Plasma display: Difference between revisions

Plasma Display[edit]

A plasma display, also known as a plasma panel, is a type of flat-panel display technology that uses small cells containing electrically charged ionized gases to produce an image. It is commonly used in televisions, computer monitors, and other electronic devices.

History[edit]

The concept of plasma display technology was first introduced in the late 1960s by Donald L. Bitzer and H. Gene Slottow at the University of Illinois. They developed the first plasma display panel (PDP) and demonstrated its capabilities. However, it wasn't until the 1990s that plasma displays became commercially available.

How it Works[edit]

A plasma display consists of millions of tiny cells, each containing a mixture of noble gases such as neon and xenon. These gases are electrically charged to create plasma, which emits ultraviolet (UV) light. The UV light then strikes phosphors, causing them to emit visible light and produce the desired image.

Each cell in a plasma display is made up of three sub-pixels: red, green, and blue. By varying the intensity of each sub-pixel, a wide range of colors can be displayed. The cells are arranged in a grid pattern, with each cell acting as a pixel.

Advantages[edit]

Plasma displays offer several advantages over other display technologies:

1. **Wide Viewing Angle**: Plasma displays have a wide viewing angle, meaning the image remains clear and vibrant even when viewed from different angles.

2. **High Contrast Ratio**: Plasma displays have a high contrast ratio, resulting in deep blacks and vibrant colors.

3. **Fast Response Time**: Plasma displays have a fast response time, making them suitable for displaying fast-moving images without motion blur.

4. **Uniform Brightness**: Plasma displays provide uniform brightness across the entire screen, ensuring consistent image quality.

Disadvantages[edit]

Despite their advantages, plasma displays also have some drawbacks:

1. **Limited Lifespan**: Plasma displays have a limited lifespan compared to other display technologies. Over time, the phosphors used in the display can degrade, resulting in a decrease in image quality.

2. **Power Consumption**: Plasma displays consume more power than LCD or LED displays, making them less energy-efficient.

3. **Screen Burn-in**: Plasma displays are susceptible to screen burn-in, where static images displayed for extended periods can leave a permanent ghost image on the screen.

Future Developments[edit]

With the rise of LCD and LED display technologies, plasma displays have become less popular in recent years. However, there are ongoing efforts to improve plasma display technology. Researchers are exploring ways to increase the lifespan of plasma displays, reduce power consumption, and minimize the risk of screen burn-in.

Conclusion[edit]

Plasma displays have played a significant role in the evolution of flat-panel display technology. While they may not be as prevalent as they once were, they still offer unique advantages in terms of viewing angle, contrast ratio, and response time. As technology continues to advance, it will be interesting to see how plasma display technology evolves and adapts to meet the changing demands of the market.

See Also[edit]

• Liquid Crystal Display
• Light-Emitting Diode Display

References[edit]

<references />

• 
  Panasonic TX-P55ST60E late era plasma TV
• 
  Plasma display technology in 1981
• 
  Close-up of Toshiba T3100 screen
• 
  Evolution of 21st century plasma displays
• 
  Plasma lamp
• 
  Plasma display composition
• Spectrum of Plasma Display (Hitachi 42PMA500)
  Spectrum of Plasma Display (Hitachi 42PMA500)
• 
  Plasma burn-in at DFW airport