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Ku band

February 05, 2023

The Ku band (/ˌkˈj/) is the portion of the electromagnetic spectrum in the microwave range of frequencies from 12 to 18 gigahertz (GHz). The symbol is short for "K-under" (originally German: Kurz-unten), because it is the lower part of the original NATO K band, which was split into three bands (Ku, K, and Ka) because of the presence of the atmospheric water vapor resonance peak at 22.24 GHz, (1.35 cm) which made the center unusable for long range transmission. In radar applications, it ranges from 12 to 18 GHz according to the formal definition of radar frequency band nomenclature in IEEE Standard 521–2002.[1][2]

IEEE Ku band
Frequency range
11–20 GHz
Wavelength range
2.5–1.67 cm
Related bands

Ku band is primarily used for satellite communications, most notably the downlink used by direct broadcast satellites to broadcast satellite television, and for specific applications such as NASA's Tracking Data Relay Satellite used for International Space Station (ISS) communications and SpaceX Starlink satellites.[3] Ku band satellites are also used for backhauls and particularly for satellite from remote locations back to a television network's studio for editing and broadcasting. The band is split by the International Telecommunication Union (ITU) into multiple segments that vary by geographical region. NBC was the first television network to uplink a majority of its affiliate feeds via Ku band in 1983.

Some frequencies in this radio band are employed in radar guns used by law enforcement to detect vehicles speeding, especially in Europe.[4]

Segments and regions

 
One use of the band is direct-broadcast satellite television. A satellite dish on a residence, which receives satellite television channels over a Ku band microwave beam from a broadcast communications satellite in a geostationary orbit 35,700 kilometres (22,000 miles) above the Earth.

America

Segments in most of North and South America are represented by ITU Region 2 from 11.7 to 12.2 GHz (Local Oscillator Frequency (LOF) 10.75 to 11.25 GHz), allocated to the FSS (fixed satellite service), uplink from 14.0 to 14.5 GHz. There are more than 22 FSS Ku band satellites orbiting over North America, each carrying 12 to 48 transponders, 20 to 120 watts per transponder, and requiring a 0.8-m to 1.5-m antenna for clear reception.

The 12.2 to 12.7 GHz (LOF 11.25 to 11.75 GHz) segment is allocated to the BSS (broadcasting satellite service). BSS (DBS direct broadcast satellites) normally carry 16 to 32 transponders of 27 MHz bandwidth running at 100 to 240 watts of power, allowing the use of receiver antennas as small as 18 inches (450 mm).

Europe and Africa

Segments in those regions are represented by ITU Region 1, and they are the 11.45 to 11.7 and 12.5 to 12.75 GHz bands are allocated to the FSS (fixed satellite service, uplink 14.0 to 14.5 GHz). In Europe Ku band is used from 10.7 to 12.75 GHz (LOF Low 9.750 GHz, LOF High 10.600 GHz) for direct broadcast satellite services such as those carried by the Astra satellites. The 11.7 to 12.5 GHz segment is allocated to the BSS (broadcasting satellite service).

Australia

Australia is part of ITU Region 3 and the Australian regulatory environment provides a class license that covers downlinking from 11.70 GHz to 12.75 GHz and uplinking from 14.0 GHz to 14.5 GHz.[5]

Indonesia

The ITU has categorized Indonesia as Region P, countries with very high rain precipitation. This statement has made many people unsure about using Ku-band (11 – 18 GHz) in Indonesia. Using frequencies higher than 10 GHz in a heavy rain area usually gives poor results. This problem can be solved by using an appropriate link budget when designing the wireless communication link. Higher power can overcome the loss to rain fade.

Measurements of rain attenuation in Indonesia have been done for satellite communication links in Padang, Cibinong, Surabaya and Bandung. The DAH Model for rain attenuation prediction is valid for Indonesia, as is the ITU model. The DAH model has become an ITU recommendation since 2001 (Recommendation No. ITU-R P.618-7). This model can create a 99.7% available link so that Ku-band can be applied in Indonesia.

Use of the Ku-band for satellite communications in tropical regions like Indonesia is becoming more frequent. Several satellites above Indonesia have Ku-band transponders, and even Ka band transponders. Newskies (NSS 6), launched in December 2002 and positioned at 95° East, contains only Ku-band transponders with a footprint on Indonesia (Sumatra, Java, Borneo, Celebes, Bali, Nusa Tenggara, Moluccas). NSS 6 is intended to be replaced by SES-12 at the same location, which launched in June 2018 and carries 54 Ku-band transponders. The iPSTAR satellite, launched in 2004 also uses Ku band footprints. Other satellites that provides Ku band covers Indonesia are Palapa D, MEASAT 3/3A, JCSAT-4B, AsiaSat 5, ST 2, Chinasat 11, Korea Telecom Koreasat 8/ABS 2 (2nd half 2013), and SES-8.

