Community hub
Recent from talks
Knowledge base stats:
Talk channels stats:
Members stats:
Color television
Color television (American English) or colour television (British English) is a television transmission technology that also includes color information for the picture, so the video image can be displayed in color on the television set. It improves on the monochrome or black-and-white television technology, which displays the image in shades of gray (grayscale). Television broadcasting stations and networks in most parts of the world transitioned from black-and-white to color broadcasting between the 1960s and the 1980s. The invention of color television standards was an important part of the history and technology of television.
Transmission of color images using mechanical scanners had been conceived as early as the 1880s. A demonstration of mechanically scanned color television was given by John Logie Baird in 1928, but its limitations were apparent even then. Development of electronic scanning and display made a practical system possible. Monochrome transmission standards were developed prior to World War II, but civilian electronics development was frozen during much of the war. In August 1944, Baird gave the world's first demonstration of a practical fully electronic color television display. In the United States, competing color standards were developed, finally resulting in the NTSC color standard that was compatible with the prior monochrome system. Although the NTSC color standard was proclaimed in 1953, and limited programming soon became available, it was not until the early 1970s that color television in North America outsold black-and-white units. Color broadcasting in Europe did not standardize on the PAL or SECAM formats until the 1960s.[citation needed]
Broadcasters began to upgrade from analog color television technology to higher resolution digital television c. 2006; the transition year varies by country. While the changeover is complete in many countries, analog television still remains in use in some countries.[citation needed]
The human eye's detection system in the retina consists primarily of two types of light detectors: rod cells that capture light when there is not much of it available, and the cone cells that detect light of certain wavelengths when it is bright enough, and are responsible for color. A typical retina contains 4.5 million to 6 million cones, which are divided into three types, each one with a characteristic profile of excitability by different wavelengths of the spectrum of visible light.
The eye has limited bandwidth to the rest of the visual system, estimated at just under 8 Mbit/s. This manifests itself in a number of ways, but the most important in terms of producing moving images is the way that a series of still images displayed in quick succession will appear to be continuous smooth motion. This illusion starts to work at about 16 frame/s, and common motion pictures use 24 frame/s. Television, using power from the electrical grid, historically tuned its rate in order to avoid interference with the alternating current being supplied – in North America, some Central and South American countries, Taiwan, Korea, part of Japan, the Philippines, and a few other countries, this was 60 video fields per second to match the 60 Hz power, while in most other countries it was 50 fields per second to match the 50 Hz power. The NTSC color system changed from the black-and-white 60-fields-per-second standard to 59.94 fields per second to make the color circuitry simpler; the 1950s TV sets had matured enough that the power frequency/field rate mismatch was no longer important. Modern TV sets can display multiple field rates (50, 59.94, or 60, in either interlaced or progressive scan) while accepting power at various frequencies (often the operating range is specified as 48–62 Hz).
In its most basic form, a color broadcast can be created by broadcasting three monochrome images, one each in the three colors of red, green, and blue (RGB). When displayed together or in rapid succession, these images will blend together to produce a full-color image as seen by the viewer. To do so without making the images flicker, the refresh time of all three images put together would have to be above the critical limit, and generally the same as a single black and white image. This would require three times the number of images to be sent in the same time, greatly increasing the amount of radio bandwidth required to send the complete signal and thus similarly increasing the required radio spectrum. Early plans for color television in the United States included a move from very high frequency (VHF) to ultra high frequency (UHF) to open up additional spectrum.[citation needed]
One of the great technical challenges of introducing color broadcast television was the desire to conserve bandwidth. In the United States, after considerable research, the National Television Systems Committee approved an all-electronic system developed by RCA that encoded the color information separately from the brightness information and greatly reduced the resolution of the color information in order to conserve bandwidth. The brightness image remained compatible with existing black-and-white television sets at slightly reduced resolution, while color-capable televisions could decode the extra information in the signal and produce a limited-resolution color display. The higher resolution black-and-white and lower resolution color images combine in the eye to produce a seemingly high-resolution color image. The NTSC standard represented a major technical achievement.
Experiments with facsimile image transmission systems that used radio broadcasts to transmit images date to the 19th century. It was not until the 20th century that advances in electronics and light detectors made television practical. A key problem was the need to convert a 2D image into a "1D" radio signal; some form of image scanning was needed to make this work. Early systems generally used a device known as a "Nipkow disk", which was a spinning disk with a series of holes punched in it that caused a spot to scan across and down the image. A single photodetector behind the disk captured the image brightness at any given spot, which was converted into a radio signal and broadcast. A similar disk was used at the receiver side, with a light source behind the disk instead of a detector.[citation needed]
Hub AI
Color television AI simulator
(@Color television_simulator)
Color television
Color television (American English) or colour television (British English) is a television transmission technology that also includes color information for the picture, so the video image can be displayed in color on the television set. It improves on the monochrome or black-and-white television technology, which displays the image in shades of gray (grayscale). Television broadcasting stations and networks in most parts of the world transitioned from black-and-white to color broadcasting between the 1960s and the 1980s. The invention of color television standards was an important part of the history and technology of television.
