Envisat

Envisat
Spacecraft properties
Model of Envisat

Mission type	Earth observation
Operator	ESA
COSPAR ID	2002-009A
SATCAT №	27386
Website	envisat.esa.int
Mission duration	5 years planned 10 years achieved

Manufacturer	Astrium
Launch mass	8,211 kg (18,102 lb)
Dimensions	2.5 m X 2.5 m X 10 m
Power	6.5 kW

Start of mission
Launch date	1 March 2002, 01:07:59 (2002-03-01UTC01:07:59Z) UTC
Rocket	Ariane 5G V145
Launch site	Kourou ELA-3
Contractor	Arianespace

End of mission
Last contact	8 April 2012 (2012-04-09)

Orbital parameters
Reference system	Geocentric
Regime	Polar low Earth
Semi-major axis	7,144.9 km (4,439.6 mi)
Eccentricity	0.00042
Perigee	772 km (480 mi)
Apogee	774 km (481 mi)
Inclination	98.40 degrees
Period	100.16 minutes
Repeat interval	35 days
Epoch	15 December 2013, 03:07:00 UTC^[1]
Instruments
ASAR RA-2 MWR MIPAS MERIS AATSR DORIS GOMOS SCIAMACHY

Envisat ("Environmental Satellite") is a large inactive Earth-observing satellite which is still in orbit. Operated by the European Space Agency (ESA), it was the world's largest civilian Earth observation satellite.^[2]

It was launched on 1 March 2002 aboard an Ariane 5 from the Guyana Space Centre in Kourou, French Guiana, into a Sun synchronous polar orbit at an altitude of 790 km (490 mi) (± 10 km (6.2 mi)). It orbits the Earth in about 101 minutes, with a repeat cycle of 35 days. After losing contact with the satellite on 8 April 2012, ESA formally announced the end of Envisat's mission on 9 May 2012.^[3]

Envisat cost €2.3 billion (including €300 million for 5 years of operations) to develop and launch.^[4] The mission is due to be replaced by the Sentinel series of satellites. The first of these, Sentinel 1, has taken over the radar duties of Envisat since its launch in 2014.

Mission

Envisat was launched as an Earth observation satellite. Its objective was to service the continuity of European Remote-Sensing Satellite missions, providing additional observational parameters to improve environmental studies.

In working towards the global and regional objectives of the mission, numerous scientific disciplines currently use the data acquired from the different sensors on the satellite, to study such things as atmospheric chemistry, ozone depletion, biological oceanography, ocean temperature and colour, wind waves, hydrology (humidity, floods), agriculture and arboriculture, natural hazards, digital elevation modelling (using interferometry), monitoring of maritime traffic, atmospheric dispersion modelling (pollution), cartography and study of snow and ice.

Specifications

Dimensions

26 m (85 ft) × 10 m (33 ft) × 5 m (16 ft)

Mass

8,211 kg (18,102 lb), including 319 kg (703 lb) of fuel and a 2,118 kg (4,669 lb) instrument payload.^[5]

Power

Solar array with a total load of 3560 W.

Instruments

Envisat carries an array of nine Earth-observation instruments that gathered information about the Earth (land, water, ice, and atmosphere) using a variety of measurement principles. A tenth instrument, DORIS, provided guidance and control. Several of the instruments were advanced versions of instruments that were flown on the earlier ERS 1 and ERS 2 missions and other satellites.

MERIS

Main article: MERIS

MERIS (MEdium Resolution Imaging Spectrometer) measures the reflectance of the Earth (surface and atmosphere) in the solar spectral range (390 to 1040 nm) and transmits 15 spectral bands back to the ground segment. MERIS was built at the Cannes Mandelieu Space Center.

AATSR

Main article: AATSR

AATSR (Advanced Along Track Scanning Radiometer) can measure the sea surface temperature in the visible and infrared spectra. Because of its wide angle lens it is possible to make very precise measurements of atmospheric effects on how emissions from the Earth's surface propagate.

