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Sentinel-6 Michael Freilich

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Earth observation satellite

Sentinel-6 Michael Freilich
Spacecraft properties
Illustration of the Sentinel-6 Michael Freilich spacecraft in orbit aboveEarth with its deployablesolar panels extended
Names	Sentinel-6A Jason-CS A

Mission type	Oceanography mission
Operator	EUMETSAT /NASA
COSPAR ID	2020-086A
SATCAT no.	46984
Website	www.eumetsat.int/sentinel-6
Mission duration	5.5 years (planned) 4 years, 11 months and 1 day(in progress)


Bus	Sentinel-6
Manufacturer	Airbus Defence and Space
Launch mass	1,192 kg (2,628 lb)
Dimensions	5.13 x 4.17 x 2.34 metres
Power	891watts


Start of mission
Launch date	21 November 2020, 17:17:08UTC
Rocket	Falcon 9 Block 5
Launch site	Vandenberg,SLC-4E
Contractor	SpaceX
Entered service	21 June 2021^[1]


Orbital parameters
Reference system	Geocentric orbit
Regime	Low Earth orbit
Altitude	1,336 km (830 mi)
Inclination	66.0°
Repeat interval	10 days

Instruments
Radar altimeter Advanced Microwave Radiometer (AMR-C) GNSS Precise Orbit Determination (POD) Receiver DORIS Receiver Laser Reflector Array (LRA) Radio-occultation instrument
Sentinel ← Sentinel-3B Sentinel-2C → Jason satellite series/Sentinel 6 ← Jason-3 Sentinel-6B →

TheSentinel-6 Michael Freilich (S6MF) orSentinel-6A is aradar altimeter satellite developed in partnership between several European and American organizations. It is part of theJason satellite series and is named afterMichael Freilich. S6MF includessynthetic-aperture radar altimetry techniques to improveocean topography measurements, in addition to rivers and lakes.^[2] The spacecraft entered service in mid 2021 and is expected to operate for 5.5 years.

Spacecraft

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Inside SpaceX's Payload Processing Facility at Vandenberg Air Force Base in California, the U.S.-European Sentinel-6 Michael Freilich ocean-monitoring satellite is being encapsulated in the SpaceX Falcon 9 payload fairing on 3 November 2020. (NASA)

The Sentinel-6 program includes two identical satellites, to be launched five years apart, Sentinel-6 Michael Freilich, which launched on 21 November 2020,^[3] and Sentinel-6B, which will launch in 2025.^[4] These satellites will measure sea level change from space, which have been measured without interruption since 1992.^[5]^[6]

Formerly calledSentinel-6A andJason-CS A (Jason Continuity of Service-A), it was renamed in honor of the former director ofNASA Earth Science Division,Michael Freilich, who was instrumental in advancing space-based ocean measurements. It follows the most recent U.S.-European sea level observation satellite,Jason-3, which launched in 2016, and is currently providing high-precision and timely observations of the topography of the global ocean.^[7]

Context

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Since the launch ofTOPEX/Poseidon on 10 August 1992, high-precision satellite altimeters have been essential to monitor how the ocean stores and redistributes heat, water, and carbon in the climate system. The two satellites, Sentinel-6 Michael Freilich and Sentinel-6B, will extend this legacy through to at least 2030, which will provide a nearly forty-year record ofsea level rise as well as changes in ocean currents.^[4]^[8]

Partnership

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The Sentinel-6 was developed byEuropean Space Agency (ESA) in the context of the EuropeanCopernicus Programme led by theEuropean Commission, theEuropean Organisation for the Exploitation of Meteorological Satellites (EUMETSAT),NASA, and theNational Oceanic and Atmospheric Administration (NOAA), with funding support from the European Commission and technical support from France's National Centre for Space Studies (CNES, Centre national d'études spatiales).^[9]

The Sentinel-6 mission is part of the Copernicus programme initiative, the main objective of the Sentinel-6 mission is to measuresea surface topography with high accuracy and reliability to support ocean forecasting systems,environmental monitoring and climate monitoring.^[10]

The mission definition is driven by the need for continuity in provision ofTOPEX/Poseidon mission andJason satellite series (Jason-1,OSTM/Jason-2, andJason-3) with improvements in instrument performance and coverage.^[11] ESA, NASA, and EUMETSAT will provide mission management and system engineering support. EUMETSAT and NASA will be responsible for long-term archives of altimetry data products. All partners will be involved with the selection of science investigators.^[11]

Responsibilities of partners

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Launch

ESA

has responsibility for the development of the first satellite and the ground prototype processors, and for procurement of the second satellite on behalf of EUMETSAT and the European Commission
has responsibility for conducting the Launch and Early Operations Phase (LEOP) of both satellites
supports flight operations performed by EUMETSAT

