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Line 1: {{Short description\|Analog video monitor}} A '''multiple-sync''' ('''multisync''') '''monitor''', also known as a '''multiscan''' or '''multimode''' monitor, is a [[Raster scan\|raster-scan]] video [[Computer display\|monitor]], generally used for computer displays, that can properly [[Synchronization\|synchronise]] with multiple [[Horizontal scan rate\|horizontal]] and [[Vertical synchronization\|vertical]] [[Scan rate\|scan rates]].<ref>{{cite web\|title=13 What's the difference between fixed frequency and multisynchronous monitors?\|url=http://stason.org/TULARC/pc/video-faq/13-What-s-the-difference-between-fixed-frequency-andmultisynchronous-monitors.html}} 070808 stason.org</ref><ref>{{Cite web\|last=\|first=\|date=\|title=Standards FAQ\|url=https://vesa.org/vesa-standards/standards-faq/\|url-status=live\|archive-url=\|archive-date=\|access-date=2020-08-16\|website=VESA - Interface Standards for The Display Industry\|language=en-US\|quote=Multimode monitors can measure the incoming sync signal frequencies and thus sync to any frequency within their range of operation.}}</ref> In contrast, fixed frequency monitors can only synchronise with a specific set of scan rates.▼ {{More citations needed\|date=May 2023}} ▲A '''multiple-sync''' ('''multisync''') '''monitor''', also known as a '''multiscan''' or '''multimode''' monitor, is a [[Raster scan\|raster-scan]] [[analog device\|analog]] video [[Computer display\|monitor]]~~, generally used for computer displays,~~ that can properly [[Synchronization\|synchronise]] with multiple [[Horizontal scan rate\|horizontal]] and [[Analog television#Vertical synchronization\|vertical]] [[~~Scan~~Vertical scan rate\|scan ~~rates~~rate]]s.<ref>{{cite web\|title=13 What's the difference between fixed frequency and multisynchronous monitors?\|url=http://stason.org/TULARC/pc/video-faq/13-What-s-the-difference-between-fixed-frequency-andmultisynchronous-monitors.html}} 070808 stason.org</ref><ref>{{Cite web~~\|last=\|first=\|date=~~\|title=Standards FAQ\|url=https://vesa.org/vesa-standards/standards-faq/~~\|url-status=live\|archive-url=\|archive-date=~~\|access-date=2020-08-16\|website=VESA - Interface Standards for The Display Industry\|language=en-US\|quote=Multimode monitors can measure the incoming sync signal frequencies and thus sync to any frequency within their range of operation.}}</ref> In contrast, fixed frequency monitors can only synchronise with a specific set of scan rates. They are generally used for computer displays, but sometimes for television, and the terminology is mostly applied to [[Cathode-ray tube\|CRT displays]] although the concept applies to other technologies. Multiscan computer monitors appeared during the ~~late~~mid 1980s, offering flexibility as computer video hardware shifted from producing a single fixed scan rate to multiple possible scan rates.<ref>{{cite web \|title=MultiSync 25th Anniversary{{Snd}} The Evolution of the MultiSync \|url=http://www.nec-display.com/ap/en_display/25th/~~}}</ref>~~ ~~offering~~\|url-status=dead ~~flexibility~~\|archive-url=https://web.archive.org/web/20211101010646/https://www.nec-display.com/ap/en_display/25th/ as\|archive-date=1 ~~computers~~November ~~moved from earlier standards such as [[composite video]]~~2021 ~~and [[Color Graphics Adapter~~\|~~CGA]],~~website=NEC ~~which~~Display ~~utilized a single set refresh rate~~Solutions, toLtd.}}</ref> ~~standards~~"MultiSync" ~~implementing~~specifically ~~multiple~~was ~~scan~~a ~~rates~~trademark ~~such~~of asone of [[~~Enhanced Graphics Adapter~~NEC\|~~EGA~~NEC's]], ~~[[VGA]]~~first ~~and~~multiple-sync ~~[[SVGA]]~~monitors.