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The main functions of the [[GLONASS Space Segment| Space Segment]] are to transmit radio-navigation signals, and to store and retransmit the navigation message sent by the Control Segment. The [[GLONASS General Introduction|GLONASS]] space segment consists of 24 operational satellites, distributed over three orbital planes.<ref> [http://www.sdcm.ru/index_eng.html Russian system of differentional correction and monitoring]</ref> The longitude of ascending node differs by 120 deg from plane to plane and each plane comprises eight satellites, staggered by 45 deg in argument of latitude. The satellites operate in circular orbits at an altitude of 19100-km, an inclination of 64.8 deg and each satellite completes the orbit in approximately 11 hours 15 minutes.
The main functions of the [[GLONASS Space Segment| Space Segment]] are to transmit radio-navigation signals, and to store and retransmit the navigation message sent by the Control Segment. The [[GLONASS General Introduction|GLONASS]] space segment consists of 24 operational satellites, distributed over three orbital planes.<ref> [http://www.sdcm.ru/index_eng.html Russian system of differentional correction and monitoring]</ref> The longitude of ascending node differs by 120 deg from plane to plane and each plane comprises eight satellites, staggered by 45 deg in argument of latitude. The satellites operate in circular orbits at an altitude of 19100-km, an inclination of 64.8 deg and each satellite completes the orbit in approximately 11 hours 15 minutes.


GLONASS updated constellation status is available online <ref>http://www.glonass-ianc.rsa.ru/en/</ref>.
GLONASS updated constellation status is available online <ref>https://www.glonass-iac.ru/en/</ref>.


==GLONASS Ground Segment==
==GLONASS Ground Segment==
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The [[GLONASS User Segment| GLONASS User Segment]] consists of L-band radio receiver/processors and antennas which receive [[GLONASS General Introduction|GLONASS]] navigation signals, determine pseudoranges (and other observables), and solve the navigation equations in order to obtain their coordinates and provide a very accurate time.
The [[GLONASS User Segment| GLONASS User Segment]] consists of L-band radio receiver/processors and antennas which receive [[GLONASS General Introduction|GLONASS]] navigation signals, determine pseudoranges (and other observables), and solve the navigation equations in order to obtain their coordinates and provide a very accurate time.


Although the [[GLONASS General Introduction|GLONASS]] constellation is nearing global coverage, its commercialization, especially development of the user segment, has been lacking compared to the U.S. [[GPS General Introduction|GPS]] system.<ref name="GLONASS_Wikipedia">[http://en.wikipedia.org/wiki/GLONASS GLONASS on Wikipedia]</ref> To improve the situation, the Russian government has been actively promoting GLONASS for civilian use. The government is planning to force all car manufactures in Russia to make cars with [[GLONASS General Introduction|GLONASS]] and they announced, in February 2011, that all passenger cars, large transport vehicles and vehicles transporting dangerous materials were required to use GLONASS-equipped navigators since July 2011.<ref>[http://vikno.eu/eng/avto/avto/ministry-of-transport-wants-to-fine-for-absence-of-navigators-glonass.html Ministry of transport want to fine for absence of GLONASS navigators]</ref>
Although the [[GLONASS General Introduction|GLONASS]] constellation is nearing global coverage, its commercialization, especially development of the user segment, has been lacking compared to the U.S. [[GPS General Introduction|GPS]] system.<ref name="GLONASS_Wikipedia">[http://en.wikipedia.org/wiki/GLONASS GLONASS on Wikipedia]</ref> To improve the situation, the Russian government has been actively promoting GLONASS for civilian use. The government is planning to force all car manufactures in Russia to make cars with [[GLONASS General Introduction|GLONASS]] and they announced, in February 2011, that all passenger cars, large transport vehicles and vehicles transporting dangerous materials were required to use GLONASS-equipped navigators since July 2011.<ref>[http://asmmag.com/2012-12-30-14-40-18/feature/1472-russia-accelerates-glonass-navigation-satellite-launches.html Russia Accelerates GLONASS Navigation Satellite Launches]</ref>


