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{{Article Infobox2
{{Article Infobox2
|Category=Fundamentals
|Category=Fundamentals
|Title={{PAGENAME}}
|Editors=GMV
|Authors=GMV
|Level=Basic
|Level=Basic
|YearOfPublication=2011
|YearOfPublication=2011
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SBAS systems are spreading out all over the world. More and more, it is believed that upon dual-frequency SBAS service provision, a seamless navigation will be possible from and to any two locations in the world.
SBAS systems are spreading out all over the world. More and more, it is believed that upon dual-frequency SBAS service provision, a seamless navigation will be possible from and to any two locations in the world.


==SBAS in the World==
==SBAS in the World==
From all the SBAS systems in the world, three are already operational ([[WAAS General Introduction|WAAS]], [[MSAS General Introduction|MSAS]], [[EGNOS General Introduction|EGNOS]]), three are under implementation ([[Work in Progress:GAGAN|GAGAN]], [[Work in Progress:SDCM|SDCM]], [[SNAS]]) while others are under feasibility studies, for instance SACCSA.
[[File:SBAS Service Areas 2021.PNG|300px|SBAS Indicative Service Areas. Source: GSA User Technology Report 2020 <ref>[https://www.euspa.europa.eu/sites/default/files/uploads/technology_report_2020.pdf GSA User Technology Report 2020]</ref> |thumb]]
From all the SBAS systems in the world, some of them are already operational ([[WAAS General Introduction|WAAS]], [[MSAS General Introduction|MSAS/QZSS]],[[GAGAN|GAGAN System]], [[EGNOS General Introduction|EGNOS]]), other are under implementation ([[SDCM|SDCM]], China’s Beidou SBAS BDSBAS, previously known as [[SNAS]]) or [[SouthPAN|SouthPAN]] (Southern Positioning Augmentation Network) in Australia<ref name"Australian_SBAS">[https://www.crcsi.com.au/sbas/ Australian SBAS]</ref> and New Zealand, while others are under feasibility studies, as is the case of [[Other SBAS|SACCSA]], A-SBAS (ASECNA) <ref name="ASECNAC">[https://egnos-user-support.essp-sas.eu/new_egnos_ops/sites/default/files/EWS19%20ASECNA%20-%20SBAS-ASECNA%20programme%20status.pdf ASECNA status]</ref> or KASS<ref name="KAAS">[https://egnos-user-support.essp-sas.eu/new_egnos_ops/sites/default/files/EWS19%20KARI%20-%20KASS%20programme%20status.pdf KAAS status (2019)]</ref> in South Korea planned for 2022 .


<gallery widths="200px">
According to the Interoperability Working Group (IWG) of SBAS System several evolutions are expected in the coming years:<ref>[http://www.faa.gov/about/office_org/headquarters_offices/ato/service_units/techops/navservices/gnss/library/briefings/media/SBAS_Global_Status_June%202014.pdf Global SBAS Status], Satellite Based Augmentation System (SBAS), Interoperability Working Group(IWG), June 2014</ref>
Image:SBAS_in_the_world.png|Some SBAS systems either operational, under development or under study
* GNSS Dual Frequency Operations;
</gallery>
* GNSS Multiple-Constellation Operations (Galileo, BeiDou);
* EGNOS and MSAS reference network expansion;
* SDCM and other SBAS systems under development to become operational.
 
When these evolutions are completed it is thought that the global SBAS coverage will suffer an increase from the 7.54% at 99% (only WAAS, EGNOS and MSAS) to 92.65%, considering the use of multiple-constellation (GPS and Galileo).
[[File:Prediction_On_SBAS_Availability.png|450px|Prediction of World Wide SBAS coverage|center|thumb]]


==[[WAAS]]==
==WAAS==
[[File:waas_logo.gif|right|100px|thumb]]
[[File:waas_logo.gif|right|100px|thumb]]


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On July 10, 2003, the WAAS signal was activated for safety-of-life aviation, covering 95% of the United States, and portions of Alaska.<ref name="WAAS WIKI"/> At present, WAAS supports en-route, terminal and approach operations down to a full LPV-200 (CAT-I like Approach Capability) for the CONUS, Mexico and Canada.
On July 10, 2003, the WAAS signal was activated for safety-of-life aviation, covering 95% of the United States, and portions of Alaska.<ref name="WAAS WIKI"/> At present, WAAS supports en-route, terminal and approach operations down to a full LPV-200 (CAT-I like Approach Capability) for the CONUS, Mexico and Canada.
The WAAS programme is continuously in evolution; three development phases have been already covered, and there are on-going plans to improve the capability of the system in parallel with the evolution of the SBAS standards towards a dual-frequency augmentation service.<ref>[http://www.faa.gov/about/office_org/headquarters_offices/ato/service_units/techops/navservices/gnss/library/satnav/media/SatNav_March08.pdf SatNav News, Vol. 33, March 2008,] [http://www.faa.gov/ Federal Aviation Agency (FAA).]</ref>


