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Mariner 6 and 7

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Mariner 6
Mariner 6 and 7
Mission typeMars flyby
OperatorNASA / JPL
COSPAR ID1969-014A
SATCAT no.3759
Mission duration1 year, 9 months and 28 days
Spacecraft properties
ManufacturerJet Propulsion Laboratory
Launch mass381 kg[1]
Power449 W
Start of mission
Launch dateFebruary 25, 1969, 01:29:02 (1969-02-25UTC01:29:02Z) UTC[2]
RocketAtlas SLV-3D Centaur-D1A
Launch siteCape Canaveral LC-36B
End of mission
DisposalDecommissioned
DeactivatedDecember 23, 1970 (1970-12-24)
Flyby of Mars
Closest approachJuly 31, 1969
Distance3,431 kilometers (2,132 mi)
Mariner 7 →
Mariner 7
Mission typeMars flyby
OperatorNASA / JPL
COSPAR ID1969-030A
SATCAT no.3837
Mission duration1 year, 9 months and 1 day
Spacecraft properties
ManufacturerJet Propulsion Laboratory
Launch mass381 kg[3]
Power449 W
Start of mission
Launch dateMarch 27, 1969, 22:22:00 (1969-03-27UTC22:22Z) UTC[4]
RocketAtlas SLV-3D Centaur-D1A
Launch siteCape Canaveral LC-36A
End of mission
DisposalDecommissioned
DeactivatedDecember 28, 1970 (1970-12-29)
Flyby of Mars
Closest approachAugust 5, 1969
Distance3,430 kilometers (2,130 mi)
← Mariner 6

Mariner 6 and Mariner 7 (Mariner Mars 69A and Mariner Mars 69B) were two uncrewed NASA robotic spacecraft that completed the first dual mission to Mars in 1969 as part of NASA's wider Mariner program. Mariner 6 was launched from Launch Complex 36B at Cape Canaveral Air Force Station[2] and Mariner 7 from Launch Complex 36A.[4] The two craft flew over the equator and south polar regions, analyzing the atmosphere and the surface with remote sensors, and recording and relaying hundreds of pictures. The mission's goals were to study the surface and atmosphere of Mars during close flybys, in order to establish the basis for future investigations, particularly those relevant to the search for extraterrestrial life, and to demonstrate and develop technologies required for future Mars missions. Mariner 6 also had the objective of providing experience and data which would be useful in programming the Mariner 7 encounter five days later.

Launch

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Three Mariner probes were constructed for the mission, with two intended to fly and one as a spare in the event of a mission failure. The spacecraft were shipped to Cape Canaveral with their Atlas-Centaur boosters in December 1968 – January 1969 to begin pre-launch checkouts and testing. On February 14, Mariner 6 was undergoing a simulated countdown on LC-36A, electrical power running, but no propellant loaded in the booster. During the test run, an electrical relay in the Atlas malfunctioned and opened two valves in the pneumatic system which allowed helium pressure gas to escape from the booster's balloon skin. The Atlas began to crumple over, however two pad technicians quickly activated a manual override switch to close the valves and pump helium back in. Although Mariner 6 and its Centaur stage had been saved, the Atlas had sustained structural damage and could not be reused, so they were removed from the booster and placed atop Mariner 7's launch vehicle on the adjacent LC-36B, while a different Atlas was used for Mariner 7.

NASA awarded the quick-thinking technicians, Bill McClure and Charles (Jack) Beverlin, an Exceptional Medal of Bravery for their courage in risking being crushed underneath the 124-foot (38 m) rocket. In 2014, an escarpment on Mars which NASA'S Opportunity rover had recently visited was named the McClure-Beverlin Ridge in honor of the pair, who had since died.[5][6][7]

Mariner 6 lifted off from LC-36B at Cape Canaveral on February 25, 1969, using the Atlas-Centaur AC-20 rocket, while Mariner 7 lifted off from LC-36A on March 27, using the Atlas-Centaur AC-19 rocket. The boost phase for both spacecraft went according to plan and no serious anomalies occurred with either launch vehicle. A minor LOX leak froze some telemetry probes in AC-20 which registered as a drop in sustainer engine fuel pressure; however, the engine performed normally through powered flight. In addition, BECO occurred a few seconds early due to a faulty cutoff switch, resulting in longer than intended burn time of the sustainer engine, but this had no serious effect on vehicle performance or the flight path. AC-20 was launched at a 108-degree azimuth.[8]

The Centaur stage on both flights was set up to perform a retrorocket maneuver after capsule separation. This served two purposes, firstly to prevent venting propellant from the spent Centaur from contacting the probe, secondly to put the vehicle on a trajectory that would send it into solar orbit and not impact the Martian surface, potentially contaminating the planet with Earth microbes.

