C band

This article is about the frequency spectra. For the genetic term, see constitutive heterochromatin.
C band
NATO C band
Frequency range
500 – 1000 MHz
Wavelength range
60 – 30 cm
Related bands
UHF (ITU / IEEE)
IEEE C band
Frequency range
4 – 8 GHz
Wavelength range
7.5 – 3.75 cm
Related bands

The C band is a name given to certain portions of the electromagnetic spectrum, including wavelengths of microwaves that are used for long-distance radio telecommunications. The IEEE C-band (4 to 8 GHz) and its slight variations contain frequency ranges that are used for many satellite communications transmissions, some Wi-Fi devices, some cordless telephones, and some weather radar systems. For satellite communications, the microwave frequencies of the C-band perform better under adverse weather conditions in comparison with the Ku band (11.2 GHz to 14.5 GHz), microwave frequencies used by other communication satellites.[1] Rain fade the collective name for the negative effects of adverse weather conditions on transmission – is mostly a consequence of precipitation and moisture in the air.

NATO C-band

The NATO C-band is the obsolete designation given to the radio frequencies from 500 to 1000 MHz (equivalent to wavelengths between 0.6 and 0.3 m) during the cold war period. Since 1992 frequency allocations, allotment and assignments are in line to NATO Joint Civil/Military Frequency Agreement (NJFA).[2] However, in order to identify military radio spectrum requirements, e.g. for crises management planning, training, Electronic warfare activities, or in military operations, this system is still in use.

NATO Radio spectrum designation
LATEST SYSTEM ALTERNATIVE SYSTEM
BAND FREQUENCY (MHz) BAND FREQUENCY (MHz)
A 0 – 250 I 100 – 150
B 250 – 500 G 150 – 225
C 500 – 1 000 P 225 – 390
D 1 000 – 2 000 L 390 – 1 550
E 2 000 – 3 000 S 1 550 – 3 900
F 3 000 – 4 000 C 3 900 – 6 200
G 4 000 – 6 000 X 6 200 – 10 900
H 6 000 – 8 000 K 10 900 – 36 000
I 8 000 – 10 000 Ku 10 900 – 20 000
J 10 000 – 20 000 Ka 20 000 – 36 000
K 20 000 – 40 000 Q 36 000 – 46 000
L 40 000 – 60 000 V 46 000 – 56 000
M 60 000 – 100 000 W 56 000 – 100 000

IEEE C-band

C-band antennas of this type became widespread in the United States in the 1950s for terrestrial microwave radio relay chains.

The IEEE C-band is a portion of the electromagnetic spectrum in the microwave range of frequencies ranging from 4.0 to 8.0 gigahertz (GHz);[3] however, this definition is the one followed by radar manufacturers and users, not necessarily by microwave radio telecommunications users.

The communications C-band was the first frequency band that was allocated for commercial telecommunications via satellites. The same frequencies were already in use for terrestrial microwave radio relay chains. Nearly all C-band communication satellites use the band of frequencies from 3.7 to 4.2 GHz for their downlinks, and the band of frequencies from 5.925 to 6.425 GHz for their uplinks. Note that by using the band from 3.7 to 4.0 GHz, this C-band overlaps somewhat into the IEEE S-band for radars.

The C-band communication satellites typically have 24 radio transponders spaced 20 MHz apart, but with the adjacent transponders on opposite polarizations.[4] Hence, the transponders on the same polarization are always 40 MHz apart. Of this 40 MHz, each transponder utilizes about 36 MHz. (The unused 4.0 MHz between the pairs of transponders acts as "guard bands" for the likely case of imperfections in the microwave electronics.)

The C-band is primarily used for open satellite communications, whether for full-time satellite television networks or raw satellite feeds, although subscription programming also exists. This use contrasts with direct-broadcast satellite, which is a completely closed system used to deliver subscription programming to small satellite dishes that are connected with proprietary receiving equipment.

The satellite communications portion of the C-band is highly associated with television receive-only satellite reception systems, commonly called "big dish" systems, since small receiving antennas are not optimal for C-band systems. Typical antenna sizes on C-band capable systems ranges from 7.5 to 12 feet (2.5 to 3.5 meters) on consumer satellite dishes, although larger ones also can be used.

The C-band frequencies of 5.4 GHz band [5.15 to 5.35 GHz, 5.47 to 5.725 GHz, or 5.725 to 5.875 GHz, depending on the region of the world] are used for IEEE 802.11a Wi-Fi and cordless telephone applications, leading to occasional interference with some weather radars that are also allocated to the C-band.

C-band variations

Slight variations in the assignments of C-band frequencies have been approved for use in various parts of the world, depending on their locations in the three ITU radio regions. Note that one region includes all of the Americas; a second includes all of Europe and Africa, plus all of Russia, and the third region includes all of Asia outside of Russia, plus Australia and New Zealand. This latter region is the most populous one, since it includes the People's Republic of China, India, Pakistan, Japan, and Southeast Asia.

C-Band Variations Around The World
Band Transmit Frequency
(GHz)
Receive Frequency
(GHz)
Standard C-Band 5.850–6.425 3.625–4.200
Super Extended C-Band 6.425–6.725 3.400–3.625
INSAT 6.725–7.025 4.500–4.800
Russian C-Band 5.975–6.475 3.650–4.150
LMI C-Band 5.7250–6.025 3.700–4.000

Amateur radio

The Radio Regulations of the International Telecommunication Union allow amateur radio operations in the frequency range 5.650 to 5.925 GHz, and amateur satellite operations are allowed in the ranges 5.830 to 5.850 GHz for down-links and 5.650 to 5.670 GHz for up-links. This is known as the 5-centimeter band by amateurs and the C-band by AMSAT.

Fiber optic communications

In infrared optical communications, C-band refers to the wavelength range 1530–1565 nm, which corresponds to the amplification range of erbium doped fiber amplifiers (EDFAs).[5]

See also

Notes

  1. What is C Band page from tech-faq (accessed Aug. 14, 2008)
  2. NATO Joint Civil/Military Frequency Agreement (NJFA)
  3. Peebles, Peyton Z., Jr, (1998), Radar Principles, John Wiley and Sons, Inc., p 20
  4. http://www.lyngsat.com/america.html
  5. Optical Fiber Communications article in rp-photonics' Encyclopedia of Laser Physics and Technology (accessed Nov. 11 2010)

External links

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