AATSR is the successor of ATSR1 and ATSR2, payloads of ERS 1 and ERS 2. AATSR can measure Earth's surface temperature to a precision of 0.3 K (0.54 °F), for climate research. Among the secondary objectives of AATSR is the observation of environmental parameters such as water content, biomass, and vegetal health and growth.

SCIAMACHY

Main article: SCIAMACHY

SCIAMACHY (SCanning Imaging Absorption spectroMeter for Atmospheric CHartographY) compares light coming from the sun to light reflected by the Earth, which provides information on the atmosphere through which the Earth-reflected light has passed.

SCIAMACHY is an image spectrometer with the principal objective of mapping the concentration of trace gases and aerosols in the troposphere and stratosphere. Rays of sunlight that are reflected transmitted, backscattered and reflected by the atmosphere are captured at a high spectral resolution (0.2 to 0.5 nm) for wavelengths between 240 and 1,700 nm, and in certain spectra between 2,000 and 2,400 nm. Its high spectral resolution over a wide range of wavelengths can detect many trace gases even in tiny concentrations. The wavelengths captured also allow effective detection of aerosols and clouds. SCIAMACHY uses 3 different targeting modes: to the nadir (against the sun), to the limbus (through the atmospheric corona), and during solar or lunar eclipses.

RA-2

RA-2 (Radar Altimeter 2) is a dual-frequency Nadir pointing Radar operating in the K_u band and S bands, it is used to define ocean topography, map/monitor sea ice and measure land heights.

Mean sea level measurements from Envisat are continuously graphed at the Centre National d'Etudes Spatiales web site, on the Aviso page.

MWR

MWR (Microwave Radiometer) was designed for measuring water vapour in the atmosphere.

DORIS

Main article: DORIS (geodesy)

DORIS (Doppler Orbitography and Radiopositioning Integrated by Satellite) determines the satellite's orbit to within 10 cm (4 in).

GOMOS

Main article: GOMOS

GOMOS (Global Ozone Monitoring by Occultation of Stars) looks to stars as they descend through the Earth's atmosphere and change color, which also tells a lot about the presence of gases such as ozone (O
3), and allows for the first time a space-based measurement of the vertical distribution of these trace gases.

GOMOS uses the principle of occultation. Its sensors detect light from a star traversing the Earth's atmosphere and measures the depletion of that light by trace gases nitrogen dioxide (NO
2), nitrogen trioxide, (NO
3), OClO), ozone (O
3) and aerosols present between about 20 to 80 km (12 to 50 mi) altitude. It has a resolution of 3 km (1.9 mi).

MIPAS

MIPAS (Michelson Interferometer for Passive Atmospheric Sounding) is a Fourier transforming infrared spectrometer which provides pressure and temperature profiles, and profiles of trace gases nitrogen dioxide (NO
2), nitrous oxide (N
2O), methane (CH
4), nitric acid (HNO
3), ozone (O
3), and water (H
2O) in the stratosphere. The instrument functions with high spectral resolution in an extended spectral band, which allows coverage across the Earth in all seasons and at equal quality night and day. MIPAS has a vertical resolution of 3 to 5 km (2 to 3 mi) depending on altitude (the larger at the level of the upper stratosphere).

ASAR

ASAR (Advanced Synthetic Aperture Radar) operates in the C band in a wide variety of modes. It can detect changes in surface heights with sub-millimeter precision. It served as a data link for ERS 1 and ERS 2, providing numerous functions such as observations of different polarities of light or combining different polarities, angles of incidence and spatial resolutions.

