This is a comparison of various properties of different display technologies.
General characteristics
Major technologies are CRT, LCD and its derivatives (Quantum dot display, LED backlit LCD, WLCD, OLCD), Plasma, and OLED and its derivatives (Transparent OLED, PMOLED, AMOLED). An emerging technology is Micro LED. Cancelled and now obsolete technologies are SED and FED.
Temporal characteristics
Different display technologies have vastly different temporal characteristics, leading to perceptual differences of motion, flicker, etc.
Sketch of some common display technologies' temporal behaviour
The figure shows a sketch of how different technologies present a single white/grey frame. Time and intensity is not to scale. Notice that some have a fixed intensity, while the illuminated period is variable. This is a kind of pulse-width modulation. Others can vary the actual intensity in response to the input signal.
Single-chip DLPs use a kind of "chromatic multiplexing" in which each color is presented serially. The intensity is varied by modulating the "on" time of each pixel within the time-span of one color. Multi-chip DLPs are not represented in this sketch, but would have a curve identical to the plasma display.
LCDs have a constant (backlit) image, where the intensity is varied by blocking the light shining through the panel.
CRTs use an electron beam, scanning the display, flashing a lit image. If interlacing is used, a single full-resolution image results in two "flashes". The physical properties of the phosphor are responsible for the rise and decay curves.
Plasma displays modulate the "on" time of each sub-pixel, similar to DLP.
Movie theaters use a mechanical shutter to illuminate the same frame 2 or 3 times, increasing the flicker frequency to make it less perceptible to the human eye.
Research
Researchers announced a display that uses silicon metasurface pixels that do not require polarized light and require half the energy. It employs a transparent conductive oxide as a heater that can quickly change the pixels. The pixels are 100 times thinner than liquid crystal. Response times are under 1 millisecond. They claim that the metasurface array could replace the liquid crystal layer in today's displays, eliminating the need for production technology.[25]
^"Aperture grille CRT" (PDF). Archived from the original (PDF) on 2011-07-16. Retrieved 2011-02-23.
^"Monochrome CRT". Archived from the original on 2009-10-09.
^"Self-contained Rear Projection CRT". Archived from the original on 2008-10-31. Retrieved 2007-11-04.
^"Panasonic Develops World's Largest 152-Inch Full HD 3D Plasma Display - Headquarters News - Panasonic Newsroom Global". Archived from the original on 2010-01-10. Retrieved 2010-01-08.
^"Gas Plasma Screen - Compaq Portable 386". December 19, 2018.
^"LCD Rear Projection". Archived from the original on 2012-07-17. Retrieved 2007-03-16.
^Casamassina, Matt (8 January 2007). "CES 2007: Optoma's $50k 120-inch Set".
^"JVC Develops 110-inch".
^"Mitsubishi Electric LaserVue® - Products". Archived from the original on 2009-08-25. Retrieved 2009-09-08.
^"Largest LED 3D TV".
^"55-inch SED HDTVs on the way in '08".
^LG Global (7 January 2015). "CES 2015 LG - Perfect Black, Perfect Color : Only in LG OLED TV". Archived from the original on 2015-01-08 – via YouTube.
^"LG SIGNATURE Z9 88 inch Class 8K Smart OLED TV w/AI ThinQ® (87.6 Diag) (OLED88Z9PUA)". LG USA.
^"Quantum Dots QDTV Displays from Nanoco Technologies". Archived from the original on 2009-07-14. Retrieved 2009-05-02.
^"Nevada Nanotechnology Center - Research".
^Gache, Gabriel (10 December 2007). "LED's Outpower QDLED's".
^"Ocean NanoTech research in QDLEDs". Archived from the original on 2009-04-29. Retrieved 2009-05-02.
^"Wireless Technology & Innovation - Mobile Technology - Qualcomm" (PDF). Archived from the original (PDF) on 2011-06-11.
^"IMOD" (PDF). Archived from the original (PDF) on 2008-03-09.
^Ridden, Paul (2023-02-23). "Meta-display concept could retire LCD panels in big-screen TVs". New Atlas. Retrieved 2023-02-23.
