Jason-3

Instruments
	Poseidon-3B Altimeter
AMR-2	Advanced Microwave Radiometer-2
DORIS	Doppler Orbitography and Radiopositioning Integrated by Satellite
GPSP	Global Positioning System Payload
LRA	Laser Retroreflector Array
CARMEN-3	Characterization and Modeling of Environment-3
LPT	Light Particle Telescope

Ocean Surface Topography
← OSTM/Jason-2	Jason-CS →

Jason-3 is an international Earth observation satellite mission that continues the ocean surface height measurements begun in 1992 by the TOPEX/Poseidon mission, followed by Jason-1 launched in 2001 and Jason-2 in 2008.^[4]

Jason-3 is the result of a four-agency international partnership consisting of NOAA, NASA, the French Space Agency CNES (Centre National d’Etudes Spatiales), and EUMETSAT (the European Organization for the Exploitation of Meteorological Satellites). The spacecraft was built by Thales Alenia Space and launched by SpaceX on the 21st Falcon 9 flight.

Science objectives

The science objectives for Jason-3 are:

Extend the time series of ocean surface topography measurements beyond TOPEX/Poseidon and Jason-1 to accomplish two decades of observations
Provide a minimum of three years of global ocean surface topography measurement
Determine the variability of ocean circulation at decadal time scales from combined data record of TOPEX/Poseidon and Jason-1
Improve the measure of the time-averaged ocean circulation
Improve the measure of global sea level change
Improve open ocean tide models

Spacecraft

The satellite was built around a Proteus satellite bus by Thales Alenia Space under contract from CNES. A pair of deployable, tracking solar arrays supply a total of 580 watts of power. Four hydrazine monopropellant thrusters are used for orbital maneuvering. Attitude control is provided by reaction wheels, with magnetorquers used to periodically despin the wheels.^[5] Jason-3 weighed about 553 kg (1,219 lb) at launch, with a dry mass of 525 kg (1,157 lb).^[1]

Instruments

Jason-3 carries five main instruments. The primary instrument is the Poseidon-3B Altimeter, which is derived from the Poseidon-3 carried on Jason-2. The other main instruments are Doppler Orbitography and Radiopositioning Integrated by Satellite (DORIS), Advanced Microwave Radiometer-2 (AMR-2), Global Positioning System Payload (GPSP), and Laser Retroreflector Array (LRA). Two additional "passenger instruments" are carried as part of the Joint Radiation Experiment. These are CARMEN-3 (Characterization and Modeling of Environment), which measures charged particle flux, and Light Particle Telescope (LPT), which measures radiation and charged particles.^[6]

Launch

Falcon 9 rolling out on January 15, 2015

Appearing on the SpaceX manifest as early as July 2013,^[7] Jason-3 was originally scheduled for launch on July 22, 2015. However, this date was pushed back to August 19 following the discovery of contamination in one of the satellite's thrusters, requiring the thruster to be replaced and further inspected.^[8]^[9] The launch was further delayed by several months due to the loss of a Falcon 9 rocket with the CRS-7 mission on June 28.^[10]

After SpaceX conducted their return-to-flight mission in December 2015 with the upgraded Falcon 9 Full Thrust, Jason-3 was assigned to the final previous-generation Falcon 9 v1.1 rocket, although some parts of the rocket body had been reworked following the findings of the failure investigation.^[11]^[12]

A 7-second static fire test of the rocket was completed on January 11, 2016.^[13] The Launch Readiness Review was signed off by all parties on January 15, 2016, and the launch proceeded successfully on January 17, 2016, at 18:42 UTC. The Jason-3 payload was deployed into its target orbit at 830 miles (1,336 km) altitude after an orbital insertion burn about 56 minutes into the flight.^[14] It was the 21st Falcon 9 flight overall^[11] and the second into a high-inclination orbit from Vandenberg Air Force Base Space Launch Complex 4E in California.^[8]

Post-mission landing test

Main article: Falcon 9 first-stage landing tests

First stage of Falcon 9 Flight 21 descending over the floating landing platform, January 17, 2016

Following paperwork filed with US regulatory authorities in 2015,^[15] SpaceX confirmed in January 2016 that they would attempt a controlled-descent flight test and vertical landing of the rocket's first stage on their west-coast floating platform Just Read the Instructions,^[16] located about 200 miles (320 km) out in the Pacific Ocean.