Mode	Id	Polarisation	Incidence	Resolution	Swath
Alternating polarisation	AP	HH/VV, HH/HV, VV/VH	15 – 45°	30 – 150 m	58 – 110 km
Image	IM	HH, VV	15 – 45°	30 – 150 m	58 – 110 km
Wave	WV	HH, VV		400 m	5 × 5 km
Suivi global (ScanSAR)	GM	HH, VV		1 km	405 km
Wide Swath (ScanSAR)	WS	HH, VV		150 m	405 km

These different types of raw data can be given several levels of treatment (suffixed to the ID of the acquisition mode: IMP, APS, and so on):

RAW (raw data, or "Level 0"), which contains all the information necessary to create images.
S (complex data, "Single Look Complex"), images in complex numeric form, the real and imaginary parts of the output of the compression algorithm
P (precision image), amplified image with constant pixel width (12.5 m for IMP)
M (medium precision image), amplified radiometry image with a resolution greater than P
G (geocoded image), amplified image to which simple geographical transforms have been applied to show relief.

Data capture in WV mode is unusual in that they constitute a series of 5 km × 5 km spaced at 100 km.

Loss of contact

ESA announced on 12 April 2012 that they lost contact with Envisat since Sunday, 8 April 2012, after 10 years of service, exceeding initially planned life span by 5 years. The spacecraft was still in a stable orbit, but attempts to contact it were unsuccessful.^[6]^[7] Ground-based radar and the French Pleiades Earth probe were used to image the silent Envisat and look for damage.^[8] ESA formally announced the end of Envisat's mission on 9 May 2012.^[3]

Envisat was launched in 2002 and it operated five years beyond its planned mission lifetime, delivering over a petabyte of data.^[3] ESA was expecting to turn off the spacecraft in 2014. ^[9]

Space safety

Space debris populations seen from outside geosynchronous orbit (GEO). Note the two primary debris fields, the ring of objects in GEO, and the cloud of objects in low earth orbit (LEO).

Given Envisat's orbit and its area-to-mass ratio, it will take about 150 years for the satellite to be gradually pulled into the Earth’s atmosphere.^[10] Envisat is currently orbiting in an environment where 2 catalogued objects can be expected to pass within about 200 m (660 ft) of it every year, which would likely trigger the need for a maneuver to avoid a possible collision.^[11] A collision between a satellite the size of Envisat and an object as small as 10 kg could produce a very large cloud of debris, initiating a self-sustaining chain-reaction of collisions and fragmentation with production of new debris, a phenomenon known as the Kessler Syndrome.^[11]

Envisat is a candidate for a mission to remove it from orbit, called e.Deorbit. The spacecraft sent to bring down Envisat would itself need to have a mass of approximately 1.6 tonnes.^[12]

Further information: Space debris

References

↑ "ENVISAT Satellite details 2002-009A NORAD 27386". N2YO. 15 December 2013. Retrieved 15 December 2013.
↑ EarthNet Online
1 2 3 "ESA declares end of mission for Envisat". ESA. 9 May 2012.
↑ European Space Agency web-site
↑ Envisat – Overall configuration
↑ "Breaking News | Flagship Envisat satellite stops communicating". Spaceflight Now. Retrieved 2012-04-21.
↑ "ESA Portal – Envisat services interrupted". Esa.int. Retrieved 2012-04-21.
↑ Huge, Mysteriously Silent Satellite Spotted by Another Spacecraft Space.com article, 20 April 2012
↑ Contact lost with flagship Envisat spacecraft 12 April 2012.
↑ "Envisat To Pose Big Orbital Debris Threat for 150 Years, Experts Say." SpaceNews. Retrieved: 27 September 2015.
1 2 Gini, Andrea (25 April 2012). "Don Kessler on Envisat and the Kessler Syndrome". Space Safety Magazine. Retrieved 2012-05-09.
↑ "e.Deorbit Symposium". ESA. 6 May 2014. Retrieved 2 June 2015.