<gallery widths="200px">
<gallery widths="200px">
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</gallery>
</gallery>


==MSAS==
==EGNOS==
The [[MSAS General Introduction|Multi-functional Satellite Augmentation System (MSAS)]] is the Japanese SBAS. NEC manufactured and delivered MSAS under contract with the Civil Aviation Bureau, Ministry of Land, Infrastructure, Transport and Tourism.
[[EGNOS General Introduction|EGNOS (European Geostationary Navigation Overlay Service)]] is the European SBAS system that complements the existing satellite navigation services provided by the US [[GPS General Introduction|Global Positioning System]] (GPS). EGNOS constitutes together with [[GALILEO General Introduction|Galileo]] the two major initiatives in Europe in terms of satellite navigation. Future evolutions such as EGNOS V3 are expected to augment both GPS and Galileo constellation data.
 
EGNOS currently supports the following [[EGNOS Services|services]]:<ref name= "GSA EGNOS Services">[https://www.gsa.europa.eu/egnos/services "EGNOS services in GSA website"]</ref>
*The [[EGNOS Open Service|Open Service]] (OS), freely available to the public over Europe. This service was officially started on 1 October 2009.
*The [[EGNOS Safety of Life Service|Safety of Life Service]] (SoL), that provides the most stringent level of signal-in-space performance to all communities of Safety of Life users over Europe. This service was officially started on 2 March 2011.
*The [[EGNOS Data Access System (EDAS) | EGNOS Data Access System (EDAS)]] represents the provision of additional data for professional users not provided by the EGNOS signal broadcast by geostationary satellites but by other distribution channels.


MSAS is operational since 2007 supporting en-route, terminal and non-precision approach operations (RNP 0.1). Recently has completed successful LPV flight trials.
==MSAS/QZSS==
The [[MSAS General Introduction|Multi-functional Satellite Augmentation System (MSAS)]] is the Japanese Satellite Based Augmentation System (SBAS) System<ref name="MSAS_STATUS_2007">[http://www.unoosa.org/ MSAS Current Status, Japan Civil Aviation Bureau,] [http://www.oosa.unvienna.org/oosa/SAP/gnss/icg/icg02/presentations.html Second Meeting of the International Committee on Global Navigation Satellite Systems (ICG) organized by the International Space Research Organization,  Bangalore, India , 5 - 7 September 2007]</ref>: a GPS Augmentation system with the goal of improving its accuracy, integrity, and availability.
First tests were accomplished successfully, and MSAS system for aviation use was declared operational in September 27, 2007,<ref name="MSAS_STATUS_2007_2">QZSS / MSAS Status, CGSIC –47th Meeting ,Fort Worth, Texas September25, 2007, Satoshi KOGURE, [http://www.jaxa.jp/index_e.html Japan Aerospace Exploration Agency,] QZSS Project Team</ref><ref name="MSAS_GPSW">[http://www.gpsworld.com/surveyperspectives-late-april-2008-7289 Eric Gakstatter, Perspectives - Late April 2008, GPSworld, April 15, 2008]</ref><ref name=MSAS_WIKI_2>[http://en.wikipedia.org/wiki/Multi-functional_Satellite_Augmentation_System Multi-functional Satellite Augmentation System] in [http://en.wikipedia.org/ Wikipedia]</ref> providing a service of horizontal guidance for En-route through Non-Precision Approach.<ref name="MSAS_STATUS_2007"/><ref name="MSAS_STATUS_2007_2"/><ref name="MSAS_STATUS_2008">[http://www.unoosa.org/ Overview of MSAS, Presentation for ICG-3, 2008]</ref>
The SBAS signal used to be transmitted from MTSAT (Multi-functional Transport Satellites) operated by the Ministry of Land, Infrastructure, Transport and Tourism (MLIT). The SBAS signal that is made by MLIT is now transmitted from the QZS-3 GEO satellite using the QZSS SBAS transmission service since April 2020.<ref name="QZSS_SBAS">[https://qzss.go.jp/en/overview/services/sv12_sbas.html SBAS Transmission Service], QZSS Official Website</ref>