This attempt followed the first successful landing and booster recovery on the previous launch in December 2015.^[17]^[18] The controlled descent through the atmosphere and landing attempt for each booster is an arrangement that is not used on other orbital launch vehicles.^[19]

Approximately nine minutes into the flight, the live video feed from the drone ship went down due to the losing its lock on the uplink satellite. Elon Musk later reported that the first stage did touch down smoothly on the ship, but a lockout on one of the four landing legs failed to latch, so that the booster fell over and was destroyed.^[20]^[21]^[22]

Debris from the fire, including several rocket engines attached to the octaweb assembly, arrived back to shore on board the floating landing platform on January 18, 2016.^[23]

References

1 2 3 4 "Satellite: JASON-3". World Meteorological Organization. Retrieved January 17, 2016.
↑ "Jason-3 Ocean-Monitoring Satellite healthy after smooth ride atop Falcon 9 Rocket". Spaceflight 101. January 17, 2016. Retrieved January 17, 2016.
↑ "Jason 3 - Orbit". Heavens Above. July 16, 2016. Retrieved July 16, 2016.
↑ "What is Jason-3?". NOAA.
↑ "Jason-3 Spacecraft & Instruments". Spaceflight 101. Retrieved January 6, 2016.
↑ "Spacecraft". NOAA.
↑ "Launch Manifest - Future Missions". SpaceX. Archived from the original on July 31, 2013.
1 2 Rhian, Jason (June 3, 2015). "Thruster contamination on NOAA's Jason-3 satellite forces delay". Spaceflight Insider.
↑ Clark, Stephen (June 18, 2015). "Jason 3 satellite shipped to Vandenberg for SpaceX launch". Spaceflight Now.
↑ "CRS-7 Investigation Update". SpaceX. July 20, 2015. Retrieved July 21, 2015. Our investigation is ongoing until we exonerate all other aspects of the vehicle, but at this time, we expect to return to flight this fall and fly all the customers we intended to fly in 2015 by end of year.
1 2 Bergin, Chris (September 7, 2015). "SpaceX conducts additional Falcon 9 improvements ahead of busy schedule". NASASpaceFlight.com. Retrieved September 7, 2015.
↑ Gebhardt, Chris (January 8, 2016). "SpaceX Falcon 9 v1.1 conducts static fire test ahead of Jason-3 mission". NASASpaceFlight.com. Retrieved January 9, 2016.
↑ Curie, Mike (January 11, 2016). "SpaceX Falcon 9 Static Fire Complete for Jason-3". NASA. Retrieved January 12, 2016. At Space Launch Complex 4 on Vandenberg Air Force Base in California, the static test fire of the SpaceX Falcon 9 rocket for the upcoming Jason-3 launch was completed Monday at 5:35 p.m. PST, 8:35 p.m. EST. The first stage engines fired for the planned full duration of 7 seconds.
↑ Jason-3 Hosted Webcast. YouTube.com. SpaceX. January 17, 2016. Event occurs at 1:37:08 (55:58 after lift-off). Retrieved January 17, 2016.
↑ "Application for Special Temporary Authority". Federal Communications Commission. December 28, 2015.
↑ Coldewey, Devin (January 7, 2016). "SpaceX Plans Drone Ship Rocket Landing for Jan. 17 Launch". NBC News. Retrieved January 8, 2016.
↑ "Press Kit: ORBCOMM-2 Mission" (PDF). SpaceX. December 21, 2015. Retrieved December 21, 2015. This mission also marks SpaceX's return-to-flight as well as its first attempt to land a first stage on land. The landing of the first stage is a secondary test objective.
↑ Gebhardt, Chris (December 31, 2015). "Year In Review, Part 4: SpaceX and Orbital ATK recover and succeed in 2015". NASASpaceFlight.com. Retrieved January 1, 2016.
↑ "SpaceX wants to land next booster at Cape Canaveral". Florida Today. December 1, 2015. Retrieved December 4, 2015.
↑ Jason-3 Hosted Webcast. YouTube.com. SpaceX. January 17, 2016. Event occurs at 1:06:30 (25:20 after lift-off). Retrieved January 17, 2016.
↑ Boyle, Alan (January 17, 2016). "SpaceX rocket launches satellite, but tips over during sea landing attempt". GeekWire. Retrieved January 18, 2016.
↑ Musk, Elon (January 17, 2016). "Flight 21 landing and breaking a leg". Instagram.
↑ "SpaceX rocket wreckage back on shore after near-miss at landing". Spaceflight Now. January 20, 2016. Retrieved January 21, 2016.

External links

About the satellite

Wikimedia Commons has media related to Jason-3.

Wikimedia Commons has media related to Falcon 9 Flight 21.

