clock | - |
Drive IC | ILI6480Q | - | - |
Display mode | Transmissive/ Normally White | - | - |
Operating temperature | -20~+70 | ℃ | - |
Storage temperature | -30~+80 | ℃ | - |
* Mechanical Information
Item | Min. | Typ. | Max. | Unit | Note | |
Module size | Horizontal(H) | - | 105.5 | - | mm | - |
Vertical(V) | - | 67.2 | - | mm | - | |
Depth(D) | 4.15 | mm | - | |||
Weight | - | TBD | - | g | - | |
1. Our standard TFT LCD Module size:
1.44'', 1.77", 2.0", 2.4", 2.8", 3.2", 3.5",
4"(3.97"), 4.3", 5", 7", 8", 9'', 10.1".
2. Developed 4.0''(3.97'') LCD module with IPS glass.
3. Developed 2.4'' to 7.0'' TFT LCD with ZIF FPC connection.
4. Standard CTP for 3.2'', 3.5'', 4.3", 5.0", 7'', 8'', 10.1''.
5. High transmittance RTP for 4.3" and 7".
6. Can make customized CTP.
4.3'' TFT LCD Display
TFT-lcd (Color thin Film Transistor liquid Crystal display) is mainly used in computer, video terminal, communication and instrument industry. Major applications include notebook computers, desktop computer monitors, workstations, industrial monitors, GPS (gps), personal data processing, game consoles, video phones, portable vcd,dvd and other portable devices.
******************************************************************************************************************
Knowledge point:
Furthermore, MicroLED screens have a longer lifespan compared to LCD screens, as they do not suffer from burn-in issues that can occur over time. This makes them suitable for applications where screens are constantly on, such as digital signage or smart home devices.
In addition to OLED and MicroLED technologies, there are ongoing research and development efforts exploring other potential alternatives to LCD screens. One such example is the use of Quantum Dot technology. Quantum Dots are tiny semiconductor particles that can emit light of different colors when stimulated by an external light source. This technology can enhance color accuracy and improve overall picture quality.
Moreover, researchers are also exploring the possibilities of holographic displays, which could potentially revolutionize the way we view and interact with screens. Holographic displays use light diffraction to create three-dimensional images that can be viewed from multiple angles without the need for special glasses.
OLED Screens in Healthcare and Medical Applications
OLED screens have found applications in the healthcare and medical industry as well. OLED displays are used in medical imaging devices such as X-ray machines and ultrasound systems, providing high-resolution images for accurate diagnosis. The high contrast ratio of OLED screens helps healthcare professionals identify subtle details and anomalies. Additionally, the flexibility of OLED technology allows for curved and conformable displays, enabling the creation of wearable medical devices and flexible medical monitors.
Subheading : Conclusion
The application range of OLED screens is vast and diverse, spanning across smartphones, televisions, automotive displays, wearables, virtual reality devices, and even healthcare applications. The exceptional image quality, vibrant colors, and energy efficiency of OLED technology have made it a preferred choice for manufacturers across various industries. As OLED technology continues to evolve, we can expect to see even more innovative applications and advancements in display technology.
In conclusion, the LCD screen, which has been a dominant technology for many years, may soon be replaced by more advanced and innovative alternatives. OLED, MicroLED, Quantum Dot, and holographic technologies are all potential contenders to revolutionize the way we view and interact with screens in the future.
With ongoing research and development, we can expect even more exciting advancements in display technology that will enhance our visual experiences and redefine the way we engage with digital content.
