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* MWR is a [[Microwave radiometer|Microwave Radiometer]] used in measuring atmospheric water, as well as providing a correction for the atmospheric water for the altimeter.
* MWR is a [[Microwave radiometer|Microwave Radiometer]] used in measuring atmospheric water, as well as providing a correction for the atmospheric water for the altimeter.


To accurately determine its orbit, the satellite included the PRARE (Precision Range and Range-Rate Equipment) and a [[laser]] [[retroreflector]]. The PRARE became non-operational shortly after launch; later analysis concluded that the failure was due to a memory [[Radiation_hardening#Single-event_latchup|latchup]] caused by radiation.<ref name="eoportal-ers1"/> The [[retroreflector]] was used for calibrating the [[Radar]] [[Altimeter]] to within 10&nbsp;cm.
To accurately determine its orbit, the satellite included the PRARE (Precision Range and Range-Rate Equipment) and a [[laser]] [[retroreflector]]. The PRARE became non-operational shortly after launch; later analysis concluded that the failure was due to a memory [[Radiation_hardening#Single-event_latchup|latchup]] caused by radiation.<ref name="eoportal-ers1"/> The [[retroreflector]] was used for calibrating the [[Radar Altimeter| radar altimeter]] to within 10&nbsp;cm.


===Mission===
===Mission===

Revision as of 12:34, 21 February 2024

A full-size model of ERS-2.

European Remote Sensing satellite (ERS) was the European Space Agency's first Earth-observing satellite programme using a polar orbit. It consisted of two satellites, ERS-1 and ERS-2, with ERS-1 being launched in 1991.

ERS-1

ERS-1
Mission typeEarth observatrion
COSPAR ID1991-050A

ERS-1 launched 17 July 1991 from Guiana Space Centre aboard an Ariane 4 rocket.[1] The satellite was put into a Sun-synchronous polar orbit at an altitude of 782–785 km. ERS-1 failed on 10 March 2000 after nine years in orbit.[2]

Instruments

ERS-1 carried an array of Earth-observation instruments that gathered information about the Earth (land, water, ice, and atmosphere) using a variety of measurement principles. These included:

To accurately determine its orbit, the satellite included the PRARE (Precision Range and Range-Rate Equipment) and a laser retroreflector. The PRARE became non-operational shortly after launch; later analysis concluded that the failure was due to a memory latchup caused by radiation.[3] The retroreflector was used for calibrating the radar altimeter to within 10 cm.

Mission

ERS-1 had various mission phases using 3-day and 35-day repeat cycles. During the geodetic mission, ERS-1 was put in two long repeat cycles of 168 days, which is equivalent to a single 336-day cycle. The geodetic mission allowed for accurate mapping of the Earth's bathymetry and geoid over the seas using the Radar Altimeter.

On 10 March 2000, ERS-1's attitude control system failed due to a gyroscope malfunction and its mission was officially declared finished.[3]

ERS-2

ERS-2
Mission typeEarth observatrion
COSPAR ID1995-021A

Its successor, ERS-2, was launched on 21 April 1995, on an Ariane 4, from ESA's Guiana Space Centre near Kourou, French Guiana.[4] Largely identical to ERS-1, it added additional instruments and improved existing instruments including:

When ERS-2 was launched, ERS-1 shared the same orbital plane. This allowed a tandem mission, with ERS-2 passing the same point on the ground 1 day later than ERS-1. ERS-2 has a repeat cycle of 35 days.[5]

ERS-2 operated without gyroscopes from February 2001, resulting in some degradation of the data provided by the instruments. The tape drive aboard failed on 22 June 2003, leaving the instruments operating only within visibility of a ground station. After the tape drive failure additional ground stations were brought online to increase the data gathering abilities of the satellite. The Wind Scatterometer and GOME were the only instruments of their kind until the launches of MetOp-A and Envisat, respectively.

The successor to ERS-2 was the Envisat satellite, launched 1 March 2002. Envisat contained improved versions of many of the instruments onboard ERS-2. However, even after the launch of its successor, the operational life of ERS-2 was extended until 2011, when the decision was made to end the mission. Over a series of burns in July, August and September, ERS-2 was finally depleted of all fuel on 5 September 2011. At 13:16:38 the batteries were switched off and the satellite decommissioned. The spacecraft was left in an orbit where it will reenter the Earth's atmosphere and safely disintegrate within 25 years, in accordance with international standards.[6]

In the final stages of emptying the fuel tanks, it was estimated that they would be empty after a 40-minute burn on 2 September 2011. However, the spacecraft survived both this manoeuvre and a second 40-minute burn on 3 September. On 5 September a third burn was initiated and the fuel tanks were finally drained.

In February 2024, ESA reported that ERS-2 was expected to reenter in an uncontrolled fashion, some time between 16 February and 22 February 2024.[7]

See also

Notes

  • Zhao, D.; Kuenzer, C.; Fu, C.; Wagner, W. (2008). "Evaluation of the ERS Scatterometer derived Soil Water Index to monitor water availability and precipitation distribution at three different scales in China". Journal of Hydrometeorology. 9 (3). AMS: 549–562. Bibcode:2008JHyMe...9..549Z. doi:10.1175/2007JHM965.1.

References

  1. ^ Krebs, Gunter (2020). "ERS 1, 2". Gunter's Space Page. Retrieved 31 December 2022.
  2. ^ "ERS - Earth Online". earth.esa.int. Retrieved 8 May 2022.
  3. ^ a b "ERS-1 (European Remote-Sensing Satellite-1)". eoPortal. ESA. 2012. Retrieved 31 December 2022.
  4. ^ "ESA - ERS-2". Enabling and Support. ESA. Retrieved 31 December 2022.
  5. ^ "ERS-2 (European Remote-Sensing Satellite-2)". eoPortal. ESA. 2012. Retrieved 31 December 2022.
  6. ^ ESA. "Flight Dynamics". Retrieved 16 September 2016.
  7. ^ ESA. "ERS-2 Reentry". Retrieved 18 February 2024.