EUMETSAT

has responsibility for ground segment development and coordination at system level, including for operations preparation
has responsibility for conducting operations of the two satellites after LEOP performed by ESA
has responsibility for conducting operations of the European part of the ground segment, including processing of altimeter data and delivery of product services to European users

NASA

has responsibility for the development and delivery of the U.S. payload instruments, the microwave radiometer and the GNSS radio occultation receiver
provides launch services for both satellites
provides ground segment development support and will contribute to operations and data processing on the U.S. side, including processing of GNSS radio occultation data
with NOAA, shares responsibility for the distribution of products to research and operational users in the U.S.

NOAA

provides a U.S. ground station for tracking and command of the satellite and data downlinks
with NASA, shares responsibility for the distribution of products to research and operational users in the U.S.

CNES

has responsibility for processing higher-level products (L2P, L3)
has responsibility for providing precise orbit determination and support for Doris and altimeter operations^[12]

Instruments

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POSEIDON4, aradar altimeter, developed by ESA, based on theSentinel-3 SRAL instrument, but with a design adopted to allow an interleaved mode combining asynthetic-aperture radar High-Resolution (HR) mode and a low resolution (LR) mode based onpulse-limited altimetry
Advanced Microwave Radiometer (AMR-C) provided by NASA
Global Navigation Satellite System Precise Orbit Determination (GNSS POD)receiver, developed by ESA and derived from the GNSS Receiver on Sentinel-3
Doppler Orbitography and Radiopositioning Integrated by Satellite (DORIS Receiver), identical to the one used on Jason-3 and Sentinel-3
Laser Reflector Array (LRA), used forsatellite laser ranging, identical to the one used on Jason-3, provided by NASA
GNSS Radio Occultation (GNSS-RO) based on a Tri-G receiver, provided by NASA^[12]

References

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^"New sea-level monitoring satellite goes live". ESA. 21 June 2021. Retrieved23 June 2021.
^Donlon, Craig J.; Cullen, Robert; Giulicchi, Luisella; Vuilleumier, Pierrik; Francis, C. Richard; Kuschnerus, Mieke; Simpson, William; Bouridah, Abderrazak; Caleno, Mauro; Bertoni, Roberta; Rancaño, Jesus (1 June 2021)."The Copernicus Sentinel-6 mission: Enhanced continuity of satellite sea level measurements from space".Remote Sensing of Environment.258 112395.Bibcode:2021RSEnv.258k2395D.doi:10.1016/j.rse.2021.112395.ISSN 0034-4257.S2CID 233566650.
^Howell, Elizabeth (20 November 2020)."SpaceX will launch the Sentinel-6 ocean-mapping satellite Saturday". SPACE.com. Retrieved21 November 2020.
^^a ^b"Jason-CS (Sentinel 6) Summary".sealevel.jpl.nasa.gov. NASA. August 2020. Archived fromthe original on 8 April 2017. Retrieved2 November 2020. This article incorporates text from this source, which is in thepublic domain.
^"A Decade of Global Sea Level Measurements: Jason-2 Marks Tenth Year in Orbit".nesdis.noaa.gov. NOAA. 20 June 2018. Retrieved26 May 2021. This article incorporates text from this source, which is in thepublic domain.
^B., Mark (8 September 2020)."NASA Sentinel 6 Michael Freilich to Launch in November 2020". Science Times.
^"NASA TV to Air Sentinel-6 Michael Freilich Launch, Prelaunch Activities". NASA. 13 November 2020. Retrieved22 November 2020. This article incorporates text from this source, which is in thepublic domain.
^"Upcoming Satellite Mission will Improve Hurricane Forecasts and Climate Science, NOAA Expert Says". NOAA. 14 August 2020. Retrieved26 May 2021. This article incorporates text from this source, which is in thepublic domain.
^Greicius, Tony (19 November 2020)."Sentinel-6 Michael Freilich Satellite Prepared for Launch". NASA. Retrieved21 November 2020. This article incorporates text from this source, which is in thepublic domain.
^"Copernicus Sentinel-6: Testing Complete for New International Ocean Satellite". SciTechDaily. 15 June 2020. Retrieved26 May 2021.
^^a ^b"Sentinel-6 Overview". ESA. Retrieved29 October 2019.
^^a ^b"Sentinel-6". EUMETSAT. 19 May 2020. Retrieved26 May 2021.