Others

Other ITU allocations have been made within the Ku band to the fixed service (microwave towers), radio astronomy service, space research service, mobile service, mobile satellite service, radiolocation service (radar), amateur radio service, and radionavigation. However, not all of these services are actually operating in this band and others are only minor users.

Advantages

Compared with C-band, Ku band is not similarly restricted in power to avoid interference with terrestrial microwave systems, and the power of its uplinks and downlinks can be increased. This higher power also translates into smaller receiving dishes and points out a generalization between a satellite's transmission and a dish's size. As the power increases, the size of an antenna's dish will decrease.[6][page needed] This is because the purpose of the dish element of the antenna is to collect the incident waves over an area and focus them all onto the antenna's actual receiving element, mounted in front of the dish (and pointed back towards its face); if the waves are more intense, fewer of them need to be collected to achieve the same intensity at the receiving element.

A major attraction of the band over lower frequency microwave bands is that the shorter wavelengths allow sufficient angular resolution to separate the signals of different communication satellites to be achieved with smaller terrestrial parabolic antennas. From the Rayleigh criterion, the diameter of a parabolic dish required to create a radiation pattern with a given angular beamwidth (gain) is proportional to the wavelength, and thus inversely proportional to the frequency. At 12 GHz a 1-meter dish is capable of focusing on one satellite while sufficiently rejecting the signal from another satellite only 2 degrees away. This is important because satellites in FSS (Fixed Satellite Service) service (11.7-12.2 GHz in the U.S.) are only 2 degrees apart. At 4 GHz (C-band) a 3-meter dish is required to achieve this narrow angular resolution. Note the inverse linear correlation between dish size and frequency. For Ku satellites in DBS (Direct Broadcast Satellite) service (12.2-12.7 GHz in the U.S.) dishes much smaller than 1-meter can be used because those satellites are spaced 9 degrees apart. As power levels on both C and Ku band satellites have increased over the years, dish beam-width has become much more critical than gain.

The Ku band also offers a user more flexibility. A smaller dish size and a Ku band system's freedom from terrestrial operations simplifies finding a suitable dish site. For the end users Ku band is generally cheaper and enables smaller antennas (both because of the higher frequency and a more focused beam).[7] Ku band is also less vulnerable to rain fade than the Ka band frequency spectrum.

Disadvantages

There are, however, some disadvantages of the Ku band system. Around 10 GHz is the absorption peak due to orientation relaxation of molecules in liquid water.[8] Above 10 GHz, Mie scattering takes over. The effect is a noticeable degradation, commonly known as rain fade, during heavy rain (100 mm/h).[9] This problem can be mitigated by transmitting a higher powered signal from the satellite to compensate. Therefore, the Ku band satellites typically require considerably more power to transmit than the C-band satellites.

Another weather-caused degradation called "snow fade" is not specific to the Ku band. It is due to snow or ice accumulation on a dish significantly altering its focal point.

The satellite operator's Earth station antenna requires more accurate position control when operating at Ku band due to its much narrower beam focus compared to C band for a dish of a given size. Position feedback accuracies are higher and the antenna may require a closed loop control system to maintain position under wind loading of the dish surface.

See also

References

  1. ^ IEEE Std 521 - 2002 URL only available to IEEE members
  2. ^ Note that in the band 11.2–12 GHz the working definitions of Ku band and X band overlap; satellite communications engineers would generally regard frequencies above 11.2 GHz as being part of the Ku band.
  3. ^ "SpaceX seeks FCC permission for operating all first-gen Starlink in lower orbit". SpaceNews.com. 2020-04-21. Retrieved 2020-04-23.
  4. ^ Radar Detectors Glossary
  5. ^ "Radiocommunications (Communication with Space Object) Class Licence 1998". Federal Register of Legislation. Australian Government. 2012-03-21. Retrieved 2016-07-06.
  6. ^ Mirabito, M; Morgenstern, B (2004). Satellites: Operations and Applications. The New Communication Technologies (5 ed.). Burlington: Focal Press. ISBN 978-0240805863.
  7. ^ Satellite Communications: Advantage and Disadvantages 2007-10-23 at the Wayback Machine
  8. ^ Martin Chaplin: Water and Microwaves 2019-07-29 at the Wayback Machine.
  9. ^ TECH-FAQ: Ku band.

