History of display technology
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Electrically operated display devices have developed from electromechanical systems for display of text, up to all-electronic devices capable of full-motion 3D color graphic displays. Electromagnetic devices, using a solenoid coil to control a visible flag or flap, were the earliest type, and were used for text displays such as stock market prices and arrival/departure display times. The cathode ray tube was the workhorse of text and video display technology for several decades until being displaced by plasma, liquid crystal (LCD), and solid-state devices such as thin-film transistors (TFTs), LEDs and OLEDs. With the advent of metal–oxide–semiconductor field-effect transistors (MOSFETs), integrated circuit (IC) chips, microprocessors, and microelectronic devices, many more individual picture elements ("pixels") could be incorporated into one display device, allowing graphic displays and video.
Cathode ray tube
{{main|Cathode-ray tube}}
One of the earliest electronic displays is the cathode-ray tube (CRT), which was first demonstrated in 1897 and made commercial in 1922.{{Cite web |title=Computer History - 1922 |url=https://www.computerhope.com/history/1922.htm |access-date=2023-11-26 |website=www.computerhope.com |language=en}} The CRT consists of an electron gun that forms images by firing electrons onto a phosphor-coated screen. The earliest CRTs were monochrome and were used primarily in oscilloscopes and black and white televisions. The first commercial colour CRT was produced in 1954. CRTs were the single most popular display technology used in television sets and computer monitors for over half a century; it was not until the 2000s that LCDs began to gradually replace them.
A derivative of CRTs were storage tubes, which had the ability to retain information displayed on them, unlike standard CRTs which need to be refreshed periodically. In 1968, Tektronix introduced the Direct-view bistable storage tube, which went on to be widely used in oscilloscopes and computer terminals.[http://www.medical-answers.org/hd/index.php?t=Tektronix+4014 medical-answers.org – Tektronix 4014] {{webarchive|url=https://web.archive.org/web/20120322134634/http://www.medical-answers.org/hd/index.php?t=Tektronix+4014 |date=2012-03-22 }}
= Monochrome CRT =
= Color CRT =
1954 Color cathode ray tube for the display of color television:{{Cite web |url=http://www.earlytelevision.org/15GP22.html |title=– earlytelevision.org – Picture Tubes, 15GP22 Color CRT |access-date=2011-04-25 |archive-url=https://web.archive.org/web/20170101195201/http://earlytelevision.org/15GP22.html |archive-date=2017-01-01 |url-status=dead }}
= Direct-View Bistable Storage Tube =
1968 The Direct-View Bistable Storage Tube CRT retains static information displayed upon it, written using a steerable electron beam that can be turned off. The DVBST was used in vector displays of early computers and in oscilloscopes.
Nixie tube display
1955 Nixie tube:
Flip-flap or disc display
Stroboscopic display
1960s Stroboscopic display:[https://www.youtube.com/watch?v=iCiJS3BU0i4 Stroboscopic display on the Soviet calculator "RASA" (video)][http://www.leningrad.su/museum/show_calc.php?n=201 Soviet made "RASA" electronic calculator with stroboscopic display] In the 1960s RASA Calculator (Russian), a small motor spins a cylinder that has a number of transparent numerals. To display a numeral, the calculator briefly flashes a thyratron light behind the required number when it spins into position.
Monochrome plasma display
LED display
Eggcrate display
1968 Eggcrate display{{Clear}}
Vacuum fluorescent display
1967 Vacuum fluorescent display as used in consumer electronics.
Twisted nematic field effect LCD
1971 Twisted nematic field effect LCD
{{cite journal | last1=Schadt | first1=M. | last2=Helfrich | first2=W. | title=Voltage-Dependent Optical Activity of a Twisted Nematic Liquid Crystal | journal=Applied Physics Letters | publisher=AIP Publishing | volume=18 | issue=4 | date=1971-02-15 | issn=0003-6951 | doi=10.1063/1.1653593 | pages=127–128| bibcode=1971ApPhL..18..127S }}{{cite journal | last1=Helfrich | first1=W. | last2=Schadt | first2=M. | title=Birefringence of Nematogenic Liquids Caused by Electrical Conduction | journal=Physical Review Letters | publisher=American Physical Society (APS) | volume=27 | issue=9 | date=1971-08-30 | issn=0031-9007 | doi=10.1103/physrevlett.27.561 | pages=561–564| bibcode=1971PhRvL..27..561H }}
Electroluminescent display
Super-twisted nematic LCD
1984 Super-twisted nematic display (STN LCD) to improve passive-matrix LCDs, allowing for the first time higher resolution panels with 540x270 pixels.
Pin screen
1969 Braille display:{{US patent|3594787}};{{Clear}}
Thin film transistor LCD
Digital Light Processing
1987 optical micro-electro-mechanical technology that uses a digital micromirror device. While the Digital Light Processing (DLP) imaging device was invented by Texas Instruments, the first DLP-based projector was introduced by Digital Projection Ltd in 1997.
Full-color plasma display
Organic light-emitting diode
Electronic paper
2004 Electronic paper:[http://www.hitech-projects.com/euprojects/diginews/publications/Adapting%20production%20workflow%20processes%20for%20digital%20newsprint.pdf hitech-projects.com – E-paper production flow – Adapting production workflow processes for digital newsprint] {{webarchive|url=https://web.archive.org/web/20110516084307/http://www.hitech-projects.com/euprojects/diginews/publications/Adapting%20production%20workflow%20processes%20for%20digital%20newsprint.pdf |date=2011-05-16 }}
Image:Lange Nacht der Entdeckungen 09.jpeg E-book reader equipped with e-paper display]]
Image:Bouquin électronique iLiad en plein soleil.jpg in sunlight]]