<ref name=":1" /> == Computers == The term "MultiSync" derives from an [[NEC]] trademark for one of the first multiple-sync monitors. Sond uses the terms "Multiscan" and "MultiFormat" instead, and Samsung uses the "SyncMaster" trademark. === History === Early [[~~Home~~home computer~~\|home computers~~]]s output video to ordinary televisions or [[~~Composite~~composite monitor~~\|composite monitors~~]]s, utilizing television display standards such as [[NTSC]], [[PAL]] or [[SECAM]]. These display standards had fixed scan rates, and only used the vertical and horizontal sync pulses embedded in the video signals to ensure synchronization, not to set the actual scan rates. ~~Computers~~Early ~~that~~dedicated ~~did~~[[computer ~~not use ordinary televisions~~monitor]]s still often relied on fixed scan rates. IBM's original 1981 [[IBM Personal Computer\|PC]], for instance, was sold with a choice of two video cards ([[IBM Monochrome Display Adapter\|MDA]] and [[Color Graphics Adapter\|CGA]]) which were intended for use with custom, IBM monitors which still used fixed scan~~-rate~~ ~~IBM~~rates. The CGA timings were identical to NTSC television, whereas the MDA card used a custom timing for higher resolution to provide better text quality. Early Macintosh monitors also used fixed scan rates. ~~Released in~~In 1984, IBM's [[Enhanced Graphics Adapter\|EGA]] ~~required~~added a second resolution which necessitated the use of a ~~dual-sync~~ monitor ~~which~~supporting ~~supported the~~two scan ~~rate~~rates, ofthe original CGA rate as well as a second scan rate for ~~EGA's~~the new video modes.<ref name=":0">{{Cite book~~\|last=\|first=~~\|url=http://minuszerodegrees.net/oa/OA%20-%20IBM%20Enhanced%20Color%20Display%20(5154).pdf\|title=IBM Enhanced Color Display Manual\|~~publisher~~pages=1}}</ref> This monitor as well as others that could be manually switched between these two sync rates were known as dual-scan displays.<ref name="InfoWorld">{{Cite book\|~~year~~url=https://books.google.com/books?id=YToEAAAAMBAJ&dq=dual-sync%20EGA&pg=PA39\|~~isbn~~title=InfoWorld\|~~___location~~date=1988-08-22\|~~pages~~publisher=1InfoWorld Media Group, Inc.\|language=en}}</ref> The ~~first~~NEC ~~multisync~~Multisync ~~monitor~~was released in 1985 for -use with the ~~NEC~~IBM ~~Multisync~~PC, -supporting ~~was~~a ~~released~~wide inrange ~~1985~~of tosync ~~provide~~frequencies ~~support~~including those for CGA, EGA, ~~the~~ various extended forms of those standards marketed by third party vendors, and standards yet to be released.<ref name=":1">{{Cite book~~\|last=Inc\|first=InfoWorld Media Group~~\|url=https://books.google.com/books?id=mTwEAAAAMBAJ~~&lpg=PA61~~&dq=multisync&pg=PA61~~#v=onepage&q&f=false~~\|title=InfoWorld\|date=1986-10-27\|publisher=InfoWorld Media Group, Inc.\|language=en}}</ref> IBM's 1987 [[Video Graphics Array\|VGA]] standard, in turn, expanded to three fixed scan rates,. ~~but~~At ~~soon~~this ~~VGA~~point, ~~began~~PC toand beMac ~~extended~~owners bywith ~~third-party~~multiple ~~vendors~~graphics ~~and~~cards ~~[[Video~~required ~~Electronics~~unique ~~Standards~~monitors ~~Association\|VESA]]~~for ~~into~~each ~~[[Super~~of ~~VGA]]~~them,<ref ~~which~~name="InfoWorld"/> ~~implemented~~and ~~both~~by ~~higher~~the ~~resolutions~~late ~~and~~80s ~~different~~all ~~[[Refresh~~of ~~rate\|refresh~~the ~~rates]]~~below ~~for~~computer video standards required monitors which supported a ~~single~~small ~~given~~number ~~resolution.~~of specific frequencies: # [[PAL]], [[NTSC]], [[Color Graphics Adapter\|CGA]]: ~15.7 kHz horizontal scan, 50 or 60 Hz vertical scan By the late 1990s, monitors were available with specs ranging from 1024x768 at 60 Hz, to at least 1600x1200 at 85 Hz.<ref>{{Cite book\|last=Inc\|first=InfoWorld Media Group\|url=https://books.google.com/books?id=DDwEAAAAMBAJ&lpg=PA14-IA1&dq=infoworld%2085hz&pg=PA14-IA1#v=onepage&q&f=false\|title=InfoWorld\|date=1997-12-15\|publisher=InfoWorld Media Group, Inc.\|language=en}}</ref> In addition to these higher resolutions and frequencies, during system boot the [[Power-on self-test\|POST]] display on their host systems would operate at the standard VGA mode of 320x200 at 70Hz, so a monitor of this type would need to be able to horizontally scan in a range from at least 31 to 68kHz.