Copernicus Programme

Sentinel
satellites

Classes	Sentinel-1 Sentinel-2 Sentinel-3 Sentinel-4 Sentinel-5 Sentinel-6 CO2M (Sentinel-7)
Launches	Sentinel-1A(Apr 2014) Sentinel-2A(Jun 2015) Sentinel-3A(Feb 2016) Sentinel-1B(Apr 2016) Sentinel-2B(Mar 2017) Sentinel-5P(Oct 2017) Sentinel-3B(Apr 2018) Sentinel-6A(Nov 2020) Sentinel-2C(Sep 2024) Sentinel-1C(Dec 2024) Sentinel-4A(Jul 2025) Sentinel-5A(Aug 2025)

Contributing
missions

SAR	ERS-2 Envisat COSMO-SkyMed Radarsat-2 TerraSAR-X TanDEM-X Paz
Optical	ERS-2 Envisat Deimos-2 Disaster Monitoring Constellation EnMAP HiROS Pléiades Prisma Proba-V RapidEye Ingenio SPOT VENµS
Altimetry	Envisat CryoSat Ocean Surface Topography Mission SARAL
Atmospheric	CALIPSO Envisat Merlin Meteosat Second Generation MetOp

European Space Agency

Space Centres	Guiana Esrange
Launch vehicles	Ariane 6 Vega C
Facilities	Space Operations Centre Space Research and Technology Centre ESA Centre for Earth Observation European Astronaut Centre Space Astronomy Centre Space Applications and Telecommunications Centre Concurrent Design Facility Space Telescope European Coordinating Facility
Communications	ESTRACK European Data Relay System
Programmes	Artemis ESM Aurora Copernicus Columbus CryoSat EGNOS Galileo ELIPS ExoMars FLPP FutureEO Space Safety Programme Science Programme Cosmic Vision PRIDE
Predecessors	European Launcher Development Organisation European Space Research Organisation
Related topics	Arianespace ESA Television EUMETSAT European Astronaut Corps European Space Camp GEWEX Planetary Science Archive

Projects and missions

Science

Astronomy and cosmology	Cos-B (1975–1982) IUE (1978–1996) EXOSAT (1983–1986) Hipparcos (1989–1993) Hubble Space Telescope (1990–present) Eureca (1992–1993) ISO (1995–1998) XMM-Newton (1999–present) INTEGRAL (2002–2025) CoRoT (2006–2013) Planck (2009–2013) Herschel (2009–2013) Gaia (2013–2025) CHEOPS (2019–present) James Webb Space Telescope (2021–present) Euclid (2023–present) PLATO (2026) ARIEL (2029) ARRAKIHS (2030s) Athena (2035) LISA (2035)
Earth observation	Meteosat First Generation (1977–1997) ERS-1 (1991–2000) ERS-2 (1995–2011) Meteosat Second Generation (2002–present) Envisat (2002–2012) Double Star (2003–2007) MetOp (2006–present) GOCE (2009–2013) SMOS (2009–present) CryoSat-2 (2010–present) Swarm (2013–present) Copernicus (2014–present) Sentinel-1 /1A /1B /1C (2014–present) Sentinel-2 /2A /2B /2C (2015–present) Sentinel-3 /3A /3B (2016–present) Sentinel-5 Precursor (2017–present) ADM-Aeolus (2018–2023) ɸ-Sat (1 (2020)2 (2024–present)) Meteosat Third Generation (2022–present) EarthCARE (2024–present) Biomass (2025–present) Sentinel-4 (2025–present) MetOp-SG-A (2025) MetOp-SG-B (2025) SMILE (2025) ALTIUS (2026) FLEX (2026) FORUM (2027) Wivern (2032)
Planetary science	Giotto (1985–1992) Huygens (1997–2005) SMART-1 (2003–2006) Mars Express (2003–present) Rosetta/Philae (2004–2016) Venus Express (2005–2014) ExoMars (2016–present) Trace Gas Orbiter (2016–present) Rosalind Franklin rover (2028) BepiColombo (2018–present) Jupiter Icy Moons Explorer (2023–present) Hera (2024–present) Comet Interceptor (2029) EnVision (2031)
Solar physics	ISEE-2 (1977–1987) Ulysses (1990–2009) SOHO (1995–present) Cluster II (2000–2024) Solar Orbiter (2020–present) Vigil (2031)

ISS contributions

Columbus (2008–present)
Automated Transfer Vehicle (2008–2015)
Cupola (2010)
European Robotic Arm (2021)

Telecommunications

GEOS 2 (1978)
Olympus-1 (1989–1993)
Artemis (2001–2017)
GIOVE-A (2005–present)
GIOVE-B (2008–present)
HYLAS-1 (2010–present)
Galileo IOV (2011–present)
Galileo FOC (2014–present)
EGNOS
European Data Relay System (2016–present)