Besides, Russian efforts to improve [[GLONASS General Introduction|GLONASS]] accuracy are getting results, several electronic companies have announced the launching of new receivers supporting GLONASS.<ref>[http://www.glonass-center.ru/en/content/news/?ELEMENT_ID=116 Qualcomm Incorporated now has product support for the Russian GLONASS satellite system]</ref><ref>[http://www.broadcom.com/press/release.php?id=s548713 Broadcom announces two new system-on-a-chip solutions with support for GLONASS]</ref>
Besides, Russian efforts to improve [[GLONASS General Introduction|GLONASS]] accuracy are getting results, several electronic companies have announced the launching of new receivers supporting GLONASS.<ref>[http://www.glonass-center.ru/en/content/news/?ELEMENT_ID=116 Qualcomm Incorporated now has product support for the Russian GLONASS satellite system]</ref><ref>[http://www.broadcom.com/press/release.php?id=s548713 Broadcom announces two new system-on-a-chip solutions with support for GLONASS]</ref>

Latest revision as of 12:01, 22 June 2018


GLONASSGLONASS
Title GLONASS Architecture
Edited by GMV
Level Basic
Year of Publication 2011
Logo GMV.png

GLONASS is a space-based global navigation satellite system (GNSS) that provides reliable positioning, navigation, and timing services to users on a continuous worldwide basis freely available to all. GLONASS receivers compute their position in the GLONASS Reference System using satellite technology and based on triangulation principles.

Introduction

GLONASS Architecture

The GLONASS infrastructure consists of:

  • A constellation of 24 satellites distributed over three orbital planes;
  • the System Control Centre (SSC) located at Krasnoznamensk;
  • two Uplink stations;
  • the Central Clock situated in Schelkovo (near Moscow)
  • a network of four Monitoring and Measuring Stations (MS);
  • five Telemetry, Tracking and Control (TT&C) stations.

GLONASS infrastructure is organized in two segments, the Space Segment and the Ground Segment, to be complemented by the users receivers, which compose the User Segment.

GLONASS Space Segment

The main functions of the Space Segment are to transmit radio-navigation signals, and to store and retransmit the navigation message sent by the Control Segment. The GLONASS space segment consists of 24 operational satellites, distributed over three orbital planes.[1] The longitude of ascending node differs by 120 deg from plane to plane and each plane comprises eight satellites, staggered by 45 deg in argument of latitude. The satellites operate in circular orbits at an altitude of 19100-km, an inclination of 64.8 deg and each satellite completes the orbit in approximately 11 hours 15 minutes.

GLONASS updated constellation status is available online [2].

GLONASS Ground Segment

SLR Station in Shelkovo (near Moscow)

The GLONASS Ground Segment (also referred to as Control Segment or Operational Control System) is the responsible for the proper operation of the GLONASS system. It consists of a System Control Centre(SSC); a network of five Telemetry, Tracking and Command centers (TT&C); the Central Clock; three Upload Stations (UL); two Satellite Laser Ranging Stations (SLR); and a network of four Monitoring and Measuring Stations (MS), distributed over the territory of the Russian Federation. Six additional monitoring and measurement stations are to start operating in the near future.[3] This network is complemented by other additional measurement stations on the territory of the Russian Federation, equipped with laser ranging and other monitoring facilities.

Furthermore, the synchronization of all the processes in the GLONASS system is very important for its proper operability. The Central Synchronizer is high-precise hydrogen atomic clock which forms the GLONASS system time scale.

GLONASS User Segment

App transport.png

The GLONASS User Segment consists of L-band radio receiver/processors and antennas which receive GLONASS navigation signals, determine pseudoranges (and other observables), and solve the navigation equations in order to obtain their coordinates and provide a very accurate time.

Although the GLONASS constellation is nearing global coverage, its commercialization, especially development of the user segment, has been lacking compared to the U.S. GPS system.[4] To improve the situation, the Russian government has been actively promoting GLONASS for civilian use. The government is planning to force all car manufactures in Russia to make cars with GLONASS and they announced, in February 2011, that all passenger cars, large transport vehicles and vehicles transporting dangerous materials were required to use GLONASS-equipped navigators since July 2011.[5]

Besides, Russian efforts to improve GLONASS accuracy are getting results, several electronic companies have announced the launching of new receivers supporting GLONASS.[6][7]

Notes

References