▼ # [[Enhanced Graphics Adapter\|EGA]]: 15.7 kHz (CGA compatible mode) or 21.8 kHz horizontal scan, 60 Hz vertical scan # [[VGA]]: 31.5 kHz horizontal scan, 60 or 70 Hz vertical scan. No support for CGA/EGA timings. CGA/EGA resolutions are transmitted to the monitor at VGA compatible timings. # [[XGA]]: 35.5 kHz horizontal scan, 87 Hz (43.5 Hz interlaced) vertical scan (plus VGA modes) # Many different display formats for Macintosh, Sun, NeXT, and other microcomputers After 1987's [[Video Graphics Array\|VGA]]. the IBM market began to develop [[Super VGA]] cards which used many different scan rates, culminating in the [[VESA BIOS Extensions\|VBE]] which established standardized methods for outputting many different resolutions from one card, eventually becoming the [[Generalized Timing Formula]] which permitted graphics cards to output arbitrary resolutions. In response, VESA established a standardized list of display resolutions, refresh rates, and accompanying timing for hardware manufacturers.<ref>{{Cite book\|last=Inc\|first=Ziff Davis\|url=https://books.google.com/books?id=eX8w8B-OhIIC&lpg=PA151&dq=vesa%20display%20monitor%20timings&pg=PA177#v=onepage&q&f=false\|title=PC Mag\|date=1993-07\|publisher=Ziff Davis, Inc.\|language=en}}</ref> This was superseded by VESA's [[Generalized Timing Formula]], which provided a standard method to derive the timing of an arbitrary display mode from its sync pulses,<ref>{{Cite web\|last=\|first=\|date=\|title=Standards FAQ\|url=https://vesa.org/vesa-standards/standards-faq/\|url-status=live\|archive-url=\|archive-date=\|access-date=2020-08-16\|website=VESA - Interface Standards for The Display Industry\|language=en-US\|quote=Q: How will GTF help the monitor automatically set itself to any timing format? / A: GTF defines the relationship between syncs and video signals at any frequency of operation. The display can measure the incoming sync frequency, and thus can predict where the image will start and finish, even though it may not have been preset at that operating point.}}</ref> and this in turn was superseded by VESA's [[Coordinated Video Timings]] standard.▼ ▲By the late 1990s, ~~monitors~~graphics cards for microcomputers were available with specs ranging from 1024x768 at 60  Hz, to at least 1600x1200 at 85 Hz.<ref>{{Cite book~~\|last=Inc\|first=InfoWorld Media Group~~\|url=https://books.google.com/books?id=DDwEAAAAMBAJ~~&lpg=PA14-IA1~~&dq=infoworld%2085hz&pg=PA14-IA1~~#v=onepage&q&f=false~~\|title=InfoWorld\|date=1997-12-15\|publisher=InfoWorld Media Group, Inc.\|language=en}}</ref> In addition to these higher resolutions and frequencies, during system boot ~~the [[Power-~~on ~~self-test\|POST]]~~systems ~~display~~like onthe ~~their~~IBM ~~host~~PC, ~~systems~~the display would operate at ~~the~~ standard ~~VGA~~low ~~mode~~resolution, such as the PC standard of ~~320x200~~720x400 at ~~70Hz,~~70 Hz. ~~so a~~A monitor capable of ~~this~~displaying ~~type~~at both resolutions would need to be able to horizontally scan in a range from at least 31 to ~~68kHz~~68 kHz. == Implementation ==▼ Early multisync monitors designed for use with CGA / EGA / VGA standards supported limited fixed frequencies, e.g. 15.7 kHz, 21.8 kHz and 31.5 kHz horizontal rates, detected via the polarity of one or both H- and V-sync signals sent by the video adapter.<ref name=":0" /> ▼ ▲In response, VESA established a standardized list of display resolutions, refresh rates, and accompanying timing for hardware manufacturers.<ref>{{Cite book~~\|last=Inc\|first=Ziff Davis~~\|url=https://books.google.com/books?id=eX8w8B-OhIIC~~&lpg=PA151~~&dq=vesa%20display%20monitor%20timings&pg=PA177~~#v=onepage&q&f=false~~\|title=PC Mag\|date=July 1993~~-07~~\|publisher=Ziff Davis, Inc.