List of broadcast video formats

This list of broadcast formats is a review of the most popular formats used to broadcast video information over Cable Television, Satellite, the Internet, and other means. Video broadcasting was popularized by the advent of the television during the middle of the twentieth century.[1]

Recently, Internet streaming has almost surpassed television as the top video broadcast platform.[2]

This film, television or video-related list is incomplete; you can help by expanding it with reliably sourced additions.

Below is a list of broadcast video formats.

  • 24p is a progressive scan format and is now widely adopted by those planning on transferring a video signal to film. Film and video makers use 24p even if they are not going to transfer their productions to film, simply because of the on-screen "look" of the (low) frame rate, which matches native film. When transferred to NTSC television, the rate is effectively slowed to 23.976 FPS (24×1000÷1001 to be exact), and when transferred to PAL or SECAM it is sped up to 25 FPS. 35 mm movie cameras use a standard exposure rate of 24 FPS, though many cameras offer rates of 23.976 FPS for NTSC television and 25 FPS for PAL/SECAM. The 24 FPS rate became the de facto standard for sound motion pictures in the mid-1920s.[3] Practically all hand-drawn animation is designed to be played at 24 FPS. Actually hand-drawing 24 unique frames per second ("1's") is costly. Even in big budget films, usually hand-drawn animation is done shooting on "2's" (one hand-drawn frame is shown twice, so only 12 unique frames per second)[4] and some animation is even drawn on "4's" (one hand-drawn frame is shown four times, so only six unique frames per second).
  • 25p is a progressive format and runs 25 progressive frames per second. This frame rate derives from the PAL television standard of 50i (or 50 interlaced fields per second). Film and television companies use this rate in 50 Hz regions for direct compatibility with television field and frame rates. Conversion for 60 Hz countries is enabled by doing 2:2:3:2:3 pulldown.[5] This is similar to 2:3 pulldown, and the result looks identical to a typical film transfer. While 25p captures half the temporal resolution or motion that normal 50i PAL registers, it yields a higher vertical spatial resolution per frame. Like 24p, 25p is often used to achieve "cine"-look, albeit with virtually the same motion artifacts. It is also better suited to progressive-scan output (e.g., on LCD displays, computer monitors and projectors) because the interlacing is absent.
  • 29.97 was the stated frame rate that NTSC legacy American television broadcasts traditionally used. However this is a misnomer; in NTSC 59.94 images per second were transmitted, the first image of each pair containing the "odd" scanlines, and the second of each pair containing the "even" scanlines. Each scan did produce a complete image, yielding 59.94 images per second. Because the unscanned/blank lines were not transmitted, the resulting images were 1/2 height. The television stretched them back out vertically by "double spacing" the scanlines it effectively "typed" across the face of the picture tube. This was the standard format of American TVs due to the displaying of CRT screens which were common place before the wide spread use of digital monitors. Alternating currents are used to time each scan, by which two scans are performed per frame due to interlacing of the display. The NTSC method implemented in the display of televisions bandwidth of the frequency requires an odd integer multiple of the horizontal frequency divided into two separate interlacing parallel line patterns. The Horizontal frequency was 15,750. This format was the solution caused by the problem of 30 Frames per second is not able to output to the even integer by the odd integer multiple. Each conducted scan equals 262.5 rows on the television set with interlacing totaling 525 rows. Before 1953 the entire frequency band of the TV was divided between black and white image and sound, but after the introduction of color broadcasting to widespread commercial use, more information was needed to provide for the color. The space between each frequency on the band was dedicated as to not cause electromagnetic interference between the picture and the sound. 6 MHz is dedicated to each analog broadcasting station. 1.5 MHz of which is unusable due to the electromagnetic interference gap between frequencies. This format fell out of use because of the introduction of digital broadcasting and online streaming.[6]
  • 30p is a progressive format and produces video at 30 frames per second. Progressive (noninterlaced) scanning mimics a film camera's frame-by-frame image capture. The effects of inter-frame judder are less noticeable than 24p yet retains a cinematic-like appearance. Shooting video in 30p mode gives no interlace artifacts but can introduce judder on image movement and on some camera pans. The widescreen film process Todd-AO used this frame rate in 1954–1956.[7]
  • 48p is a progressive format and that is being trialled in the film industry. At twice the traditional rate of 24p, this frame rate attempts to reduce motion blur and flicker found in films. Director James Cameron stated his intention to film the two sequels to his film Avatar higher than 24 frames per second to add a heightened sense of reality.[8] The first film to be filmed at 48 FPS was The Hobbit: An Unexpected Journey, a decision made by its director Peter Jackson.[9] At a preview screening at CinemaCon, the audience's reaction was mixed after being shown some of the film's footage at 48p, with some arguing that the feel of the footage was too lifelike (thus breaking the suspension of disbelief).[10]
  • 50i is an interlaced format and is the standard video field rate per second for PAL and SECAM television.
  • 60i is an interlaced format and is the standard video field rate per second for NTSC television (e.g., in the US), whether from a broadcast signal, DVD, or home camcorder. This interlaced field rate was developed separately by Farnsworth and Zworykin in 1934,[11] and was part of the NTSC television standards mandated by the FCC in 1941. When NTSC color was introduced in 1953, the older rate of 60 fields per second was reduced by a factor of 1000/1001 to avoid interference between the chroma subcarrier and the broadcast sound carrier. (Hence the usual designation "29.97 FPS" = 30 frames (60 fields)/1.001)
  • 59.94p is the frame rate used for 720p broadcast HDTV, as specified in SMPTE 296M. It is also, in reality, the frame rate of 1080i broadcasts, which, like NTSC, send the "odd" scanlines in the first of each pair of frames (1/60th) and the "even" scanlines in the second frame of each pair. It is purely custom to state the frame rate of the pair of frames as the actual frame rate but this is incorrect and causes great confusion. There are two frames in each pair; each frame is a photograph of the image and can be thought of as a complete frame. Each represents 1/60th /sec. Each frame is sent as 1920 (width) x 540 (height with unscanned lines eliminated) x 59.94fps. [12]
  • 50p/60p is a progressive format and is used in high-end HDTV systems. While it is not technically part of the ATSC or DVB broadcast standards yet, reports suggest that higher progressive frame rates will be a feature of the next-generation high-definition television broadcast standards.[13] In Europe, the EBU considers 1080p50 the next step future proof system for TV broadcasts and is encouraging broadcasters to upgrade their equipment for the future.[14] Many modern cameras can shoot video at 50p and 60p in various resolutions. YouTube allowed users to upload videos at 50 FPS and 60 FPS in June 2014. YouTube also allowed full HFR videos previously uploaded before 2014. Douglas Trumbull, who undertook experiments with different frame rates that led to the Showscan film format, found that emotional impact peaked at 60 FPS for viewers.[15]
  • 72p is a progressive format and is currently in experimental stages. Major institutions such as Snell have demonstrated 720p72 pictures as a result of earlier analogue experiments, where 768 line television at 75 FPS looked subjectively better than 1150 line 50 FPS progressive pictures with higher shutter speeds available (and a corresponding lower data rate). Modern cameras such as the Red One can use this frame rate to produce slow motion replays at 24 FPS.
  • 100p / 119.88p / 120p are progressive-scan formats standardized for UHDTV by the ITU-R BT.2020 recommendation.