External links

Envisat-homepage at ESA
Envisat operations page at ESA
Miravi – Meris Image Rapid Visualization. MIRAVI shows the gallery of images generated on the Level0 (raw data) Meris Full Resolution (300m) products, few seconds after their availability.
SRRS – Satellite Rapid Response System. Like MIRAVI but including also ASAR, MERIS Full and Reduced Resolution and ALOS AVNIR2 images.
Earth Snapshot – Web Portal dedicated to Earth Observation. Includes commented satellite images, information on storms, hurricanes, fires and meteorological phenomena.
Next ESA SAR Toolbox for viewing, calibrating and analyzing Envisat ASAR Level 1 data and higher
Four years on, Envisat hailed for its contribution to Earth science Physorg.com (2006-02-28)
ESA Envisat DDS (Data Dissemination System)
gcs Global Communication & Services – Manufacturer of the Envisat DDS Commercial Receiver Kit for ENVIHAM Home Users
Dossier Envisat: 10 years of climate and environmental research at Astrium

Orbital meteorological and remote sensing systems

Concepts

Current projects

Earth Observing System (EOS)	GPM TRMM Landsat 7 QuikSCAT Terra ACRIMSAT NMP/EO-1 Jason-1 OSTM/Jason-2 Jason-3 Meteor 3M-1/Sage III GRACE Aqua SORCE Aura CloudSat CALIPSO NPOESS Megha-Tropiques SARAL IRS ESSP Aquarius Landsat 8 SMAP

A-train satellites	Aqua Aura CALIPSO CloudSat GCOM-W1 (Shizuku) OCO-2

Copernicus programme	Sentinel-1 Sentinel-2 Sentinel-3 Sentinel-4 Sentinel-5 Precursor Sentinel-5

Geostationary meteorological satellites	Elektro-L Fengyun-2 GOES INSAT Meteosat Himawari-8

Other satellites	CBERS COSMO-SkyMed DMSP DMC EROS Fengyun-3 FORMOSAT-2 GOSAT (Ibuki) Landsat MetOp Meteor POES RADARSAT-2 SMOS SPOT TerraSAR-X THEOS

Former projects

Completed	ADEOS (Midori) ADEOS II (Midori 2) COSMIC (FORMOSAT-3) Envisat ERS FORMOSAT-1 Geosat GMS (Himawari) ICESat IKONOS Nimbus PARASOL QuickBird RADARSAT-1 Seasat SeaWiFS TIROS TOPEX/Poseidon UARS Vanguard

Failed	OCO Glory

Cancelled	NMP/EO-3

European Space Agency

Spaceports	Guiana Space Centre Esrange

Launch vehicles	Ariane 5 Arianespace Soyuz Vega

Facilities	ESOC ESTEC ESRIN EAC ESAC ECSAT CDF ST-ECF

Communications	ESTRACK European Data Relay System

Programmes	Aurora Copernicus Sentinel Cosmic Vision EGNOS ELIPS ExoMars FLPP Galileo LPP Space Situational Awareness Programme

Predecessors	ELDO ESRO

Related topics	Arianespace ESA Television EUMETSAT European Space Camp GEWEX Planetary Science Archive

Projects and missions

Science

Solar physics	ISEE-2 (1977–1987) Ulysses (1990–2009) SOHO (1995–present) Cluster II (2000–present) Solar Orbiter (2017)

Planetary science	Giotto (1985–92) Huygens (1997–2005) SMART-1 (2003–06) Mars Express (2003–present) Rosetta/Philae (2004–2016) Venus Express (2005–2014) ExoMars Trace Gas Orbiter (2016–present) BepiColombo (2018) ExoMars rover (2020) Jupiter Icy Moons Explorer (2022)

Astronomy and cosmology	Cos-B (1975–82) IUE (1978–96) EXOSAT (1983–86) Hipparcos (1989–93) Hubble (1990–present) Eureca (1992–93) ISO (1995–98) XMM-Newton (1999–present) INTEGRAL (2002–present) COROT (2006–13) Planck (2009–13) Herschel (2009–13) Gaia (2013–present) CHEOPS (2017) James Webb (2018) Euclid (2020) PLATO (2024) ATHENA (2028) eLISA (2034)