Technology
demonstrators

ARD (1998)
PROBA-1 (2001–present)
YES2 (2007)
PROBA-2 (2009–present)
PROBA-V (2013–present)
IXV (2015)
LISA Pathfinder (2015–2017)
OPS-SAT (2019–2024)
PROBA-3 (2024–present)

Cancelled
and proposed

Failed

Future missions initalics

v t e ← 2019 Orbital launches in2020 2021 →
January	Starlink V1.0-L2 (60 satellites) TJS-5 Jilin-1 Kuanfu-01,ÑuSat 7,ÑuSat 8 Eutelsat Konnect,GSAT-30 Starlink V1.0-L3 (60 satellites) USA-294
February	OneWeb L2 (34 satellites) IGS-Optical 7 Solar Orbiter (TechEdSat-10) Cygnus NG-13 Starlink V1.0-L4 (60 satellites) Chollian-2B JCSAT-17 Meridian-M 9
March	SpaceX CRS-20 (Lynk 04) BeiDou-3 G2Q Kosmos 2545 /GLONASS-M 760 Starlink V1.0-L5 (60 satellites) OneWeb L3 (34 satellites) Yaogan 30-06 (3 satellites) USA-298 /AEHF-6
April	Soyuz MS-16 Noor Starlink V1.0-L6 (60 satellites) Progress MS-14
May	Chinese next-generation crewed spacecraft /Flexible Inflatable Cargo Return Module Xingyun-2 01, 02 X-37B OTV-6 /FalconSAT-8 HTV-9 EKS-4 LauncherOne†, Starshine 4† XJS-G,XJS-H Crew Dragon Demo-2
June	Starlink 7 (60 satellites) Starlink 8 (58 satellites)
July	Gaofen DUOMO Flock-4e × 5† Shiyan 6-02 Ofek-16 Apstar 6D Jilin-1 Gaofen-02E† USA-305,USA-306,USA-307,USA-308 Emirates Mars Mission ANASIS-II Tianwen-1 (Zhurong) Progress MS-15 Ziyuan III-03 Mars 2020 (Perseverance,Ingenuity) Ekspress-80,Ekspress-103
August	Gaofen 9-04 Starlink V1.0-L9 (57 satellites),BlackSky Global 7,BlackSky Global 8 BSAT-4b,Galaxy 30,MEV-2 Starlink V1.0-L10 (58 satellites),SkySat × 3 Gaofen 9-05 SAOCOM 1B Capella 2,PhotonFirst Light
September	ION-SCV 001 (Flock-4v × 12),ÑuSat 6,UPM-Sat 2,Flock-4v × 14,Lemur-2 × 8,NAPA-1,SpaceBEE × 12 Starlink V1.0-L11 (60 satellites) Chinese reusable experimental spacecraft Gaofen 11-02 Jilin-1 Gaofen-02C† Jilin-1 Gaofen-03B × 6,Jilin-1 Gaofen-03C × 3 HaiYang 2C Huanjing 2A,Huanjing 2B Gonets-M × 3,ICEYE X6,ICEYE X7,Kepler 4,Kepler 5,LacunaSat-3,Lemur-2 × 4
October	Cygnus NG-14 (Lemur-2 × 2,SPOC) Starlink V1.0-L12 (60 satellites) Gaofen-13 Soyuz MS-17 Starlink V1.0-L13 (60 satellites) Starlink V1.0-L14 (60 satellites) Kosmos 2547 /GLONASS-K 15L Yaogan 30-07 (3 satellites) Flock-4e' × 9
November	USA-309 /GPS IIIA-04 ÑuSat × 10 EOS-01 /RISAT-2BR2,KSM × 4,Lemur-2 × 4 Tiantong-1 02 USA-310 /NROL-101 SpaceX Crew-1 SEOSat-Ingenio†,TARANIS† Landmapper-BC 5,SpaceBEE × 18 Sentinel-6 Chang'e 5 Starlink V1.0 L15 (60 satellites)
December	Gonets-M × 3,Kosmos 2548 / ERA-1 Gaofen 14 SpaceX CRS-21 (Nanoracks Bishop Airlock) GECAM A,GECAM B USA-311 /Orion 10 SXM-7 CMS-01 /GSAR-12R OneWeb L4 (36 satellites) USA-312,USA-313 Yaogan 33 CSO-2
Launches are separated by dots ( • ), payloads by commas ( , ), multiple names for the same satellite by slashes ( / ). Crewed flights are underlined. Launch failures are marked with the † sign. Payloads deployed from other spacecraft are (enclosed in parentheses).

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