See also

References
  1. Stephens, Mitchell (2000). "History of Television". Grolier Encyclopedia (2000 ed.). New York City: Grolier.
  2. "Netflix May Be Poised to Surpass Cable in the Near Future". Observer. 2017-12-20. Retrieved 2018-04-22.
  3. Brownlow, Kevin (Summer 1980). "Silent Films: What Was the Right Speed?". Sight & Sound. 49 (3): 164–167. Archived from the original on 8 July 2011. Retrieved 2 May 2012.
  4. "How many cels does a typical cartoon yield?" Archived 2011-05-19 at the Wayback Machine
  5. 2:2:3:2:3 Pulldown
  6. "Analog TV Is Dead. Is Broadcast TV Dying?". NPR.org. Retrieved 2017-12-28.
  7. Todd-AO Specifications at a Glance, Widescreen Museum.
  8. Giardina, Carolyn (March 30, 2011). "James Cameron 'Fully Intends' to Make 'Avatar 2 and 3' at Higher Frame Rates". The Hollywood Reporter. Retrieved April 4, 2010.
  9. Jackson, Peter (12 April 2011). "48 Frames Per Second". Peter Jackson's Facebook page. Facebook. Retrieved 12 April 2011.
  10. Walters, Florence (25 April 2012). "The Hobbit previews to mixed reactions". The Daily Telegraph. London. Retrieved 30 April 2012.
  11. Gary Edgerton, The Columbia History of American Television, Columbia University Press, 2009, p. 51–52. ISBN 978-0-231-12165-1.
  12. Soseman, Ned. "What's the difference between 59.94fps and 60fps?". Archived from the original on 29 June 2017. Retrieved 12 July 2017.
  13. Hoffmann, Hans; Takebumi Itagaki; David Wood; Alois Bock (December 2006). "Studies on the Bit Rate Requirements for a HDTV Format With 1920 × 1080 pixel Resolution, Progressive Scanning at 50 Hz Frame Rate Targeting Large Flat Panel Displays" (PDF). IEEE Transactions on Broadcasting. 52 (4): 420–434. doi:10.1109/tbc.2006.884735.
  14. "10 Things You Need to Know about 1080p50" (PDF). EBU Technical.
  15. "Beyond 24fps".
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