\|language=en}}</ref> This was superseded by VESA's [[Generalized Timing Formula]], which provided a standard method to derive the timing of an arbitrary display mode from its sync pulses,<ref>{{Cite web~~\|last=\|first=\|date=~~\|title=Standards FAQ\|url=https://vesa.org/vesa-standards/standards-faq/~~\|url-status=live\|archive-url=\|archive-date=~~\|access-date=2020-08-16\|website=VESA - Interface Standards for The Display Industry\|language=en-US\|quote=Q: How will GTF help the monitor automatically set itself to any timing format? / A: GTF defines the relationship between syncs and video signals at any frequency of operation. The display can measure the incoming sync frequency, and thus can predict where the image will start and finish, even though it may not have been preset at that operating point.}}</ref> and this in turn was superseded by VESA's [[Coordinated Video Timings]] standard. Later designs supported a continuous range of scan frequencies, such as the original NEC Multisync which supported horizontal scan rates from 15 to 31 kHz<ref name=":1" /> derived from the sync signal timing rather than the polarity of the sync signals.<ref>{{Cite web\|title=PC Mag 1987-03-31 : Free Download, Borrow, and Streaming\|url=https://archive.org/details/PC-Mag-1987-03-31\|access-date=2020-08-16\|website=Internet Archive\|language=en}}</ref> ▼ ▲=== Implementation === Modern monitors produced using the VESA frequency standards generally support arbitrary scan rates up to a specific maximum horizontal and vertical rate. Most modern multiscan computer monitors have a minimum horizontal scan frequency of 31kHz.<ref>{{Cite web\|title=Converters {{!}} RetroRGB\|url=https://www.retrorgb.com/converters.html\|access-date=2020-08-16\|language=en-US}}</ref> ▼ ▲Early multisync monitors designed for use with ~~CGA~~systems /having a small number of specific frequencies, like CGA, EGA /and VGA, ~~standards~~or built-in Macintosh graphics, supported limited fixed frequencies~~, e.g~~. ~~15.7 kHz~~On the IBM PC, ~~21.8 kHz~~these ~~and~~were ~~31.5 kHz~~signaled ~~horizontal~~from ~~rates,~~the graphics card to the ~~detected~~monitor ~~via~~through the ~~polarity~~polarities of one or both H- and V-sync signals sent by the video adapter.<ref name=":0" /> ▲Later designs supported a continuous range of scan frequencies, such as the ~~original~~ NEC Multisync which supported horizontal scan rates from 15 to 31 kHz<ref name=":1" /> derived from the sync signal timing rather than the polarity of the sync signals.<ref>{{Cite web\|title=PC Mag 1987-03-31 : Free Download, Borrow, and Streaming\|url=https://archive.org/details/PC-Mag-1987-03-31\|access-date=2020-08-16\|website=Internet Archive\|date=31 March 1987 \|language=en}}</ref> Displays like these could be used on multiple platforms and video cards as long as the frequencies were within range. In both multisync and fixed-sync monitors, timing is important to prevent image distortion and even damage to components.<ref>{{Cite web\|last=\|first=\|date=\|title=Standards FAQ\|url=https://vesa.org/vesa-standards/standards-faq/\|url-status=live\|archive-url=\|archive-date=\|access-date=2020-08-16\|website=VESA - Interface Standards for The Display Industry\|language=en-US\|quote=Sync signals for displays drastically affect the quality, performance and even reliability of CRT displays. Even small differences in timing parameters can significantly affect image position and size, causing problems for the user. Difference in blanking times can lead to excessive power dissipation and electrical stress in the scanning circuits, or at the other extreme, incomplete or distorted images being displayed.}}</ref> Most modern multiscan monitors are [[microprocessor]] controlled<ref>{{Cite web\|last=\|first=\|date=\|title=Standards FAQ\|url=https://vesa.org/vesa-standards/standards-faq/\|url-status=live\|archive-url=\|archive-date=\|access-date=2020-08-16\|website=VESA - Interface Standards for The Display Industry\|language=en-US\|quote=In order to identify the mode, most present day multiple frequency monitors use a simple microcontroller to measure syncs.