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High definition television is part of a larger standard known as DTV, or Digital Television. DTV is actually comprised of 18 different standards, six of which are High Definition. Of these, five are progressive standards, while one is interlaced (1080i). Of the remaining formats, eight are SDTV (four wide-screen formats with 16:9 aspect ratios, and four conventional formats with 4:3 aspect ratios), and the remaining four are video graphics array (VGA) formats. Broadcasters are free to choose which formats to broadcast.
The most common DTV formats are:
- 480p - 480 vertical pixels progressive
- 720p - 720 vertical pixels progressive
- 1080i - 1080 vertical pixels interlaced
- 1080p - 1080 vertical pixels progressive
"Interlaced" or "progressive" refers to the display type. In an interlaced format, the screen shows every odd line during one scan (or field), and then follows that up with the even lines in a second scan, displaying each half frame in 1/60th of a second. These two fields then combine into a single frame of video lasting 1/30th of a second. As a result, your NTSC TV acts very much like a high frequency strobe light, with two lights flashing alternately. This, obviously, is not the best way to show a moving picture; image noise and distortion are common. As screens get larger, these distortions show up as flicker, ghosting, and other types of “noise”. For smaller screens, this is less noticeable.
Progressive scanning shows the whole picture, every line at the same instant, every sixtieth of a second. This provides for a much smoother picture, but uses more bandwidth – the picture information is twice as large. The resulting image is superior because progressive scanning (or “full frame”) reduces undesirable features like ghosting and image artefacting, as well as producing a more natural transition between frames; you eyes and brain don’t have to work as hard to blend the still images into one fluid sequence.
HD vs. HD Ready
Plasmas are available in two DTV formats, HD and ED. HD units, like the Pioneer 434CMX, NEC 42XM3HA, Panasonic TH-42PHD8UK, all have screen resolutions of 1024x768 (XGA), and are capable of displaying HD without significant down sampling of the image (see below). Enhanced definition, or HD “Compatible” units, like the NEC 42VM5, and Panasonic TH-42PWD8UK are capable of receiving HD input, but resize the image to fit onto their lower resolution displays (852x480). It’s worth noting that there is absolutely no problem displaying HD on an ED display, and at average viewing distances, the difference between HD and ED is very difficult to see.
The current generation of 50 inch and larger plasmas are almost always HD units, with resolutions of 1280x768 or greater.
Understanding Resolution
The first number in your plasma’s pixel ratio refers to the horizontal pixel rows, the pixels running up and down arranged horizontally, like the slats in a picket fence. The second number, the lower number, refers to the pixel rows running vertically, from side to side, like layers in a cake. Your plasma display has a fixed number of pixels, and compensates for the various DTV formats by re-sampling the DTV signal into something that conforms to the actual, physical pixels present in the display panel. Currently, only the lowest standards of HD (720p) are supported by even the highest resolution plasmas. 1080p and 1080i native (without re-sampling or downscaling) displays are only currently available on high end broadcast television production monitors and LCDs. Most US and Canadian broadcasters are choosing to broadcast HD in the 720p format as a result. This doesn’t mean your HD or HD ready monitor won’t display these images. It simply means that even the most modern, up to date plasma down samples these resolutions while still retaining exceptional image clarity.
DVDs are currently encoded at 480i, or 480p for Progressive Scan enabled units. Due to limitations of compression technology, true HD encoded DVDs aren’t yet available (January 2004). There are exceptions: “Superbit” discs push the limit of modern encoding, often obtaining resolutions in excess of 500 lines. Microsoft has a true HD compressor / de-compressor, similar to the one used for WMV files. As of this writing, there aren’t any DVD player manufacturers who support the WMV format. Samsung has a DVD player that up converts DVDs to HD resolution, but this is really a stopgap measure, as picture quality is limited by the source material that is still encoded at 480 lines. Sony is in the process of introducing its Blue Laser HD DVD recorder, the BDZ-S77. Expect that in 2006 with a sticker price of four to five thousand dollars.
Reprinted from Wikipedia
Television is a telecommunication system for broadcasting and receiving moving pictures and sound over a distance. The term has come to refer to all the aspects of television from the television set to the programming and transmission. The word is derived from mixed Latin and Greek roots, meaning "far sight": Greek τῆλε "tele", far, and Latin visio-n, sight (from video, vis- to see).
The origins of what would become today's television system can be traced back as far as the discovery of the photoconductivity of the element selenium by Willoughby Smith in 1873 and the invention of a scanning disk by Paul Nipkow in 1884. All practical television systems use the fundamental idea of scanning an image to produce a time series signal representation. That representation is then transmitted to a device to reverse the scanning process. The final device, the television, relies on the human eye to integrate the result into a coherent image.
Electromechanical techniques were developed prior to World War II, most notably by Charles Francis Jenkins and John Logie Baird. Baird gave the world's first public demonstration of a working television system to members of the Royal Institution and a newspaper reporter on 26 January 1926 at his laboratory in London. Baird further demonstrated the world's first color television transmission on 3 July 1928.
Completely electronic television systems relied on the inventions of Philo Taylor Farnsworth, Vladimir Zworykin and others to produce a system suitable for mass distribution of television programming. Commercial broadcast programming, following years of experimental broadcasts seen only in a few specially-equipped homes, occurred in both the United States and the United Kingdom before World War II.
The first television broadcasts with a modern level of definition (more than 240 lines) were made in England in 1936. So-called "System A" used 405 lines. Television did not become common in United States homes until the middle 1950s. While North American over-the-air broadcasting was originally free of direct marginal cost to the consumer (i.e., cost in excess of acquisition and upkeep of the hardware) and broadcasters were compensated primarily by receipt of advertising revenue, increasingly United States television consumers obtain their programming by subscription to cable television systems or direct-to-home satellite transmissions. In the United Kingdom, on the other hand, the owner of each television must pay a licence fee annually which is used to support the British Broadcasting Corporation.
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