Jason-3 website by NASA JPL
Jason-3 website by NASA JPL's Ocean Surface Topography program
Jason-3 website by NOAA
Jason-3 website by CNES
Jason-3 website by EUMETSAT
Jason-3 website by ESA's eoPortal

About the flight

Jason-3 press kit by SpaceX

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 JERS-1 (Fuyo-1) Nimbus PARASOL QuickBird RADARSAT-1 Seasat SeaWiFS TIROS TOPEX/Poseidon UARS Vanguard

Failed	OCO Glory

Cancelled	NMP/EO-3

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 Fetch Gravity wave Green's law Infragravity wave Internal wave Kelvin wave Kinematic wave Longshore drift Luke's variational principle Mild-slope equation Radiation stress Rogue wave Rossby wave Rossby-gravity waves Sea state Seiche Significant wave height Sneaker wave Soliton Stokes boundary layer Stokes drift Stokes wave Swell Trochoidal wave Tsunami megatsunami Undertow Ursell number Wave action Wave base Wave height 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 wave model

Circulation	Atmospheric circulation Baroclinity Boundary current Coriolis effect Downwelling Eddy Ekman layer Ekman spiral Ekman transport El Niño Southern Oscillation General Circulation Model Geostrophic current Global Ocean Data Analysis Project Gulf Stream Halothermal circulation Humboldt Current Hydrothermal circulation Langmuir circulation Longshore drift Loop Current Maelstrom Modular ocean model Ocean dynamics Ocean gyre Princeton ocean model Rip current Subsurface currents Sverdrup balance Thermohaline circulation shutdown Upwelling Whirlpool 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 water Tidal bore Tidal force Tidal power Tidal race Tidal range Tidal resonance Tide gauge Tideline

Landforms	Abyssal fan Abyssal plain Atoll Bathymetric chart Coastal geography Cold seep Continental margin Continental rise Continental shelf Contourite Guyot Hydrography 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 Vine–Matthews–Morley hypothesis Oceanic crust Outer trench swell Ridge push Seafloor spreading Slab pull Slab suction Slab window Subduction Transform fault 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 Future sea level Global Sea Level Observing System North West Shelf Operational Oceanographic System Sea-level curve Sea level rise World Geodetic System

Acoustics	Deep scattering layer Hydroacoustics Ocean acoustic tomography Sofar bomb SOFAR channel Underwater acoustics

Satellites	Jason-1 Jason-2 (Ocean Surface Topography Mission) Jason-3

Related	Argo Benthic lander Color of water DSV Alvin Marginal sea Marine energy Marine pollution Mooring National Oceanographic Data Center Ocean Ocean exploration Ocean observations Ocean reanalysis Ocean surface topography Ocean thermal energy conversion Oceanography Pelagic sediment Sea surface microlayer Sea surface temperature Seawater Science On a Sphere Thermocline Underwater glider Water column World Ocean Atlas

Category Commons

SpaceX

Vehicles

Rockets

Current	Falcon 9 Full Thrust

In development	Falcon Heavy ITS launch vehicle

Retired	Falcon 1 Falcon 9 v1.0 v1.1

Cancelled	Falcon 1e Falcon 5 Falcon 9 Air

Test vehicles

Grasshopper (retired)
F9R Dev1† (destroyed)
DragonFly

Spacecraft

Engines

Merlin (1A, 1B, 1C, 1D, Vacuum)
Kestrel
Draco
SuperDraco
Raptor
Methalox thruster

Missions

Falcon 1

Demo 1† (FalconSAT-2)
Demo 2† (DemoSat)
Flight 3†
Ratsat
RazakSAT

Falcon 9

Demonstration flights	Dragon Spacecraft Qualification Unit NASA COTS Demo Flight 1 Dragon C2+

Dragon ISS logistics	CRS-1 CRS-2 CRS-3 CRS-4 CRS-5 CRS-6 CRS-7† CRS-8 CRS-9 CRS-10 CRS-11 CRS-12

Commercial satellites	SES-8 Thaicom 6 Orbcomm OG2 × 6 AsiaSat 8 AsiaSat 6 ABS-3A / Eutelsat 115 West B TurkmenAlem 52E Orbcomm OG2 × 11 SES-9 JCSAT-14 Thaicom 8 ABS-2A / Eutelsat 117 West B JCSAT-16 Amos-6† EchoStar 23 Iridium NEXT 1-10 SES-10 SES-11

Scientific satellites	CASSIOPE DSCOVR Jason-3 FormoSat-5

Falcon Heavy

Demo Flight 1
USAF STP-2
- DSX
- FormoSat-7
- LightSail 2
- GPIM
- DSAC
- ISAT
Inmarsat-5 F4
Red Dragon

Launch sites

Orbital	Cape Canaveral, Florida CCAFS Launch Complex 40 Kennedy Launch Pad 39A Vandenberg, California Launch Complex 4E Brownsville, Texas Boca Chica Kwajalein, Marshall Islands Omelek Island†

Suborbital	McGregor test site New Mexico test site†

Landing sites

Other facilities

Headquarters and factory (Hawthorne, California)
Rocket development and test facility (McGregor, Texas)
Satellite development facility (Redmond, Washington)
Regional offices (Chantilly, Houston, Seattle, Washington DC)

Contracts

Commercial Orbital Transportation Services (COTS)
Commercial Resupply Services (CRS)
Commercial Crew Development (CCDev)
Commercial Crew integrated Capability (CCiCap)

R&D programs

People

Elon Musk (CEO, CTO)
Gwynne Shotwell (President & COO)
Tom Mueller (Vice President of Propulsion Development)

Italics indicate unflown vehicles and future missions or sites. † denotes failed missions, destroyed vehicles and abandoned sites.

