2001 Mars Odyssey | |
Insignia: | 2001 Mars Odyssey - mars-odyssey-logo-sm.png |
Insignia Size: | 125px |
Mission Type: | Mars orbiter |
Operator: | NASA / JPL |
Cospar Id: | 2001-013A |
Satcat: | 26734 |
Manufacturer: | Lockheed Martin |
Dry Mass: | 376.3kg (829.6lb) |
Launch Mass: | 725 kg[1] |
Power: | 750 W |
Launch Date: | UTC |
Launch Rocket: | Delta II 7925-9.5 |
Launch Site: | Cape Canaveral SLC-17A |
Launch Contractor: | Boeing |
Last Contact: | Q4 2025 (planned) |
Orbit Epoch: | October 19, 2002[2] |
Orbit Reference: | Areocentric |
Orbit Regime: | Sun-synchronous |
Orbit Altitude: | 400km (200miles) |
Orbit Inclination: | 93.064° |
Orbit Period: | 2 hours |
Orbit Semimajor: | 3793.4km (2,357.1miles) |
Orbit Raan: | 34.98° |
Orbit Arg Periapsis: | 0° |
Orbit Mean Anomaly: | 0° |
Orbit Eccentricity: | 0.0 |
Apsis: | areion |
Interplanetary: | |
Programme: | Mars Exploration Program |
Previous Mission: | Mars Polar Lander |
Next Mission: | Spirit |
2001 Mars Odyssey is a robotic spacecraft orbiting the planet Mars. The project was developed by NASA, and contracted out to Lockheed Martin, with an expected cost for the entire mission of US$297 million. Its mission is to use spectrometers and a thermal imager to detect evidence of past or present water and ice, as well as study the planet's geology and radiation environment.[3] The data Odyssey obtains is intended to help answer the question of whether life once existed on Mars and create a risk-assessment of the radiation that future astronauts on Mars might experience. It also acts as a relay for communications between the Curiosity rover, and previously the Mars Exploration Rovers and Phoenix lander, to Earth. The mission was named as a tribute to Arthur C. Clarke, evoking the name of his and Stanley Kubrick's 1968 film 2001: A Space Odyssey.[4] [5]
Odyssey was launched April 7, 2001, on a Delta II rocket from Cape Canaveral Air Force Station, and reached Mars orbit on October 24, 2001, at 02:30 UTC (October 23, 19:30 PDT, 22:30 EDT).[6]
On May 28, 2002 (sol), NASA reported that Odysseys GRS instrument had detected large amounts of hydrogen, a sign that there must be ice lying within a meter of the planet's surface, and proceeded to map the distribution of water below the shallow surface.[7] The orbiter also discovered vast deposits of bulk water ice near the surface of equatorial regions.[8]
By December 15, 2010, it broke the record for longest serving spacecraft at Mars, with 3,340 days of operation.[9] [10] Odyssey has also served as the primary means of communications for NASA's Mars surface explorers in the past decade, up to the Curiosity rover. It currently holds the record for the longest-surviving continually active spacecraft in orbit around a planet other than Earth, ahead of the Pioneer Venus Orbiter (served 14 years[11]) and the Mars Express (serving over 20 years), at . it is in a polar orbit around Mars with a semi-major axis of about 3,800 km or 2,400 miles. It is estimated to have enough propellant to function until the end of 2025.[12]
In August 2000, NASA solicited candidate names for the mission. Out of 200 names submitted, the committee chose Astrobiological Reconnaissance and Elemental Surveyor, abbreviated ARES (a tribute to Ares, the Greek god of war). Faced with criticism that this name was not very compelling, and too aggressive, the naming committee reconvened. The candidate name "2001 Mars Odyssey" had earlier been rejected because of copyright and trademark concerns. However, NASA e-mailed Arthur C. Clarke in Sri Lanka, who responded that he would be delighted to have the mission named after his books, and he had no objections. On September 20, NASA associate administrator Ed Weiler wrote to the associate administrator for public affairs recommending a name change from ARES to 2001 Mars Odyssey. Peggy Wilhide then approved the name change.[13] [14]
The three primary instruments Odyssey uses are the:
Mars Odyssey launched from Cape Canaveral on April 7, 2001, and arrived at Mars about 200 days later on October 24. Upon arrival, the spacecraft's main engine fired[19] in order to decelerate, which allowed it to be captured into orbit around Mars. Odyssey then spent about 76 days aerobraking, using aerodynamic drag from the upper reaches of the Martian atmosphere to gradually slow down and reduce and circularize its orbit. By planning to use the atmosphere of Mars to slow the spacecraft in its orbit rather than firing its engine or thrusters, Odyssey did not need an additional 200 kilograms (440 lb) of propellant on board. This reduction in spacecraft weight allowed the mission to be launched on a Delta II 7925 launch vehicle, rather than a larger, more expensive launcher.[20]
Aerobraking ended in January 2002, and Odyssey began its science mapping mission on February 19, 2002. Odysseys original, nominal mission lasted until August 2004, but repeated mission extensions have kept the mission active.[21]
The payload's MARIE radiation experiment stopped taking measurements after a large solar event bombarded the Odyssey spacecraft on October 28, 2003. Engineers believe the most likely cause is that a computer chip was damaged by a solar particle smashing into the MARIE computer board.[22]
About 85% of images and other data from NASA's twin Mars Exploration Rovers, Spirit and Opportunity, have reached Earth via communications relay by Odyssey.[23] The orbiter helped analyze potential landing sites for the rovers and performed the same task for NASA's Phoenix mission, which landed on Mars in May 2008. Odyssey aided NASA's Mars Reconnaissance Orbiter, which reached Mars in March 2006, by monitoring atmospheric conditions during months when the newly arrived orbiter used aerobraking to alter its orbit into the desired shape.[24]
Odyssey is in a Sun-synchronous orbit,[25] which provides consistent lighting for its photographs. On September 30, 2008 (sol) the spacecraft altered its orbit to gain better sensitivity for its infrared mapping of Martian minerals. The new orbit eliminated the use of the gamma ray detector, due to the potential for overheating the instrument at the new orbit.[26]
The orbiter's orientation is controlled by a set of three reaction wheels and a spare. When one failed in June 2012, the fourth was spun up and successfully brought into service. Since July 2012, Odyssey has been back in full, nominal operation mode following three weeks of 'safe' mode on remote maintenance.[27] [28]
Mars Odysseys THEMIS instrument was used to help select a landing site for the Mars Science Laboratory (MSL).[29] Several days before MSL's landing in August 2012, Odysseys orbit was altered to ensure that it would be able to capture signals from the rover during its first few minutes on the Martian surface.[30] Odyssey also acted as a relay for UHF radio signals from the (MSL) rover Curiosity.[31] Because Odyssey is in a Sun-synchronous orbit, it passes over Curiositys location twice per day, enabling regular contact with Earth.[32]
On February 11, 2014, mission control accelerated Odysseys drift toward a morning-daylight orbit to "enable observation of changing ground temperatures after sunrise and after sunset in thousands of places on Mars". The orbital change occurred gradually until November 2015.[33] Those observations could yield insight about the composition of the ground and about temperature-driven processes, such as warm seasonal flows observed on some slopes, and geysers fed by spring thawing of carbon dioxide (CO2) ice near Mars' poles.
On October 19, 2014, NASA reported that the Mars Odyssey Orbiter,[34] as well as the Mars Reconnaissance Orbiter[35] and MAVEN,[36] were healthy after the Comet Siding Spring flyby.[37] [38]
In 2010, a spokesman for NASA's Jet Propulsion Laboratory stated that Odyssey could continue operating until at least 2016.[39] This estimate has since been extended to the end of 2025.
By 2008, Mars Odyssey had mapped the basic distribution of water below the shallow surface.[40] The ground truth for its measurements came on July 31, 2008, when NASA announced that the Phoenix lander confirmed the presence of water on Mars,[41] as predicted in 2002 based on data from the Odyssey orbiter. The science team is trying to determine whether the water ice ever thaws enough to be available for microscopic life, and if carbon-containing chemicals and other raw materials for life are present.[42]
The orbiter also discovered vast deposits of bulk water ice near the surface of equatorial regions.[8] Evidence for equatorial hydration is both morphological and compositional and is seen at both the Medusae Fossae formation and the Tharsis Montes.[8]