<gallery widths="200px">
<gallery widths="200px">
Image:msas_overview.png|MSAS architecture
Image:MSASV2.jpg|Actual MSAS V2 architecture <ref name="ICAO">[https://www.icao.int/Meetings/anconf13/Documents/WP/wp_249_en.pdf MSAS STATUS AND FUTURE PLAN] ICAO, THIRTEENTH AIR NAVIGATION CONFERENCE, Montréal, Canada, 9 to 19 October 2018 </ref>
</gallery>
</gallery>
QZSS (Quasi-Zenith Satellite System) is the Japanese satellite navigation program with a regional service coverage based on orbits for quasi-zenith satellites to broadcast radio signals from high elevation angle into urban canyons. MSAS evolutions will take advantage of the Japanese QZSS and to include DFMC capabilities in the future<ref name"MSAS_future">[https://www.icao.int/APAC/APAC-RSO/GBASSBAS%20Implementation%20Workshop/1-6_MSAS%20System%20Development_Rev2%20(S%20Saito).pdf MSAS status and evolutions]</ref>.


==GAGAN==
==GAGAN==
The [[GAGAN|GPS Aided Geo Augmented Navigation or GPS and Geo Augmented Navigation system (GAGAN)]] is the SBAS implementation by the Indian government. The Indian government states that it will use the experience of building the GAGAN system in the creation of an autonomous regional navigation system called the Indian Regional Navigational Satellite System (IRNSS).<ref name="GAGAN WIKI"/>
The [[GAGAN|GPS Aided Geo Augmented Navigation or GPS and Geo Augmented Navigation system (GAGAN)]] is the SBAS implementation by the Indian government. On 21 April 2015 it was certified for approach with vertical guidance (APV1) becoming the third SBAS in the world to achieve it and the first to do so operating in the equatorial region.<ref>[https://www.icao.int/APAC/APAC-RSO/GBASSBAS%20Implementation%20Workshop/3-7_GAGAN_Regional_Service_Availability%20(T%20Schemmp).pdf GAGAN Regional Service Availability]</ref><ref name="DGCA"/> It broadcasts SBAS navigation data using L1 signals and it is under development to also use the L5 signal for SBAS data broadcast.
 
The final, operational phase of GAGAN is likely to be completed in 2011.<ref name="GAGAN WIKI"/>


<gallery widths="200px">
<gallery widths="200px">
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The main differentiator of SDCM with respect to other SBAS systems is that it is conceived as an SBAS augmentation to GPS and GLONASS, whereas the rest of current SBAS initiatives provide corrections and integrity just to GPS satellites.
The main differentiator of SDCM with respect to other SBAS systems is that it is conceived as an SBAS augmentation to GPS and GLONASS, whereas the rest of current SBAS initiatives provide corrections and integrity just to GPS satellites.


<gallery widths="200px">
[[File:SDCM stations new.PNG|300px|SDCM planned station network|centre|thumb]]
Image:sdcm_overview.png|SDCM planned station network
 
</gallery>
==SNAS/BDSBAS==
The People's Republic of China is developing its own SBAS, called Satellite Navigation Augmentation System ([[SNAS|SNAS]]). There is little public information available on this development.
 
Now, the Chinese SBAS initiatives refer to BeiDou Satellite-based Augmentation System (BDSBAS).


==SNAS==
[[File:BDSBAS Architecture.png|300px|BDSBAS Architecture. Source: Springer Open <ref>[https://satellite-navigation.springeropen.com/articles/10.1186/s43020-020-00010-2 Springer Open]</ref> |centre|thumb]]
The People's Republic of China is developing its own SBAS, called Satellite Navigation Augmentation System ([[Work in Progress:SNAS|SNAS]]). The company [http://www.novatel.com/ Novatel] was awarded with a contract for the provision of 12 receivers for the phase 2 of the development in 2002.<ref>[http://findarticles.com/p/articles/mi_m0BPW/is_2_13/ai_n27573643/ NovAtel gains China order, GPS World, Feb. 2002]</ref> These stations would complement the 11 ones already installed around Beijing for the phase 1.
There is little public information available on this development.


==SACCSA==
==SACCSA==
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The program began in 2003 being at present in its Phase III which will determine the feasibility of the implementation of an own SBAS system in the CAR/SAM regions.
The program began in 2003 being at present in its Phase III which will determine the feasibility of the implementation of an own SBAS system in the CAR/SAM regions.


==Notes==
==A-SBAS==
<references group="footnotes"/>
A-SBAS (ASECNA) corresponds to the SBAS for Africa and Indian Ocean Development initiative. It is composed by international public organisations from 18 member states.
 