}}</ref> and will refuse to attempt to synchronise to an unsupported scan rate, which usually protects them from damage.▼ ▲Modern monitors produced using the VESA frequency standards generally support arbitrary scan rates upbetween tospecific aminimum ~~specific~~and maximum horizontal and vertical ~~rate~~rates. Most modern multiscan computer monitors have a minimum horizontal scan frequency of ~~31kHz~~31 kHz.<ref>{{Cite web\|title=Converters {{!}} RetroRGB\|url=https://www.retrorgb.com/converters.html\|access-date=2020-08-16\|language=en-US}}</ref> == Non-CRT monitors ==▼ The multisync concept applies to non-CRT monitors, such as [[LCD\|LCDs]], but is implemented differently.▼ ▲In both multisync and fixed-sync monitors, timing is important to prevent image distortion and even damage to components.<ref>{{Cite web~~\|last=\|first=\|date=~~\|title=Standards FAQ\|url=https://vesa.org/vesa-standards/standards-faq/~~\|url-status=live\|archive-url=\|archive-date=~~\|access-date=2020-08-16\|website=VESA - Interface Standards for The Display Industry\|language=en-US\|quote=Sync signals for displays drastically affect the quality, performance and even reliability of CRT displays. Even small differences in timing parameters can significantly affect image position and size, causing problems for the user. Difference in blanking times can lead to excessive power dissipation and electrical stress in the scanning circuits, or at the other extreme, incomplete or distorted images being displayed.}}</ref> Most modern multiscan monitors are [[microprocessor]] controlled<ref>{{Cite web~~\|last=\|first=\|date=~~\|title=Standards FAQ\|url=https://vesa.org/vesa-standards/standards-faq/~~\|url-status=live\|archive-url=\|archive-date=~~\|access-date=2020-08-16\|website=VESA - Interface Standards for The Display Industry\|language=en-US\|quote=In order to identify the mode, most present day multiple frequency monitors use a simple microcontroller to measure syncs.}}</ref> and will refuse to attempt to synchronise to an unsupported scan rate, which usually protects them from damage. ▲=== Non-CRT monitors === ▲The multisync concept applies to non-CRT monitors, such as [[LCD~~\|LCDs~~]]s, but is implemented differently. LCD monitors are [[Fixed pixel display\|fixed-pixel displays]], where the number of rows and columns displayed on the screen are constant, set by the construction of the panel. When the input signal has a resolution that does not match the number of pixels in the display, the LCD controller must still populate the same number of image elements. Line 36 ⟶ 46: This is accomplished either by [[Video scaler\|scaling]] the image up or down as needed, creating a picture that does not have a 1:1 relationship between LCD image elements and pixels in the original image, or by displaying the image unscaled in the center of the monitor, filling the spaces on all sides with black pixels. While stand-alone LCD monitors generally accept a wide range of horizontal scan rates, the majority of LCDs accept only 60 Hz to 75 Hz vertical scan rates. In recent years, LCD monitors designed for gaming have appeared on the market offering vertical scan rates of 120 Hz and up.<ref>{{cite web\|title=List of 120Hz monitors{{Snd}} Includes 144Hz, 240Hz Blur Busters\|url=http://www.blurbusters.com/faq/120hz-monitors/}}</ref> These monitors are usually referred to by their specific max refresh rate. == Television == {{Unreferenced section\|date=May 2023}} CRT televisions are typically designed to operate only with the video standard of the country they are sold in ([[PAL]], [[NTSC]], [[SECAM]]), but some sets, particularly broadcast monitors, can operate on multiple standards. == References == Line 43 ⟶ 57: * [http://www.webopedia.com/TERM/M/multiscanning_monitor.html Multiscanning monitor] webopedia. [[Category:~~Display~~Electronic display devices]] [[Category:Graphics hardware]]