Jason-1: Difference between revisions

Jason-1
	Artist's interpretation of the Jason-1 satellite
Mission type	Oceanography mission
Operator	NASA / CNES
COSPAR ID	2001-055A
SATCAT no.	26997
Website	Ocean Surface Topography from Space
Mission duration	3 years (planned); 11+1⁄2 years (achieved)
Spacecraft properties
Bus	Proteus
Manufacturer	Thales Alenia Space
Launch mass	500 kg (1,100 lb)
Power	1000 watts
Start of mission
Launch date	7 December 2001, 15:07:00 UTC
Rocket	Delta II 7920-10
Launch site	Vandenberg, SLC-2W
Contractor	Boeing Defense, Space & Security
End of mission
Deactivated	1 July 2013
Orbital parameters
Reference system	Geocentric orbit
Regime	Low Earth orbit
Altitude	1,336 km (830 mi)
Inclination	66.0°
Period	112.56 minutes

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Jason-1 ^[1] was a satellite altimeter oceanography mission. It sought to monitor global ocean circulation, study the ties between the ocean and the atmosphere, improve global climate forecasts and predictions, and monitor events such as El Niño and ocean eddies.^[2] Jason-1 was launched in 2001 and it was followed by OSTM/Jason-2 in 2008, and Jason-3 in 2016 – the Jason satellite series. Jason-1 was launched alongside the TIMED spacecraft.

Naming

The lineage of the name begins with the JASO1 meeting (JASO=Journées Altimétriques Satellitaires pour l'Océanographie) in Toulouse, France to study the problems of assimilating altimeter data in models. Jason as an acronym also stands for "Joint Altimetry Satellite Oceanography Network". Additionally, it is used to reference the mythical quest for knowledge of Jason and the Argonauts.[1] Archived 25 March 2016 at the Wayback Machine [2][3] This article incorporates text from this source, which is in the public domain.

History

Jason-1 is the successor to the TOPEX/Poseidon mission,^[3] which measured ocean surface topography from 1992 through 2005. Like its predecessor, Jason-1 is a joint project between the NASA (United States) and CNES (France) space agencies. Jason-1's successor, the Ocean Surface Topography Mission^[4] on the Jason-2 satellite, was launched in June 2008. These satellites provide a unique global view of the oceans that is impossible to acquire using traditional ship-based sampling.

Jason-1 was built by Thales Alenia Space using a Proteus platform, under a contract from CNES, as well as the main Jason-1 instrument, the Poseidon-2 altimeter (successor to the Poseidon altimeter on-board TOPEX/Poseidon).

Jason-1 was designed to measure climate change through very precise millimeter-per-year measurements of global sea level changes. As did TOPEX/Poseidon, Jason-1 uses an altimeter to measure the hills and valleys of the ocean's surface. These measurements of sea surface topography allow scientists to calculate the speed and direction of ocean currents and monitor global ocean circulation. The global ocean is Earth's primary storehouse of solar energy. Jason-1's measurements of sea surface height reveal where this heat is stored, how it moves around Earth by ocean currents, and how these processes affect weather and climate.

Jason-1 was launched on 7 December 2001 from Vandenberg Air Force Base, in California, aboard a Delta II Launch vehicle. During the first months Jason-1 shared an almost identical orbit to TOPEX/Poseidon, which allowed for cross calibration. At the end of this period, the older satellite was moved to a new orbit midway between each Jason ground track. Jason had a repeat cycle of 10 days.

On 16 March 2002, Jason-1 experienced a sudden attitude upset, accompanied by temporary fluctuations in the onboard electrical systems. Soon after this incident, two new small pieces of space debris were observed in orbits slightly lower than Jason-1's, and spectroscopic analysis eventually proved them to have originated from Jason-1. In 2011, it was determined that the pieces of debris had most likely been ejected from Jason-1 by an unidentified, small "high-speed particle" hitting one of the spacecraft's solar panels.^[5]

Orbit maneuvers in 2009 put the Jason-1 satellite on the opposite side of Earth from the OSTM/Jason-2 satellite, which is operated by the United States and French weather agencies. At that time, Jason-1 flew over the same region of the ocean that OSTM/Jason-2 flew over five days earlier. Its ground tracks fell midway between those of OSTM/Jason-2, which are about 315 km (196 mi) apart at the equator.

