Difference between revisions of "Viking 1"
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− | The '''Viking 1''' was the first of two spacecraft sent to [[Mars (planet)|Mars]] as part of [[NASA]]'s [[Viking program]]. For a description of the spacecraft, see the [[Viking program]] article. | + | '''The '''Viking 1'''''' was the first of two spacecraft sent to [[Mars (planet)|Mars]] as part of [[NASA]]'s [[Viking program]]. For a description of the spacecraft, see the [[Viking program]] article. |
[[Image:Vikinglander-view.jpg|thumb|right|This image was acquired at the Viking Lander 1 site with camera number 1. The large rock just left of center is about 2 meters wide. This rock was named "Big Joe" by the Viking scientists. The top of the rock is covered with red soil. Those portions of the rock not covered are similar in color to basaltic rocks on Earth. Therefore, this may be a fragment of a lava flow that was ejected by an impact crater.]] | [[Image:Vikinglander-view.jpg|thumb|right|This image was acquired at the Viking Lander 1 site with camera number 1. The large rock just left of center is about 2 meters wide. This rock was named "Big Joe" by the Viking scientists. The top of the rock is covered with red soil. Those portions of the rock not covered are similar in color to basaltic rocks on Earth. Therefore, this may be a fragment of a lava flow that was ejected by an impact crater.]] | ||
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[[Image:PSP 001521 2025 RED VL-1 lander.png|thumb|Photo of the Viking 1 lander taken by the [[Mars Reconnaissance Orbiter]] in December 2006]] | [[Image:PSP 001521 2025 RED VL-1 lander.png|thumb|Photo of the Viking 1 lander taken by the [[Mars Reconnaissance Orbiter]] in December 2006]] | ||
− | + | == Test of General Relativity == | |
+ | [[General Relativity]] predicts "[[Gravitational Time Dilation]]". Scientists used the lander to observe such phenomena. Scientists sent radio signals to the lander on Mars, and instructed the lander to send back signals. Scientists then found that the time signals needed to make a round trip match the prediction of Gravitational Time Dilation. | ||
==See also== | ==See also== |
Revision as of 09:19, 31 January 2007
'The Viking 1' was the first of two spacecraft sent to Mars as part of NASA's Viking program. For a description of the spacecraft, see the Viking program article.
Mission
Following launch using a Titan/Centaur launch vehicle on 20 August 1975 and a 10 month cruise to Mars, the orbiter began returning global images of Mars about 5 days before orbit insertion. The Viking 1 Orbiter was inserted into Mars orbit on 19 June 1976 and trimmed to a 1513 x 33,000 km, 24.66 h site certification orbit on 21 June. Landing on Mars was planned for July 4, 1976, the United States Bicentennial, but imaging of the primary landing site showed it was too rough for a safe landing. The landing was delayed until a safer site was found. The lander separated from the orbiter on 20 July 08:51 UT and landed at 11:56:06 UT.
Orbiter
The orbiter primary mission ended at the beginning of solar conjunction on 5 November, 1976. The extended mission commenced on 14 December, 1976 after solar conjunction. Operations included close approaches to Phobos in February 1977. The periapsis was reduced to 300 km on 11 March, 1977. Minor orbit adjustments were done occasionally over the course of the mission, primarily to change the walk rate — the rate at which the planetocentric longitude changed with each orbit, and the periapsis was raised to 357 km on 20 July, 1979. On 7 August, 1980 Viking 1 Orbiter was running low on altitude control gas and its orbit was raised from 357 × 33943 km to 320 × 56000 km to prevent impact with Mars and possible contamination until the year 2019. Operations were terminated on August 17, 1980 after 1485 orbits.
Lander
The lander and its aeroshell separated from the orbiter on July 20 08:51 UT. At the time of separation, the lander was orbiting at about 4 km/s. After separation rockets fired to begin lander deorbit. After a few hours at about 300 km altitude, the lander was reoriented for entry. The aeroshell with its ablatable heat shield slowed the craft as it plunged through the atmosphere. During this time, entry science experiments were performed. At 6 km altitude at about 250 m/s the 16 m diameter lander parachutes were deployed. Seven seconds later the aeroshell was jettisoned, and 8 seconds after that the three lander legs were extended. In 45 seconds the parachute had slowed the lander to 60 m/s. At 1.5 km altitude, retro-rockets were ignited and fired until landing 40 seconds later at about 2.4 m/s. The landing rockets used an 18 nozzle design to spread the hydrogen and nitrogen exhaust over a wide area. It was determined that this would limit surface heating to no more than 1 degree Celsius and that no more than 1 mm of the surface material would be stripped away. The Viking 1 Lander touched down in western Chryse Planitia (named Gold Field) at 22.697° N latitude and 48.222° W longitude at a reference altitude of −2.69 km relative to a reference ellipsoid with an equatorial radius of 3397.2 km and a flatness of 0.0105 (22.480° N, 47.967° W planetographic) at 11:53:06 UT (16:13 local Mars time). Approximately 22 kg of propellants were left at landing.
Transmission of the first surface image began 25 seconds after landing. The seismometer failed to uncage, and a sampler arm locking pin was stuck and took 5 days to shake out. Otherwise, all experiments functioned nominally. The Viking 1 Lander was named the Thomas Mutch Memorial Station in January 1982 in honor of the leader of the Viking imaging team.
The lander operated for 2245 sols, until 13 November 1982, when a faulty command sent by ground control resulted in loss of contact.[1] The command was intended to uplink new battery charging software to improve the lander's deteriorating battery capacity, but it inadvertently overwrote data used by the antenna pointing software. Attempts to contact the lander during the next four months, based on the presumed antenna position, were unsuccessful.[2]
Test of General Relativity
General Relativity predicts "Gravitational Time Dilation". Scientists used the lander to observe such phenomena. Scientists sent radio signals to the lander on Mars, and instructed the lander to send back signals. Scientists then found that the time signals needed to make a round trip match the prediction of Gravitational Time Dilation.
See also
Notes
fa:وایکینگ ۱ it:Viking 1 nl:Viking 1 pl:Viking 1 fi:Viking 1