Channel 1 (North American TV)

Last updated December 18, 2023

In North American broadcast television frequencies, channel 1 was a former broadcast (over-the-air) television channel which was removed from service in 1948.

During the experimental era of TV operation, Channel 1 was moved around the lower VHF spectrum repeatedly, with the entire band displaced upward at one point due to an early 40 MHz allocation for the FM broadcast band. After FM was moved to its current frequencies in 1946, TV Channel 1's last assigned band was 44 to 50 MHz. This allocation was short-lived.

Until 1948, Land Mobile Radio and television broadcasters shared the same frequencies, which caused interference. This shared allocation was eventually found to be unworkable, so the FCC reallocated the Channel 1 frequencies for public safety and land mobile use and assigned TV channels 2–13 exclusively to broadcasters. Aside from the shared frequency issue, this part of the VHF band was (and to some extent still is) prone to higher levels of radio-frequency interference (RFI) than even Channel 2 (System M).

As Mexico signed on its first station in 1950 and Canada's first station went on-air in 1952, the historical Channel 1 (System M) is exclusively a U.S. allocation artifact.

History

Channel 1 was allocated at 44–50 MHz between 1937 and 1940. Visual and aural carrier frequencies within the channel fluctuated with changes in overall TV broadcast standards prior to the establishment of permanent standards by the National Television Systems Committee.

In 1940, the FCC reassigned 42–50 MHz to the FM broadcast band. Television's channel 1 frequency range was moved to 50–56 MHz (see table below). Experimental television stations in New York, Chicago, and Los Angeles were affected.^[1]

Commercial TV allocations were made by the Federal Communications Commission (FCC) under the NTSC system on July 1, 1941. Channel 1 was located at 50–56 MHz, with visual carrier at 51.25 MHz and aural carrier at 55.75 MHz. At the same time, the spectrum from 42 to 50 MHz was allocated to FM radio. Several commercial and experimental television stations operated on the 50–56 MHz Channel 1 between 1941 and 1946, including one station, WNBT (now WNBC, channel 4) in New York City, which had a full commercial operating license.

In the first postwar allocation in the spring of 1946, Channel 1 was moved back to 44–50 MHz, with visual at 45.25 MHz and aural at 49.75 MHz. FM was moved to its current 88–108 MHz band. But WNBT and all other existing stations were moved to other channels, because the final Channel 1 was reserved for low-power community stations covering a limited area. While a handful of construction permits were issued for this final version of Channel 1, no station ever actually broadcast on it before it was removed from use in 1948.

When the FCC initially allocated broadcast television frequencies, channel 1 was logically the first channel. These U.S. TV stations originally broadcast on the 50–56 MHz channel 1:

W2XBS/WNBT/WRCA (today's WNBC), New York City (1941–1946), reassigned in 1946 to channel 4;
W6XAO/KTSL/KNXT (today's KCBS-TV), Los Angeles, reassigned post-war to channel 2;
W9XZV Chicago, Zenith's experimental station, billed as the first all-electric TV station in 1939.^[2] Reassigned post-war to Channel 2,^[3] it broadcast an early form of monochrome pay-TV in 1951 as K2XBS Phonevision and conducted early color television experiments before ultimately going dark in 1953.^[4] Its transmitters were donated to WTTW (PBS 11 Chicago)^[5] and its channel 2 assignment was taken by CBS O&O WBBM-TV.
KARO, Riverside, California; never began broadcasting, no current VHF allocation;
WSBE, South Bend, Indiana; never began broadcasting on channel 1, but was reallocated to UHF channel 34 in the 1952 revised channel allocation table, where it went on the air as WSBT-TV that year. As part of a consolidation of the Elkhart and South Bend communities into a single television market, WSBT-TV was moved in 1958 to UHF channel 22, where it remains as a digital CBS affiliate today; channel 34 became the home of PBS member station WNIT. No full-service VHF TV allocations were made available to South Bend due to its proximity to Chicago, making the city a UHF island.