Transmission of color images using mechanical scanners had been conceived as early as the 1880s. A demonstration of mechanically scanned color television was given by John Logie Baird in 1928, but its limitations were apparent even then. Development of electronic scanning and display made a practical system possible. Monochrome transmission standards were developed prior to World War II, but civilian electronics development was frozen during much of the war. In August 1944, Baird gave the world's first demonstration of a practical fully electronic color television display. In the United States, competing color standards were developed, finally resulting in the NTSC color standard that was compatible with the prior monochrome system. Although the NTSC color standard was proclaimed in 1953, and limited programming soon became available, it was not until the early 1970s that color television in North America outsold black-and-white units. Color broadcasting in Europe did not standardize on the PAL or SECAM formats until the 1960s.[citation needed]
Broadcasters began to upgrade from analog color television technology to higher resolution digital television c. 2006; the transition year varies by country. While the changeover is complete in many countries, analog television still remains in use in some countries.[citation needed]
The human eye's detection system in the retina consists primarily of two types of light detectors: rod cells that capture light when there is not much of it available, and the cone cells that detect light of certain wavelengths when it is bright enough, and are responsible for color. A typical retina contains 4.5 million to 6 million cones, which are divided into three types, each one with a characteristic profile of excitability by different wavelengths of the spectrum of visible light.
The eye has limited bandwidth to the rest of the visual system, estimated at just under 8 Mbit/s. This manifests itself in a number of ways, but the most important in terms of producing moving images is the way that a series of still images displayed in quick succession will appear to be continuous smooth motion. This illusion starts to work at about 16 frame/s, and common motion pictures use 24 frame/s. Television, using power from the electrical grid, historically tuned its rate in order to avoid interference with the alternating current being supplied – in North America, some Central and South American countries, Taiwan, Korea, part of Japan, the Philippines, and a few other countries, this was 60 video fields per second to match the 60 Hz power, while in most other countries it was 50 fields per second to match the 50 Hz power. The NTSC color system changed from the black-and-white 60-fields-per-second standard to 59.94 fields per second to make the color circuitry simpler; the 1950s TV sets had matured enough that the power frequency/field rate mismatch was no longer important. Modern TV sets can display multiple field rates (50, 59.94, or 60, in either interlaced or progressive scan) while accepting power at various frequencies (often the operating range is specified as 48–62 Hz).
In its most basic form, a color broadcast can be created by broadcasting three monochrome images, one each in the three colors of red, green, and blue (RGB). When displayed together or in rapid succession, these images will blend together to produce a full-color image as seen by the viewer. To do so without making the images flicker, the refresh time of all three images put together would have to be above the critical limit, and generally the same as a single black and white image. This would require three times the number of images to be sent in the same time, greatly increasing the amount of radio bandwidth required to send the complete signal and thus similarly increasing the required radio spectrum. Early plans for color television in the United States included a move from very high frequency (VHF) to ultra high frequency (UHF) to open up additional spectrum.[citation needed]
One of the great technical challenges of introducing color broadcast television was the desire to conserve bandwidth. In the United States, after considerable research, the National Television Systems Committee approved an all-electronic system developed by RCA that encoded the color information separately from the brightness information and greatly reduced the resolution of the color information in order to conserve bandwidth. The brightness image remained compatible with existing black-and-white television sets at slightly reduced resolution, while color-capable televisions could decode the extra information in the signal and produce a limited-resolution color display. The higher resolution black-and-white and lower resolution color images combine in the eye to produce a seemingly high-resolution color image. The NTSC standard represented a major technical achievement.
Experiments with facsimile image transmission systems that used radio broadcasts to transmit images date to the 19th century. It was not until the 20th century that advances in electronics and light detectors made television practical. A key problem was the need to convert a 2D image into a "1D" radio signal; some form of image scanning was needed to make this work. Early systems generally used a device known as a "Nipkow disk", which was a spinning disk with a series of holes punched in it that caused a spot to scan across and down the image. A single photodetector behind the disk captured the image brightness at any given spot, which was converted into a radio signal and broadcast. A similar disk was used at the receiver side, with a light source behind the disk instead of a detector.[citation needed]