External links

  • Frequency allocation information, mostly for U.S.
  • Spectrum allocation chart

February 05, 2023
band, this, article, multiple, issues, please, help, improve, discuss, these, issues, talk, page, learn, when, remove, these, template, messages, examples, perspective, this, article, section, might, have, extensive, bias, disproportional, coverage, towards, m. This article has multiple issues Please help improve it or discuss these issues on the talk page Learn how and when to remove these template messages The examples and perspective in this article or section might have an extensive bias or disproportional coverage towards one or more specific regions Please improve this article or discuss the issue on the talk page July 2014 Learn how and when to remove this template message This article needs additional citations for verification Please help improve this article by adding citations to reliable sources Unsourced material may be challenged and removed Find sources Ku band news newspapers books scholar JSTOR July 2014 Learn how and when to remove this template message Learn how and when to remove this template message The Ku band ˌ k eɪ ˈ j uː is the portion of the electromagnetic spectrum in the microwave range of frequencies from 12 to 18 gigahertz GHz The symbol is short for K under originally German Kurz unten because it is the lower part of the original NATO K band which was split into three bands Ku K and Ka because of the presence of the atmospheric water vapor resonance peak at 22 24 GHz 1 35 cm which made the center unusable for long range transmission In radar applications it ranges from 12 to 18 GHz according to the formal definition of radar frequency band nomenclature in IEEE Standard 521 2002 1 2 IEEE Ku bandFrequency range11 20 GHzWavelength range2 5 1 67 cmRelated bandsJ NATO SHF ITU Ku band is primarily used for satellite communications most notably the downlink used by direct broadcast satellites to broadcast satellite television and for specific applications such as NASA s Tracking Data Relay Satellite used for International Space Station ISS communications and SpaceX Starlink satellites 3 Ku band satellites are also used for backhauls and particularly for satellite from remote locations back to a television network s studio for editing and broadcasting The band is split by the International Telecommunication Union ITU into multiple segments that vary by geographical region NBC was the first television network to uplink a majority of its affiliate feeds via Ku band in 1983 Some frequencies in this radio band are employed in radar guns used by law enforcement to detect vehicles speeding especially in Europe 4 Contents 1 Segments and regions 1 1 America 1 2 Europe and Africa 1 3 Australia 1 4 Indonesia 1 5 Others 2 Advantages 3 Disadvantages 4 See also 5 References 6 External linksSegments and regions Edit One use of the band is direct broadcast satellite television A satellite dish on a residence which receives satellite television channels over a Ku band microwave beam from a broadcast communications satellite in a geostationary orbit 35 700 kilometres 22 000 miles above the Earth America Edit Segments in most of North and South America are represented by ITU Region 2 from 11 7 to 12 2 GHz Local Oscillator Frequency LOF 10 75 to 11 25 GHz allocated to the FSS fixed satellite service uplink from 14 0 to 14 5 GHz There are more than 22 FSS Ku band satellites orbiting over North America each carrying 12 to 48 transponders 20 to 120 watts per transponder and requiring a 0 8 m to 1 5 m antenna for clear reception The 12 2 to 12 7 GHz LOF 11 25 to 11 75 GHz segment is allocated to the BSS broadcasting satellite service BSS DBS direct broadcast satellites normally carry 16 to 32 transponders of 27 MHz bandwidth running at 100 to 240 watts of power allowing the use of receiver antennas as small as 18 inches 450 mm Europe and Africa Edit Segments in those regions are represented by ITU Region 1 and they are the 11 45 to 11 7 and 12 5 to 12 75 GHz bands are allocated to the FSS fixed satellite service uplink 14 0 to 14 5 GHz In Europe Ku band is used from 10 7 to 12 75 GHz LOF Low 9 750 GHz LOF High 10 600 GHz for direct broadcast satellite services such as those carried by the Astra satellites The 11 7 to 12 5 GHz segment is allocated to the BSS broadcasting satellite service Australia Edit Australia is part of ITU Region 3 and the Australian regulatory environment provides a class license that covers downlinking from 11 70 GHz to 12 75 GHz and uplinking from 14 0 GHz to 14 5 GHz 5 Indonesia Edit The ITU has categorized Indonesia as Region P countries with very high rain precipitation This statement has made many people unsure about using Ku band 11 18 GHz in Indonesia Using frequencies higher than 10 GHz in a heavy rain area usually gives poor results This problem can be solved by using an appropriate link budget when designing the wireless communication link Higher power can overcome the loss to rain fade Measurements of rain attenuation in Indonesia have been done for satellite communication links in Padang Cibinong Surabaya and Bandung The DAH Model for rain attenuation prediction is valid for Indonesia as is the ITU model The DAH model has become an ITU recommendation since 2001 Recommendation No ITU R P 618 7 This model can create a 99 7 available link so that Ku band can be applied in Indonesia Use of the Ku band for satellite communications in tropical regions like Indonesia is becoming more frequent Several satellites above Indonesia have Ku band transponders and even Ka