This interleaved tandem mission provided twice the number of measurements of the ocean's surface, bringing smaller features such as ocean eddies into view. The tandem mission also helped pave the way for a future ocean altimeter mission that would collect much more detailed data with its single instrument than the two Jason satellites now do together.^[6]

In early 2012, having helped cross-calibrate the OSTM/Jason-2 replacement mission, Jason-1 was maneuvered into its graveyard orbit and all remaining fuel was vented.^[7] The mission was still able to return science data, measuring Earth's gravity field over the ocean. On 21 June 2013, contact with Jason-1 was lost; multiple attempts to re-establish communication failed. It was determined that the last remaining transmitter on board the spacecraft had failed. Operators sent commands to the satellite to turn off remaining functioning components on 1 July 2013, rendering it decommissioned. It is estimated that the spacecraft will remain on orbit for at least 1,000 years.^[8]

The program is named after the Greek mythological hero Jason.

Satellite instruments

Jason-1 has five 5 instruments:

Poseidon 2 – Nadir pointing Radar altimeter using C band and K_u band for measuring height above sea surface.
Jason Microwave Radiometer (JMR) – measures water vapor along altimeter path to correct for pulse delay
DORIS (Doppler Orbitography and Radiopositioning Integrated by Satellite) for orbit determination to within 10 cm or less and ionospheric correction data for Poseidon 2.
BlackJack Global Positioning System receiver provides precise orbit ephemeris data
Laser retroreflector array works with ground stations to track the satellite and calibrate and verify altimeter measurements.

The Jason-1 satellite, its altimeter instrument and a position-tracking antenna were built in France. The radiometer, Global Positioning System receiver and laser retroreflector array were built in the United States.

Use of information

TOPEX/Poseidon and Jason-1 have led to major advances in the science of physical oceanography and in climate studies.^[9] Their 15-year data record of ocean surface topography has provided the first opportunity to observe and understand the global change of ocean circulation and sea level. The results have improved the understanding of the role of the ocean in climate change and improved weather and climate predictions. Data from these missions are used to improve ocean models, forecast hurricane intensity, and identify and track large ocean/atmosphere phenomena such as El Niño and La Niña. The data are also used every day in applications as diverse as routing ships, improving the safety and efficiency of offshore industry operations, managing fisheries, and tracking marine mammals.^[10] Their 15-year data record of ocean surface topography has provided the first opportunity to observe and understand the global change of ocean circulation and sea level. The results have improved the understanding of the role of the ocean in climate change and improved weather and climate predictions. Data from these missions are used to improve ocean models, forecast hurricane intensity, and identify and track large ocean/atmosphere phenomena such as El Niño and La Niña. The data are also used every day in applications as diverse as routing ships, improving the safety and efficiency of offshore industry operations, managing fisheries, and tracking marine mammals.

TOPEX/Poseidon and Jason-1 have made major contributions^[11] to the understanding of:

Ocean variability

The missions revealed the surprising variability of the ocean, how much it changes from season to season, year to year, decade to decade and on even longer time scales. They ended the traditional notion of a quasi-steady, large-scale pattern of global ocean circulation by proving that the ocean is changing rapidly on all scales, from huge features such as El Niño and La Niña, which can cover the entire equatorial Pacific, to tiny eddies swirling off the large Gulf Stream in the Atlantic.

Sea level change

Measurements by Jason-1 indicate that mean sea level has been rising at an average rate of 2.28 mm (0.09 inch) per year since 2001. This is somewhat less than the rate measured by the earlier TOPEX/Poseidon mission, but over four times the rate measured by the later Envisat mission. Mean sea level measurements from Jason-1 are continuously graphed at the Centre National d'Études Spatiales web site, on the Aviso page. A composite sea level graph, using data from several satellites, is also available on that site.

The data record from these altimetry missions has given scientists important insights into how global sea level is affected by natural climate variability, as well as by human activities.

Planetary Waves

TOPEX/Poseidon and Jason-1 made clear the importance of planetary-scale waves, such as Rossby and Kelvin waves. No one had realized how widespread these waves are. Thousands of kilometers wide, these waves are driven by wind under the influence of Earth's rotation and are important mechanisms for transmitting climate signals across the large ocean basins. At high latitudes, they travel twice as fast as scientists believed previously, showing the ocean responds much more quickly to climate changes than was known before these missions.

Ocean tides

The precise measurements of TOPEX/Poseidon's and Jason-1 have brought knowledge of ocean tides to an unprecedented level. The change of water level due to tidal motion in the deep ocean is known everywhere on the globe to within 2.5 centimeters (1 inch). This new knowledge has revised notions about how tides dissipate. Instead of losing all their energy over shallow seas near the coasts, as previously believed, about one third of tidal energy is actually lost to the deep ocean. There, the energy is consumed by mixing water of different properties, a fundamental mechanism in the physics governing the general circulation of the ocean.