By September 1945, additional stations temporarily granted construction permits to operate on channel 1 included:

W8XCT (WLW) Cincinnati, Ohio ultimately built on channel 4 as commercial station WLWT, later moved to channel 5.
W9RUI Iowa City, Iowa held an unbuilt construction permit, and additionally given a channel 12 assignment.^[6]
W8XGZ Charleston, West Virginia, licensed to a chemical company, also held a channel one construction permit; there is no indication the stations ever got on the air.^[7]

See also list of experimental television stations for additional channel one pioneers.

As a virtual channel, however, KAXT-CD in San Francisco (broadcasting on physical UHF channel 22) was assigned virtual channel 1 in July 2009, becoming the first American station to be assigned virtual channel 1 via the digital television PSIP standard, which shows the channel as such on a digital television set. KAXT-CD's physical broadcasts on UHF channel 22 cause no interference for Channel 1 physically. XHDF-TDT and all Azteca Uno stations broadcast on Virtual 1.

Community television

In 1946, prior to cable TV and the invention of public-access television channels, the FCC decided to reserve channel 1 for low-power Community television stations, and moved existing channel 1 stations to higher frequencies. Community television stations covered smaller cities and were allowed to use less radiated power. None of these stations were built before the FCC imposed a freeze on all television station construction permits in mid-1948, and removed the channel one allocations.

A shared (non-primary) allocation

From 1945 to 1948 TV stations in the U.S. shared Channel 1 and other channels with fixed and mobile services. The FCC decided in 1948 that a primary (non-shared) allocation of the VHF radio spectrum was needed for television broadcasting. Except for selected VHF frequencies in Alaska and Hawaii (and some overseas territories) the FCC-administered VHF band is primarily allocated for television broadcasting to this day.

The FCC in May 1948 formally changed the rules on TV band allocations based on propagation knowledge gained during the era of shared-user allocations. The 44–50 MHz band used by Channel 1 was replaced by lower-power narrowband users.

Channel 1 was reassigned to fixed and mobile services (44–50 MHz) in order to end their former shared use of other VHF TV frequencies. Rather than renumber the TV channel table, it was decided to merely remove Channel 1 from the table.

Cable television

On cable television systems, channel 1 was optionally used by some providers in between channels 4 and 5 at the frequencies of 72–78 MHz (moving channel 5 and 6 allocations up by 2 MHz; however, this would prevent channels 5 and 6 from being viewed on non-cable-ready television sets). Channel 1, where available, has also been mapped to 99 (frequency range 114–120 MHz) on some cable boxes.^[8]

Modern allocations 43–50 MHz

As of September 2000, the Federal Spectrum Use of the band (which is regulated by the NTIA and not the FCC)^[9] was as follows:

43.69–46.6 Non-Military Land Mobile Radio (LMR):
Primarily used by Federal agencies for mutual aid response with local communities.
Military LMR: Used by the military services for tactical and training operations on a non-interference basis. (Band is otherwise non-government exclusive).
46.6–47 Govt. FIXED MOBILE Allocation:
Non-Military LMR: Extensive use of this band is for contingency response to various national disasters. Others uses are for national resources management, law enforcement, tornado tracking, and various meteorological research support.
Military LMR: This band is used primarily for tactical and training operations by U.S. military units for combat net radio operations that provide command and control for combat, combat support, and combat service support units. Frequencies also used for air-to-ground communications for military close air support requirements as well as some other tactical air-ground and air-air communications.
47–49.6 Experimental:
Used for experimental research to observe and measure currents in harbor areas in support of vessel safety.
Military LMR: Used by the military services for tactical and training operations on a non-interference basis. (Band is otherwise non-government exclusive).
49.6–50 Govt. FIXED MOBILE Allocation:
Non-Military LMR: This band is used extensively to support contingencies or ecological emergencies, some public safety requirements, MARS system, and air-quality measurements.
Experimental: Research is performed in various regions of the atmosphere as well as experimental development of portable space orbital debris ground radars.
Military LMR: This band is used primarily for tactical and training operations by U.S. military units for combat net radio operations that provide command and control for combat, combat support, and combat service support units. Frequencies also used for air-to-ground communications for military close air support requirements as well as some other tactical air-ground and air-air communications.