band transponders Newskies NSS 6 launched in December 2002 and positioned at 95 East contains only Ku band transponders with a footprint on Indonesia Sumatra Java Borneo Celebes Bali Nusa Tenggara Moluccas NSS 6 is intended to be replaced by SES 12 at the same location which launched in June 2018 and carries 54 Ku band transponders The iPSTAR satellite launched in 2004 also uses Ku band footprints Other satellites that provides Ku band covers Indonesia are Palapa D MEASAT 3 3A JCSAT 4B AsiaSat 5 ST 2 Chinasat 11 Korea Telecom Koreasat 8 ABS 2 2nd half 2013 and SES 8 Others Edit Other ITU allocations have been made within the Ku band to the fixed service microwave towers radio astronomy service space research service mobile service mobile satellite service radiolocation service radar amateur radio service and radionavigation However not all of these services are actually operating in this band and others are only minor users Advantages EditCompared with C band Ku band is not similarly restricted in power to avoid interference with terrestrial microwave systems and the power of its uplinks and downlinks can be increased This higher power also translates into smaller receiving dishes and points out a generalization between a satellite s transmission and a dish s size As the power increases the size of an antenna s dish will decrease 6 page needed This is because the purpose of the dish element of the antenna is to collect the incident waves over an area and focus them all onto the antenna s actual receiving element mounted in front of the dish and pointed back towards its face if the waves are more intense fewer of them need to be collected to achieve the same intensity at the receiving element A major attraction of the band over lower frequency microwave bands is that the shorter wavelengths allow sufficient angular resolution to separate the signals of different communication satellites to be achieved with smaller terrestrial parabolic antennas From the Rayleigh criterion the diameter of a parabolic dish required to create a radiation pattern with a given angular beamwidth gain is proportional to the wavelength and thus inversely proportional to the frequency At 12 GHz a 1 meter dish is capable of focusing on one satellite while sufficiently rejecting the signal from another satellite only 2 degrees away This is important because satellites in FSS Fixed Satellite Service service 11 7 12 2 GHz in the U S are only 2 degrees apart At 4 GHz C band a 3 meter dish is required to achieve this narrow angular resolution Note the inverse linear correlation between dish size and frequency For Ku satellites in DBS Direct Broadcast Satellite service 12 2 12 7 GHz in the U S dishes much smaller than 1 meter can be used because those satellites are spaced 9 degrees apart As power levels on both C and Ku band satellites have increased over the years dish beam width has become much more critical than gain The Ku band also offers a user more flexibility A smaller dish size and a Ku band system s freedom from terrestrial operations simplifies finding a suitable dish site For the end users Ku band is generally cheaper and enables smaller antennas both because of the higher frequency and a more focused beam 7 Ku band is also less vulnerable to rain fade than the Ka band frequency spectrum Disadvantages EditThere are however some disadvantages of the Ku band system Around 10 GHz is the absorption peak due to orientation relaxation of molecules in liquid water 8 Above 10 GHz Mie scattering takes over The effect is a noticeable degradation commonly known as rain fade during heavy rain 100 mm h 9 This problem can be mitigated by transmitting a higher powered signal from the satellite to compensate Therefore the Ku band satellites typically require considerably more power to transmit than the C band satellites Another weather caused degradation called snow fade is not specific to the Ku band It is due to snow or ice accumulation on a dish significantly altering its focal point The satellite operator s Earth station antenna requires more accurate position control when operating at Ku band due to its much narrower beam focus compared to C band for a dish of a given size Position feedback accuracies are higher and the antenna may require a closed loop control system to maintain position under wind loading of the dish surface See also EditMultifunction Advanced Data LinkReferences Edit IEEE Std 521 2002 URL only available to IEEE members Note that in the band 11 2 12 GHz the working definitions of Ku band and X band overlap satellite communications engineers would generally regard frequencies above 11 2 GHz as being part of the Ku band SpaceX seeks FCC permission for operating all first gen Starlink in lower orbit SpaceNews com 2020 04 21 Retrieved 2020 04 23 Radar Detectors Glossary Radiocommunications Communication with Space Object Class Licence 1998 Federal Register of Legislation Australian Government 2012 03 21 Retrieved 2016 07 06 Mirabito M Morgenstern B 2004 Satellites Operations and Applications The New Communication Technologies 5 ed Burlington Focal Press ISBN 978 0240805863 Satellite Communications Advantage and Disadvantages Archived 2007 10 23 at the Wayback Machine Martin Chaplin Water and Microwaves Archived 2019 07 29 at the Wayback Machine TECH FAQ Ku band External links EditFrequency allocation information mostly for U S Spectrum allocation chart Retrieved from https en wikipedia org w index php title Ku band amp oldid 1119347453, wikipedia, wiki, book, books, library,

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