Ocean models

TOPEX/Poseidon and Jason-1 observations provided the first global data for improving the performance of the numerical ocean models that are a key component of climate prediction models. TOPEX/Poseidon and Jason-1 data are available at the University of Colorado Center for Astrodynamics Research,^[12] NASA's Physical Oceanography Distributed Active Archive Center,^[13] and the French data archive center AVISO.^[14]

Benefits to society

Altimetry data have a wide variety of uses from basic scientific research on climate to ship routing. Applications include:

Climate Research: altimetry data are incorporated into computer models to understand and predict changes in the distribution of heat in the ocean, a key element of climate.
El Niño and La Niña Forecasting: understanding the pattern and effects of climate cycles such as El Niño helps predict and mitigate the disastrous effects of floods and drought.
Hurricane Forecasting: altimeter data and satellite ocean wind data are incorporated into atmospheric models for hurricane season forecasting and individual storm severity.
Ship Routing: maps of ocean currents, eddies, and vector winds are used in commercial shipping and recreational yachting to optimize routes.
Offshore Industries: cable-laying vessels and offshore oil operations require accurate knowledge of ocean circulation patterns to minimize impacts from strong currents.
Marine Mammal Research: sperm whales, fur seals, and other marine mammals can be tracked, and therefore studied, around ocean eddies where nutrients and plankton are abundant.
Fisheries Management: satellite data identify ocean eddies which bring an increase in organisms that comprise the marine food web, attracting fish and fishermen.
Coral Reef Research: remotely sensed data are used to monitor and assess coral reef ecosystems, which are sensitive to changes in ocean temperature.
Marine Debris Tracking: the amount of floating and partially submerged material, including nets, timber and ship debris, is increasing with human population. Altimetry can help locate these hazardous materials.

References

^ "Ocean Surface Topography from Space". NASA/JPL. Archived from the original on 13 May 2008. This article incorporates text from this source, which is in the public domain.
^ "Jason Sets Sail; Satellite to Spot Sea's Solar/Atmospheric Seesaw". NASA/JPL. Archived from the original on 17 February 2013. Retrieved 30 June 2008. This article incorporates text from this source, which is in the public domain.
^ "Ocean Surface Topography from Space". NASA/JPL. Archived from the original on 31 May 2008. This article incorporates text from this source, which is in the public domain.
^ "Ocean Surface Topography from Space". NASA/JPL. Archived from the original on 6 August 2002. This article incorporates text from this source, which is in the public domain.
^ "New Evidence of Particle Impact on Jason-1 Spacecraft" (PDF). NASA. July 2011. Archived from the original (PDF) on 20 October 2011. Retrieved 2 February 2017. This article incorporates text from this source, which is in the public domain.
^ "Tandem Mission Brings Ocean Currents Into Sharper Focus". NASA/JPL. Archived from the original on 22 April 2009. This article incorporates text from this source, which is in the public domain.
^ "Last transmitter dies, finalizing retirement for ocean-sensing satellite" Ars Technica Retrieved: 25 May 2017
^ "Long-Running Jason-1 Ocean Satellite Takes Final Bow", Jet Propulsion Laboratory, Retrieved: 25 May 2017 This article incorporates text from this source, which is in the public domain.
^ "OSTM/JASON-2 SCIENCE AND OPERATIONAL REQUIREMENTS". EUMETSAT. Archived from the original on 28 September 2007.
^ "OSTM/JASON-2 SCIENCE AND OPERATIONAL REQUIREMENTS". EUMETSAT. Archived from the original on 28 September 2007.
^ ""The Legacy of Topex/Poseidon and Jason 1", page 30. Ocean Surface Topography Mission/Jason 2 Launch Press Kit, June 2008" (PDF). NASA/JPL. This article incorporates text from this source, which is in the public domain.
^ "CCAR Near Real-time Altimetry Data Homepage". University of Colorado. Archived from the original on 15 May 2008.
^ "Physical Oceanography DAAC". NASA. This article incorporates text from this source, which is in the public domain.
^ "Aviso Altimetry". CNES.

External links

[1] "Ocean Surface Topography from Space". NASA/JPL. Archived from the original on 13 May 2008. This article incorporates text from this source, which is in the public domain.

[2] "Jason Sets Sail; Satellite to Spot Sea's Solar/Atmospheric Seesaw". NASA/JPL. Archived from the original on 17 February 2013. Retrieved 30 June 2008. This article incorporates text from this source, which is in the public domain.

[3] "Ocean Surface Topography from Space". NASA/JPL. Archived from the original on 31 May 2008. This article incorporates text from this source, which is in the public domain.

[4] "Ocean Surface Topography from Space". NASA/JPL. Archived from the original on 6 August 2002. This article incorporates text from this source, which is in the public domain.