← 2015 · Orbital launches in 2016 · 2017 →

January	Belintersat-1 – Jason-3 – IRNSS-1E – Intelsat 29e – Eutelsat 9B

February	BeiDou M3-S – USA-266 / GPS IIF -12 – Kosmos 2514 / GLONASS-M 751 – Kwangmyŏngsŏng-4 – USA-267 / NROL-45 / Topaz-4 – Sentinel-3A – ASTRO-H / Hitomi · ChubuSat-2 · ChubuSat-3 · Horyu-4

March	SES-9 – Eutelsat 65 West A – IRNSS-1F – Resurs-P No.3 – ExoMars Trace Gas Orbiter · Schiaparelli EDM lander – Soyuz TMA-20M – Cygnus CRS OA-6 (Diwata-1 · Flock-2e' × 20 · Lemur-2 × 9) – Kosmos 2515 / Bars-M No.2 – BeiDou IGSO-6 – Progress MS-02

April	Shijian-10 – Dragon CRS-8 · BEAM – Sentinel-1B · MICROSCOPE · AAUSAT-4 · e-st@r-II · OUFTI-1 – Mikhailo Lomonosov · Aist-2D · SamSat 218 – IRNSS-1G

May	JCSAT-14 – Yaogan 30 – Galileo FOC-10, FOC-11 – Thaicom 8 – Kosmos 2516 / GLONASS-M 753 – Ziyuan III-02 · ÑuSat-1/-2

June	Kosmos 2517 / Geo-IK-2 No.12 – Intelsat 31 / DLA-2 – USA-268 / NROL-37 – BeiDou G7 – Eutelsat 117 West B · ABS-2A – Echostar 18 · BRIsat – CartoSat-2C · BIROS · GHGsat · LAPAN-A3 · M3MSat · SkySat-C1 · Flock-2p x 12 · SathyabamaSat · Swayam – MUOS-5 – Chinese next-generation crew capsule scale model · Aolong-1 · Aoxiang Zhixing · Tiange-1 · Tiange-2 – Shijian 16-02

July	Soyuz MS-01 – Progress MS-03 – Dragon CRS-9 – USA-269 / NROL-61

August	Tiantong-1 01 – Gaofen-3 – JCSAT-16 – QUESS / Mozi / Micius · ³Cat-2 · LiXing-1 – USA-270 / GSSAP #3 · USA-271 / GSSAP #4 – Intelsat 33e · Intelsat 36 – Gaofen-10

September	Amos-6 – INSAT-3DR – OSIRIS-REx – Ofek-11 – Tiangong-2 – PeruSat-1 · SkySat × 4 – ScatSat-1 · Alsat-1B · Alsat-2B · Blacksky Pathfinder-1 · Alsat-1N · CanX-7 · PISat · Pratham

October	Sky Muster II · GSAT-18 – Shenzhou 11 – Cygnus CRS OA-5 (Lemur-2 × 4) – Soyuz MS-02

November	Himawari 9 – Shijian-17 – XPNAV 1 – WorldView-4 · CELTEE 1 · Prometheus-2 × 2 · AeroCube 8 × 2 · U2U · RAVAN – Yunhai-1 – Galileo FOC 7, 12, 13, 14 – Soyuz MS-03 – GOES-R – Tianlian I-04

December	Progress MS-04 – Göktürk-1 – Resourcesat-2A – WGS-8 – HTV-6 / Kounotori 6 · (EGG · TuPOD · UBAKUSAT · AOBA-VELOX · STARS · FREEDOM · ITF · Waseda-SAT · OSNSAT · Tancredo · TechEDSat · Lemur-2 × 4) – Fengyun 4A

Launches are separated by dashes ( – ), payloads by dots ( · ), multiple names for the same satellite by slashes ( / ). Cubesats are smaller. Manned flights are bolded. Launch failures are in italics. Payloads deployed from other spacecraft are (enclosed in brackets).

This article is issued from Wikipedia - version of the 10/24/2016. The text is available under the Creative Commons Attribution/Share Alike but additional terms may apply for the media files.

Jason-3

Science objectives

Spacecraft

Instruments

Launch

Post-mission landing test

See also

References

External links

About the satellite

About the flight