Super-twisted nematic display

Pioneering passive-matrix STN LCD, Brown Boveri, Switzerland, 1984

A super-twisted nematic display (STN) is a type of monochrome passive-matrix liquid crystal display (LCD).[1] This type of LCD was invented at the Brown Boveri Research Center, Baden, Switzerland, in 1983.[2] For years a better scheme for multiplexing was sought. Standard twisted nematic (TN) LCDs with a 90 degrees twisted structure of the molecules have a contrast vs. voltage characteristic unsuitable for passive-matrix addressing as there is no distinct threshold voltage. STN displays, with the molecules twisted from 180 to 270 degrees, have superior characteristics.[3] The main advantage of STN LCDs is their more pronounced electro-optical threshold allowing for passive-matrix addressing with many more lines and columns. For the first time, a prototype STN matrix display with 540x270 pixels was made by Brown Boveri (today ABB) in 1984, which was considered a breakthrough for the industry.

STN LCDs require less power and are less expensive to manufacture than TFT LCDs, another popular type of LCD that has largely superseded STN for mainstream laptops. STN displays typically suffer from lower image quality and slower response time than TFT displays. However, STN LCDs can be made purely reflective for viewing under direct sunlight. STN displays are used in some inexpensive mobile phones and informational screens of some digital products. In early 1990s, they had been used in some portable computers such as Amstrad's PPC512 and PPC640.

A 12 bit CSTN in a Nokia 3510i phone

CSTN stands for color super-twist nematic, a color form of passive matrix LCD (Liquid Crystal Display) for electronic display screens originally developed by Sharp Electronics. The CSTN uses red, green and blue filters to display color. The original CSTN displays developed in the early 1990s suffered from slow response times and ghosting (where text or graphic changes are blurred because the pixels cannot turn off and on fast enough). Recent advances in the technology, however, have made CSTN a viable alternative to active matrix displays. New CSTN displays offer 100ms response times (for comparison TFT displays offer 8ms or less), a 140 degree viewing angle and high-quality color rivaling TFT displays – all at about half the cost. A newer passive-matrix technology called High-Performance Addressing (HPA) offers even better response times and contrast than CSTN.

Other STN displays

References

  1. Kelly, Stephen M. (2000). Flat Panel Displays: Advanced Organic Materials. Royal Society of Chemistry. pp. 115–117. ISBN 0-85404-567-8.
  2. European Patent No. EP 0131216: Amstutz H., Heimgartner D., Kaufmann M.,Scheffer T.J., "Flüssigkristallanzeige," October 28, 1987.
  3. T.J. Scheffer and J. Nehring,"A new highly multiplexable LCD," Appl. Phys. Lett., vol. 45, no. 10, pp. 1021–1023, November 1984.
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