FCC (NON-Federal) allocations for the band:

Primarily Land Mobile use from 43-46.6.
46.61-46.89 is used by older cordless phone base stations. The handsets use the 49.61 - 49.89 range for transmitting to the base unit.
47.0-49.60 is used by LMR and then the cordless phone range. Early experiments with meteor scatter one way messaging was in the 49 - 50 range back in the early 1990s but it no longer exists due to reliable and cheaper satellite communications.

There is also a conflict with the de facto intermediate frequency for system M television, where receiver tuners shift and flip the incoming signal onto 41.25 MHz (analogue audio) and 45.75 MHz (analogue video) after the initial RF amplifier. This standard was adopted due to image frequency problems when UHF television broadcasting initially struggled to life in 1952.

Any receivers capable of tuning VHF TV 1, by necessity, operated on a lower intermediate frequency as 45.75 MHz video IF would overlap the incoming signal at 44-50 MHz.

Channel 1 in other NTSC-using countries

Canada did not start regular television broadcasts until after the U.S. had decommissioned Channel 1 (44–50 MHz) for television use; CBFT and CBLT signed on in 1952. This TV channel was never used in Latin America, South Korea and the Philippines excluding Japan as TV broadcasting did not start in these areas until the 1950s.

Japanese public broadcaster NHK General TV broadcast on Channel 1 in Tokyo and other cities. The Japanese Channel 1 was assigned to the frequency 90 to 96 MHz, just above the Japanese FM band which is 76 to 90 MHz. Frequencies corresponding to Japan's channel 1 through 3 (90–108 MHz) are used primarily for FM radio broadcasting (88–108 MHz) outside Japan and correspond to cable 95–97 in North America. With the advent of digital television, these frequencies are being vacated by TV broadcasters and allocated to "wide FM" broadcasters, relocating from mediumwave AM to an extended FM band above 90 MHz.

The following commercial television stations operated on channel 1 on analog:

Hokkaido Broadcasting (HBC) in Sapporo, Hokkaido
Aomori Broadcasting Corporation (RAB) in Aomori, Aomori Prefecture
Tohoku Broadcasting Company (TBC) in Sendai, Miyagi Prefecture
Tokai Television Broadcasting (THK) in Nagoya, Aichi Prefecture
Kitanihon Broadcasting (KNB) in Toyama, Toyama Prefecture
Shikoku Broadcasting (JRT) in Tokushima, Tokushima Prefecture
Nihonkai Television (NKT) in Tottori, Tottori Prefecture (also serving Matsue, Shimane Prefecture)
Kyushu Asahi Broadcasting (KBC) in Fukuoka, Fukuoka Prefecture
Minaminihon Broadcasting (MBC) in Kagoshima, Kagoshima Prefecture

On digital television, their virtual channel number is 1 for historical reasons.

Related Research Articles

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<span class="mw-page-title-main">Very high frequency</span> Electromagnetic wave range of 30-300 MHz

Very high frequency (VHF) is the ITU designation for the range of radio frequency electromagnetic waves from 30 to 300 megahertz (MHz), with corresponding wavelengths of ten meters to one meter. Frequencies immediately below VHF are denoted high frequency (HF), and the next higher frequencies are known as ultra high frequency (UHF).

Ultra high frequency (UHF) is the ITU designation for radio frequencies in the range between 300 megahertz (MHz) and 3 gigahertz (GHz), also known as the decimetre band as the wavelengths range from one meter to one tenth of a meter. Radio waves with frequencies above the UHF band fall into the super-high frequency (SHF) or microwave frequency range. Lower frequency signals fall into the VHF or lower bands. UHF radio waves propagate mainly by line of sight; they are blocked by hills and large buildings although the transmission through building walls is strong enough for indoor reception. They are used for television broadcasting, cell phones, satellite communication including GPS, personal radio services including Wi-Fi and Bluetooth, walkie-talkies, cordless phones, satellite phones, and numerous other applications.