A-SBAS aims to provide early SBAS services from 2021/2022 for NPA, APV-1 and CAT-I operations. Full DFMC services are expected beyond 2028/2030 for CAT-I autoland operations and potentially further ones<ref name="ASECNAC">[https://egnos-user-support.essp-sas.eu/new_egnos_ops/sites/default/files/EWS19%20ASECNA%20-%20SBAS-ASECNA%20programme%20status.pdf ASECNA status]</ref>.
 
==KASS==
In October 2014, the Korea Aerospace Research Institute (KARI) was appointed as the leading research organization to develop and build Korea’s own Satellite Based Augmentation System (SBAS), known as KASS (Korea Augmentation Satellite System) in compliance with ICAO Annex 10.
 
It is expected to provide APV-1 safety-of-life service to airports located in South Korea in 2022<ref name="KAAS">[https://egnos-user-support.essp-sas.eu/new_egnos_ops/sites/default/files/EWS19%20KARI%20-%20KASS%20programme%20status.pdf KAAS status (2019)]</ref>.
 
==SouthPAN==
The Southern Positioning Augmentation System (SouthPAN) is the Australia and New Zealand’s operational SBAS and will be the first of its kind in the Southern Hemisphere when it reaches full operational capability in 2025.
As of December 2020 the procurement phase is underway. Initial signals will be provided gradually and it is expected to broadcast a test transmission service similar to the test-bed of 2017 in 2022 at the latest. This test service will be developed until it becomes a fully operational and certified system <ref name="southpanNews">[https://www.ga.gov.au/news-events/news/latest-news/southpan-to-position-australia-and-new-zealand-into-the-future SouthPAN to position Australia and New Zealand into the future]</ref><ref name="overviewReport">[https://frontiersi.com.au/wp-content/uploads/2018/08/SBAS-Test-bed-Overview-Report.pdf SBAS Test-bed Demonstration Project: Project Summary And Technical Results]</ref>.
 


==References==
==References==

Latest revision as of 07:42, 16 November 2021


FundamentalsFundamentals
Title SBAS Systems
Edited by GMV
Level Basic
Year of Publication 2011
Logo GMV.png

SBAS systems are spreading out all over the world. More and more, it is believed that upon dual-frequency SBAS service provision, a seamless navigation will be possible from and to any two locations in the world.

SBAS in the World

SBAS Indicative Service Areas. Source: GSA User Technology Report 2020 [1]

From all the SBAS systems in the world, some of them are already operational (WAAS, MSAS/QZSS,GAGAN System, EGNOS), other are under implementation (SDCM, China’s Beidou SBAS BDSBAS, previously known as SNAS) or SouthPAN (Southern Positioning Augmentation Network) in Australia[2] and New Zealand, while others are under feasibility studies, as is the case of SACCSA, A-SBAS (ASECNA) [3] or KASS[4] in South Korea planned for 2022 .

According to the Interoperability Working Group (IWG) of SBAS System several evolutions are expected in the coming years:[5]

  • GNSS Dual Frequency Operations;
  • GNSS Multiple-Constellation Operations (Galileo, BeiDou);
  • EGNOS and MSAS reference network expansion;
  • SDCM and other SBAS systems under development to become operational.

When these evolutions are completed it is thought that the global SBAS coverage will suffer an increase from the 7.54% at 99% (only WAAS, EGNOS and MSAS) to 92.65%, considering the use of multiple-constellation (GPS and Galileo).

Prediction of World Wide SBAS coverage

WAAS

Waas logo.gif

The Wide Area Augmentation System (WAAS) was jointly developed by the United States Department of Transportation (DOT) and the Federal Aviation Administration (FAA), beginning in 1994, to provide performance comparable to category I instrument landing system (ILS) for all aircraft possessing the appropriately certified equipment.[6]

On July 10, 2003, the WAAS signal was activated for safety-of-life aviation, covering 95% of the United States, and portions of Alaska.[6] At present, WAAS supports en-route, terminal and approach operations down to a full LPV-200 (CAT-I like Approach Capability) for the CONUS, Mexico and Canada.

The WAAS programme is continuously in evolution; three development phases have been already covered, and there are on-going plans to improve the capability of the system in parallel with the evolution of the SBAS standards towards a dual-frequency augmentation service.[7]

EGNOS

EGNOS (European Geostationary Navigation Overlay Service) is the European SBAS system that complements the existing satellite navigation services provided by the US Global Positioning System (GPS). EGNOS constitutes together with Galileo the two major initiatives in Europe in terms of satellite navigation. Future evolutions such as EGNOS V3 are expected to augment both GPS and Galileo constellation data.