[5] "New Evidence of Particle Impact on Jason-1 Spacecraft" (PDF). NASA. July 2011. Archived from the original (PDF) on 20 October 2011. Retrieved 2 February 2017. This article incorporates text from this source, which is in the public domain.

[6] "Tandem Mission Brings Ocean Currents Into Sharper Focus". NASA/JPL. Archived from the original on 22 April 2009. This article incorporates text from this source, which is in the public domain.

[7] "Last transmitter dies, finalizing retirement for ocean-sensing satellite" Ars Technica Retrieved: 25 May 2017

[8] "Long-Running Jason-1 Ocean Satellite Takes Final Bow", Jet Propulsion Laboratory, Retrieved: 25 May 2017 This article incorporates text from this source, which is in the public domain.

[9] "OSTM/JASON-2 SCIENCE AND OPERATIONAL REQUIREMENTS". EUMETSAT. Archived from the original on 28 September 2007.

[10] "OSTM/JASON-2 SCIENCE AND OPERATIONAL REQUIREMENTS". EUMETSAT. Archived from the original on 28 September 2007.

[11] ""The Legacy of Topex/Poseidon and Jason 1", page 30. Ocean Surface Topography Mission/Jason 2 Launch Press Kit, June 2008" (PDF). NASA/JPL. This article incorporates text from this source, which is in the public domain.

[12] "CCAR Near Real-time Altimetry Data Homepage". University of Colorado. Archived from the original on 15 May 2008.

[13] "Physical Oceanography DAAC". NASA. This article incorporates text from this source, which is in the public domain.

[14] "Aviso Altimetry". CNES.

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v t e Physical oceanography
Waves	Airy wave theory Ballantine scale Benjamin–Feir instability Boussinesq approximation Breaking wave Clapotis Cnoidal wave Cross sea Dispersion Edge wave Equatorial waves Gravity wave Green's law Infragravity wave Internal wave Iribarren number Kelvin wave Kinematic wave Longshore drift Luke's variational principle Mild-slope equation Radiation stress Rogue wave Draupner wave Rossby wave Rossby-gravity waves Sea state Seiche Significant wave height Soliton Stokes drift Stokes problem Stokes wave Swell Trochoidal wave Tsunami megatsunami Undertow Ursell number Wave action Wave base Wave height Wave nonlinearity Wave power Wave radar Wave setup Wave shoaling Wave turbulence Wave–current interaction Waves and shallow water one-dimensional Saint-Venant equations shallow water equations Wind fetch Wind setup Wind wave model
Circulation	Atmospheric circulation Baroclinity Boundary current Coriolis force Coriolis–Stokes force Craik–Leibovich vortex force Downwelling Eddy Ekman layer Ekman spiral Ekman transport El Niño–Southern Oscillation General circulation model Geochemical Ocean Sections Study Geostrophic current Global Ocean Data Analysis Project Gulf Stream Humboldt Current Hydrothermal circulation Langmuir circulation Longshore drift Loop Current Modular Ocean Model Ocean current Ocean dynamical thermostat Ocean dynamics Ocean gyre Overflow Princeton Ocean Model Rip current Subsurface ocean current Sverdrup balance Thermohaline circulation shutdown Upwelling Whirlpool Wind generated current World Ocean Circulation Experiment
Tides	Amphidromic point Earth tide Head of tide Internal tide Lunitidal interval Perigean spring tide Rip tide Rule of twelfths Slack tide Theory of tides Tidal bore Tidal force Tidal power Tidal race Tidal range Tidal resonance Tide gauge Tideline
Landforms	Abyssal fan Abyssal plain Atoll Bathymetric chart Carbonate platform Coastal geography Cold seep Continental margin Continental rise Continental shelf Contourite Guyot Hydrography Knoll Ocean bank Oceanic basin Oceanic plateau Oceanic trench Passive margin Seabed Seamount Submarine canyon Submarine volcano
Plate tectonics	Convergent boundary Divergent boundary Fracture zone Hydrothermal vent Marine geology Mid-ocean ridge Mohorovičić discontinuity Oceanic crust Outer trench swell Ridge push Seafloor spreading Slab pull Slab suction Slab window Subduction Transform fault Vine–Matthews–Morley hypothesis Volcanic arc
Ocean zones	Benthic Deep ocean water Deep sea Littoral Mesopelagic Oceanic Pelagic Photic Surf Swash
Sea level	Deep-ocean Assessment and Reporting of Tsunamis Global Sea Level Observing System North West Shelf Operational Oceanographic System Sea-level curve Sea level drop Sea level rise World Geodetic System
Acoustics	Deep scattering layer Ocean acoustic tomography Sofar bomb SOFAR channel Underwater acoustics
Satellites	Jason-1 OSTM/Jason-2 Jason-3
Related	Acidification Argo Benthic lander Color of water DSV Alvin Marginal sea Marine energy Marine pollution Mooring National Oceanographic Data Center Ocean Explorations Observations Reanalysis Ocean surface topography Ocean temperature Ocean thermal energy conversion Oceanography Outline of oceanography Pelagic sediment Sea surface microlayer Sea surface temperature Seawater Science On a Sphere Stratification Thermocline Underwater glider Water column World Ocean Atlas
Category Commons Oceans portal