Terrestrial television or over-the-air television (OTA) is a type of television broadcasting in which the signal transmission occurs via radio waves from the terrestrial (Earth-based) transmitter of a TV station to a TV receiver having an antenna. The term terrestrial is more common in Europe and Latin America, while in Canada and the United States it is called over-the-air or simply broadcast. This type of TV broadcast is distinguished from newer technologies, such as satellite television, in which the signal is transmitted to the receiver from an overhead satellite; cable television, in which the signal is carried to the receiver through a cable; and Internet Protocol television, in which the signal is received over an Internet stream or on a network utilizing the Internet Protocol. Terrestrial television stations broadcast on television channels with frequencies between about 52 and 600 MHz in the VHF and UHF bands. Since radio waves in these bands travel by line of sight, reception is generally limited by the visual horizon to distances of 64–97 kilometres (40–60 mi), although under better conditions and with tropospheric ducting, signals can sometimes be received hundreds of kilometers distant.

The FM broadcast band is a range of radio frequencies used for FM broadcasting by radio stations. The range of frequencies used differs between different parts of the world. In Europe and Africa and in Australia and New Zealand, it spans from 87.5 to 108 megahertz (MHz) - also known as VHF Band II - while in the Americas it ranges from 88 to 108 MHz. The FM broadcast band in Japan uses 76 to 95 MHz, and in Brazil, 76 to 108 MHz. The International Radio and Television Organisation (OIRT) band in Eastern Europe is from 65.9 to 74.0 MHz, although these countries now primarily use the 87.5 to 108 MHz band, as in the case of Russia. Some other countries have already discontinued the OIRT band and have changed to the 87.5 to 108 MHz band.

Code of Federal Regulations, Title 47, Part 15 is an oft-quoted part of Federal Communications Commission (FCC) rules and regulations regarding unlicensed transmissions. It is a part of Title 47 of the Code of Federal Regulations (CFR), and regulates everything from spurious emissions to unlicensed low-power broadcasting. Nearly every electronics device sold inside the United States radiates unintentional emissions, and must be reviewed to comply with Part 15 before it can be advertised or sold in the US market.

The radio spectrum is the part of the electromagnetic spectrum with frequencies from 3 Hz to 3,000 GHz (3 THz). Electromagnetic waves in this frequency range, called radio waves, are widely used in modern technology, particularly in telecommunication. To prevent interference between different users, the generation and transmission of radio waves is strictly regulated by national laws, coordinated by an international body, the International Telecommunication Union (ITU).

The following tables show the frequencies assigned to broadcast television channels in various regions of the world, along with the ITU letter designator for the system used. The frequencies shown are for the analogue video and audio carriers. The channel itself occupies several megahertz of bandwidth. For example, North American channel 1 occupies the spectrum from 44 to 50 MHz. See Broadcast television systems for a table of signal characteristics, including bandwidth, by ITU letter designator.

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Apex radio stations was the name commonly given to a short-lived group of United States broadcasting stations, which were used to evaluate transmitting on frequencies that were much higher than the ones used by standard amplitude modulation (AM) and shortwave stations. Their name came from the tall height of their transmitter antennas, which were needed because coverage was primarily limited to local line-of-sight distances. These stations were assigned to what at the time were described as "ultra-high shortwave" frequencies, between roughly 25 and 44 MHz. They employed amplitude modulation (AM) transmissions, although in most cases using a wider bandwidth than standard broadcast band AM stations, in order to provide high fidelity sound with less static and distortion.

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Band I is a range of radio frequencies within the very high frequency (VHF) part of the electromagnetic spectrum. The first time there was defined "for simplicity" in Annex 1 of "Final acts of the European Broadcasting Conference in the VHF and UHF bands - Stockholm, 1961". Band I ranges from 47 to 68 MHz for the European Broadcasting Area, and from 54 to 88 MHz for the Americas and it is primarily used for television broadcasting in compliance with ITU Radio Regulations. With the transition to digital TV, most Band I transmitters have already been switched off.