Earth observation	Meteosat First Generation (1977–97) ERS-1 (1991–2000) ERS-2 (1995–2011) Meteosat Second Generation (2002–present) Envisat (2002–12) Double Star (2003–07) MetOp (2006–present) GOCE (2009–13) SMOS (2009–present) CryoSat-2 (2010–present) Swarm (2013–present) Sentinel-1 / 1A / 1B (2014–present) Sentinel-2 / 2A (2015–present) Sentinel-3 / 3A (2016–present) Sentinel-5 Precursor (2016) Meteosat Third Generation (Sentinel-4) (2017) ADM-Aeolus (2017) EarthCARE (2018) MetOp-SG-A (2021) SMILE (2021) MetOp-SG-B (2022) FLEX (2022)

ISS spaceflight

ISS contribution (1998–present)
Columbus (2008–present)
Jules Verne (2008)
Cupola (2010–present)
Johannes Kepler (2011)
Edoardo Amaldi (2012)
Albert Einstein (2013)
Georges Lemaître (2014)
European Robotic Arm (2017)

Telecommunications

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

Technology
demonstrators

ARD (1998)
PROBA (2001–present)
YES2 (2007)
PROBA2 (2009–present)
Proba-V (2013–present)
IXV (2015)
LISA Pathfinder (2015–present)
OPS-SAT (2017)
Proba-3 (2018)
Lunar Lander (2018)
AIDA (2020)

Cancelled and proposed

Failed

Future missions in italics

Category
Commons
Wikinews
WikiProject

← 2001 · Orbital launches in 2002 · 2003 →

USA-164 \| INSAT-3C \| Tsubasa · DASH · VEP-3 \| HESSI \| Iridium 90 · Iridium 91 · Iridium 94 · Iridium 95 · Iridium 96 \| EchoStar VII \| Intelsat 904 \| Kosmos 2387 \| Envisat \| STS-109 \| TDRS-9 \| GRACE \| Progress M1-8 \| Shenzhou 3 \| JCSAT-8 · Astra 3A \| Intelsat 903 \| Kosmos 2388 \| STS-110 (ITS S0) \| NSS-7 \| Soyuz TM-34 \| SPOT-5 · Idefix \| Aqua \| DirecTV-5 \| Feng Yun 1D · Hai Yang 1A \| Ofek-5 \| Kosmos 2389 \| Intelsat 905 \| STS-111 (Leonardo MPLM) \| Ekspress A1R \| Galaxy 3C \| Iridium 97 · Iridium 98 \| NOAA-17 \| Progress M-46 \| CONTOUR \| Stellat 5 · N-STAR c \| Kosmos 2390 · Kosmos 2391 \| Kosmos 2392 \| Hot Bird 6 \| EchoStar VIII \| Atlantic Bird 1 · MSG-1 \| Intelsat 906 \| USERS · Kodama \| METSAT \| Tsinghua 2 \| Hispasat 1D \| Progress M1-9 \| Nadezhda 7 \| STS-112 (ITS S1) \| Foton-M No.1 \| INTEGRAL \| Zi Yuan 2B \| Soyuz TMA-1 \| Eutelsat W5 \| STS-113 (ITS P1 · MEPSI 1A · MEPSI 1B) \| Astra 1K \| AlSAT-1 · Mozhayets 3 · Rubin-3 \| TDRS-10 \| Hot Bird 7 · Stentor · MFD-A · MFD-B \| ADEOS II · Kanta Kun · FedSat · µ-LabSat 1 (RITE 1 · RITE 2) \| NSS-6 \| TrailBlazer-2001 STA · Saudisat 1C · LatinSat A · LatinSat B · UniSat 2 · Rubin 2 \| Kosmos 2393 \| Kosmos 2394 · Kosmos 2395 · Kosmos 2396 \| Shenzhou 4 \| Nimiq 2

Payloads are separated by bullets ( · ), launches by pipes ( \| ). Manned flights are indicated in bold text. Uncatalogued launch failures are listed in italics. Payloads deployed from other spacecraft are denoted in brackets.

This article is issued from Wikipedia - version of the 10/11/2016. The text is available under the Creative Commons Attribution/Share Alike but additional terms may apply for the media files.