v t e Jet Propulsion Laboratory
Current missions	Euclid Psyche ACRIMSAT ASTER Atmospheric infrared sounder (AIRS) Deep Space Atomic Clock GRACE-FO InSight Juno Keck observatory Large Binocular Telescope (LBT) Mars Odyssey Mars 2020 Perseverance rover Ingenuity helicopter Mars Reconnaissance Orbiter (MRO) Mars Science Laboratory (MSL) Microwave limb sounder (MLS) Multi-angle imaging spectroradiometer (MISR) Soil Moisture Active Passive (SMAP) Tropospheric Emission Spectrometer (TES) SWOT Voyager program Voyager 1 Voyager 2
Past missions	Cassini-Huygens Dawn Deep Impact Deep Space 1 Deep Space 2 Explorers GALEX Galileo spacecraft Genesis GRACE Herschel IRAS Jason-1 Kepler Magellan Mariner Mars Climate Orbiter Mars Cube One (MarCO) Mars Observer Mars Pathfinder Mars Polar Lander Mars Global Surveyor Mars Exploration Rovers Spirit rover Opportunity rover Near-Earth Asteroid Scout NSCAT Phoenix Pioneer QuikSCAT Ranger Rosetta Seasat Shuttle Radar Topography Mission (SRTM) Solar Mesosphere Explorer (SME) Spaceborne Imaging Radar (SIR) Spitzer Space Telescope Stardust Surveyor SVLBI TOPEX/Poseidon Ulysses Viking Wide Field and Planetary Camera (WFPC) Wide Field Infrared Explorer (WIRE) Lunar Flashlight
Planned missions	Europa Clipper Nancy Grace Roman Space Telescope SPHEREx
Proposed missions	Europa Lander FINESSE
Canceled missions	Astrobiology Field Laboratory (AFL) Mars Astrobiology Explorer-Cacher (MAX-C)
Related organizations	NASA Caltech NASA Deep Space Network Goldstone Complex Table Mountain Observatory Solar System Ambassadors
JPL Science Division Near-Earth Asteroid Tracking Space Flight Operations Facility

v t e ← 2000 Orbital launches in 2001 2002 →
January ,	Shenzhou 2 Türksat 2A Progress M1-5 USA-156
February ,	Sicral 1, Skynet 4F STS-98 (Destiny) Odin Progress M-44 USA-157
March ,	STS-102 (Leonardo MPLM) Eurobird 1, BSAT-2a XM-2
April ,	Ekran-M No.18L 2001 Mars Odyssey GSAT-1 STS-100 (Raffaello MPLM) Soyuz TM-32
May ,	XM-1 PAS-10 USA-158 Progress M1-6 Kosmos 2377
June ,	Kosmos 2378 Intelsat 901 Astra 2C ICO F2 MAP
July ,	STS-104 (Quest) Artemis, BSAT-2b Molniya-3K No.11 GOES 12 Koronas-F
August ,	USA-159 Genesis STS-105 (Leonardo MPLM, Simplesat) Progress M-45 Kosmos 2379 VEP-2, LRE Intelsat 902
September ,	USA-160 Progress M-SO1 (Pirs) OrbView-4, QuickTOMS, SBD, Odyssey Atlantic Bird 2 Starshine 3, PICOSat, PCSat, SAPPHIRE
October ,	USA-161 Globus No.14L USA-162 QuickBird-2 Soyuz TM-33 TES, PROBA, BIRD Molniya-3 No.64
November ,	Progress M1-7 (Kolibri 2000) DirecTV-4S
December ,	Kosmos 2380, Kosmos 2381, Kosmos 2382 STS-108 (Raffaello MPLM, Starshine 2 Jason-1, TIMED Meteor-3M #1, Kompass, Badr-B, Maroc-Tubsat, Reflektor Kosmos 2383 Kosmos 2384, Kosmos 2385, Kosmos 2386, Gonets-D1 No.10, Gonets-D1 No.11, Gonets-D1 No.12
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).