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<span class="mw-page-title-main">CCIR System B</span> 625-line analog television transmission format

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UHF television broadcasting is the use of ultra high frequency (UHF) radio for over-the-air transmission of television signals. UHF frequencies are used for both analog and digital television broadcasts. UHF channels are typically given higher channel numbers, like the US arrangement with VHF channels (initially) 1 to 13, and UHF channels (initially) numbered 14 to 83. Compared with an equivalent VHF television transmitter, to cover the same geographic area with a UHF transmitter requires a higher effective radiated power, implying a more powerful transmitter or a more complex antenna. However, the additional channels allow more broadcasters in a given region without causing objectionable mutual interference.

The Pan-American television frequencies are different for terrestrial and cable television systems. Terrestrial television channels are divided into two bands: the VHF band which comprises channels 2 through 13 and occupies frequencies between 54 and 216 MHz, and the UHF band, which comprises channels 14 through 36 and occupies frequencies between 470 and 700 MHz. These bands are different enough in frequency that they often require separate antennas to receive, and separate tuning controls on the television set. The VHF band is further divided into two frequency ranges: VHF low band between 54 and 88 MHz, containing channels 2 through 6, and VHF high band between 174 and 216 MHz, containing channels 7 through 13. The wide spacing between these frequency bands is responsible for the complicated design of rooftop TV antennas. The UHF band has higher noise and greater attenuation, so higher gain antennas are often required for UHF.

References

↑ "Threat to Television Is Feared in Frequency Modulation Order", New York Times, May 21, 1940, p. 23. "Gives Du Mont Right to Television Here", New York Times, July 21, 1940, p. 28.
↑ "History of Zenith Electronics Corporation – FundingUniverse".
↑ "Zenith Enters FM and TV Broadcasting", The Zenith Story (1954).
↑ "Timeline".
↑ "CompassRose.org: WBKB Chicago". Archived from the original on 2015-06-08. Retrieved 2008-11-15.
↑ "Television stations authorized by the FCC, January 1, 1941". RCA Radio Travel-Log. 1941. Archived from the original on August 18, 2012. Retrieved August 12, 2012.
↑ "Channel1".
↑ "Technical Notes". HackersCatalog.com. Extreme Media. 2012. Archived from the original on 2014-07-14. Retrieved 2016-08-12.
↑ "NTIA Federal Long-Range Spectrum Plan - 30 to 1300 MHZ". Archived from the original on 2009-10-18. Retrieved 2009-11-08.

External links

David Ferre; Radio-Electronics magazine; March 1982; pp. 43-46, 89; “What Ever Happened to Channel 1?”; archived on earlytelevision.org; retrieved September 22, 2023
What ever happened to Channel 1? - J. W. Reiser, based on a Radio-Electronics article of the same name by David A. Ferre
Why is there no Channel One on television? - Cecil Adams
What became of Channel 1? - Jeff Miller
What Happened to Channel 1? - Snopes.com

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[1] "Threat to Television Is Feared in Frequency Modulation Order", New York Times, May 21, 1940, p. 23. "Gives Du Mont Right to Television Here", New York Times, July 21, 1940, p. 28.

[2] "History of Zenith Electronics Corporation – FundingUniverse".

[3] "Zenith Enters FM and TV Broadcasting", The Zenith Story (1954).

[4] "Timeline".

[5] "CompassRose.org: WBKB Chicago". Archived from the original on 2015-06-08. Retrieved 2008-11-15.

[6] "Television stations authorized by the FCC, January 1, 1941". RCA Radio Travel-Log. 1941. Archived from the original on August 18, 2012. Retrieved August 12, 2012.

[7] "Channel1".

[8] "Technical Notes". HackersCatalog.com. Extreme Media. 2012. Archived from the original on 2014-07-14. Retrieved 2016-08-12.

[9] "NTIA Federal Long-Range Spectrum Plan - 30 to 1300 MHZ". Archived from the original on 2009-10-18. Retrieved 2009-11-08.

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