EGNOS currently supports the following services:[8]

  • The Open Service (OS), freely available to the public over Europe. This service was officially started on 1 October 2009.
  • The Safety of Life Service (SoL), that provides the most stringent level of signal-in-space performance to all communities of Safety of Life users over Europe. This service was officially started on 2 March 2011.
  • The EGNOS Data Access System (EDAS) represents the provision of additional data for professional users not provided by the EGNOS signal broadcast by geostationary satellites but by other distribution channels.

MSAS/QZSS

The Multi-functional Satellite Augmentation System (MSAS) is the Japanese Satellite Based Augmentation System (SBAS) System[9]: a GPS Augmentation system with the goal of improving its accuracy, integrity, and availability. First tests were accomplished successfully, and MSAS system for aviation use was declared operational in September 27, 2007,[10][11][12] providing a service of horizontal guidance for En-route through Non-Precision Approach.[9][10][13] The SBAS signal used to be transmitted from MTSAT (Multi-functional Transport Satellites) operated by the Ministry of Land, Infrastructure, Transport and Tourism (MLIT). The SBAS signal that is made by MLIT is now transmitted from the QZS-3 GEO satellite using the QZSS SBAS transmission service since April 2020.[14]

QZSS (Quasi-Zenith Satellite System) is the Japanese satellite navigation program with a regional service coverage based on orbits for quasi-zenith satellites to broadcast radio signals from high elevation angle into urban canyons. MSAS evolutions will take advantage of the Japanese QZSS and to include DFMC capabilities in the future[16].

GAGAN

The GPS Aided Geo Augmented Navigation or GPS and Geo Augmented Navigation system (GAGAN) is the SBAS implementation by the Indian government. On 21 April 2015 it was certified for approach with vertical guidance (APV1) becoming the third SBAS in the world to achieve it and the first to do so operating in the equatorial region.[17][18] It broadcasts SBAS navigation data using L1 signals and it is under development to also use the L5 signal for SBAS data broadcast.

SDCM

The System for Differential Corrections and Monitoring (SDCM) is the SBAS currently being developed in the Russian Federation. SDCM is expected to be certified in the coming years, being this just the first step in the SDCM strategy which pursues also other broadcast means –potentially a polar MEO– with the aim of providing also a service to the North part of Russia.

The main differentiator of SDCM with respect to other SBAS systems is that it is conceived as an SBAS augmentation to GPS and GLONASS, whereas the rest of current SBAS initiatives provide corrections and integrity just to GPS satellites.

SDCM planned station network

SNAS/BDSBAS

The People's Republic of China is developing its own SBAS, called Satellite Navigation Augmentation System (SNAS). There is little public information available on this development.

Now, the Chinese SBAS initiatives refer to BeiDou Satellite-based Augmentation System (BDSBAS).

BDSBAS Architecture. Source: Springer Open [20]

SACCSA

The SBAS initiative in South/Central America and the Caribbean is called SACCSA (Soluciόn de Aumentaciόn para Caribe, Centro y Sudamérica). SACCSA is an ICAO project founded by the Participants/Member States of the SACCSA Project: Argentina, Bolivia, Colombia, Costa Rica, Guatemala, Panama, Spain, Venezuela and COCESNA (Corporación Centroamerica de Servicios de Navegación Aérea). The objective is to study the improvement of the Air Navigation Environment in the Caribbean and South America (CAR/SAM) Regions with a SBAS solution. The program began in 2003 being at present in its Phase III which will determine the feasibility of the implementation of an own SBAS system in the CAR/SAM regions.

A-SBAS

A-SBAS (ASECNA) corresponds to the SBAS for Africa and Indian Ocean Development initiative. It is composed by international public organisations from 18 member states.

A-SBAS aims to provide early SBAS services from 2021/2022 for NPA, APV-1 and CAT-I operations. Full DFMC services are expected beyond 2028/2030 for CAT-I autoland operations and potentially further ones[3].

KASS

In October 2014, the Korea Aerospace Research Institute (KARI) was appointed as the leading research organization to develop and build Korea’s own Satellite Based Augmentation System (SBAS), known as KASS (Korea Augmentation Satellite System) in compliance with ICAO Annex 10.

It is expected to provide APV-1 safety-of-life service to airports located in South Korea in 2022[4].

SouthPAN

The Southern Positioning Augmentation System (SouthPAN) is the Australia and New Zealand’s operational SBAS and will be the first of its kind in the Southern Hemisphere when it reaches full operational capability in 2025. As of December 2020 the procurement phase is underway. Initial signals will be provided gradually and it is expected to broadcast a test transmission service similar to the test-bed of 2017 in 2022 at the latest. This test service will be developed until it becomes a fully operational and certified system [21][22].


References