Spaceflight

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On July 29, 1969, less than a week before closest approach, Jet Propulsion Laboratory (JPL) lost contact with Mariner 7. The center regained the signal via the backup low-gain antenna and regained use of the high gain antenna again shortly after Mariner 6's close encounter. Leaking gases from a battery (which later failed) were thought to have caused the anomaly.[4] Based on the observations that Mariner 6 made, Mariner 7 was reprogrammed in flight to take further observations of areas of interest and actually returned more pictures than Mariner 6, despite the battery's failure.[9]

Closest approach for Mariner 6 occurred July 31, 1969, at 05:19:07 UT at a distance of 3,431 kilometers (2,132 mi)[2] above the martian surface. Closest approach for Mariner 7 occurred August 5, 1969 at 05:00:49 UT[4] at a distance of 3,430 kilometers (2,130 mi) above the Martian surface. This was less than half of the distance used by Mariner 4 on the previous US Mars flyby mission.[9]

Both spacecraft are now defunct and in heliocentric orbits.[9]

Science data and findings

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Two full disc views of Mars from Mariner 7 as it approached, 1969
A close-up of the surface of Mars taken by Mariner 7

By chance, both spacecraft flew over cratered regions and missed both the giant northern volcanoes and the equatorial grand canyon discovered later. Their approach pictures did, however, photograph about 20 percent of the planet's surface,[9] showing the dark features long seen from Earth – in the past, these features had been mistaken for canals by some ground-based astronomers. When Mariner 7 flew over the Martian south pole on August 4, 1969, it sent back pictures of ice-filled craters and outlines of the south polar cap.[10] Despite the communication defect suffered by Mariner 7 earlier, these pictures were of better quality than what had been sent by its twin, Mariner 6, a few days earlier when it flew past the Martian equator.[11] In total, 201 photos were taken and transmitted back to Earth, adding more detail than the earlier mission, Mariner 4.[9] Both crafts also studied the atmosphere of Mars.

Coming a week after Apollo 11, Mariner 6 and 7's flyby of Mars received less than the normal amount of media coverage for a mission of this significance.

The ultraviolet spectrometer onboard Mariners 6 and 7 was constructed by the University of Colorado's Laboratory for Atmospheric and Space Physics (LASP).[12]

The engineering model of Mariners 6 and 7 still exists, and is owned by the Jet Propulsion Laboratory (JPL). It is on loan to LASP, and is on display in the lab's lobby.

Mariner 6 and 7 infrared radiometer observations helped to trigger a scientific revolution in Mars knowledge.[13][14] The Mariner 6 and 7 infrared radiometer results showed that the atmosphere of Mars is composed mostly of carbon dioxide (CO2), and they were also able to detect trace amounts of water on the surface of Mars.[13]

Spacecraft and subsystems

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Spacecraft and subsystems

The Mariner 6 and 7 spacecraft were identical, consisting of an octagonal magnesium frame base, 138.4 cm (54.5 in) diagonally and 45.7 cm (18.0 in) deep. A conical superstructure mounted on top of the frame held the high-gain 1 metre (3 ft 3 in) diameter parabolic antenna and four solar panels, each measuring 215 cm (85 in) x 90 cm (35 in), were affixed to the top corners of the frame. The tip-to-tip span of the deployed solar panels was 5.79 m (19.0 ft). A low-gain omnidirectional antenna was mounted on a 2.23 m (7 ft 4 in) high mast next to the high-gain antenna. Underneath the octagonal frame was a two-axis scan platform which held scientific instruments. Overall science instrument mass was 57.6 kg (127 lb). The total height of the spacecraft was 3.35 m (11.0 ft).

The spacecraft was attitude stabilized in three axes, referenced to the Sun and the star Canopus. It utilized 3 gyros, 2 sets of 6 nitrogen jets, which were mounted on the ends of the solar panels, a Canopus tracker, and two primary and four secondary Sun sensors. Propulsion was provided by a 223-newton rocket motor, mounted within the frame, which used the mono-propellant hydrazine. The nozzle, with 4-jet vane vector control, protruded from one wall of the octagonal structure. Power was supplied by 17,472 photovoltaic cells, covering an area of 7.7 square meters (83 sq ft) on the four solar panels. These could provide 800 watts of power near Earth, and 449 watts while on Mars. The maximum power requirement was 380 watts, once Mars was reached. A 1200 watt-hour, rechargeable, silver-zinc battery was used to provide backup power. Thermal control was achieved through the use of adjustable louvers on the sides of the main compartment.

Three telemetry channels were available for telecommunications. Channel A carried engineering data at 8⅓ or 33⅓ bit/s, channel B carried scientific data at 66⅔ or 270 bit/s and channel C carried science data at 16,200 bit/s. Communications were accomplished through the high- and low-gain antennas, via dual S-band traveling wave tube amplifiers, operating at 10 or 20 watts, for transmission. The design also included a single receiver. An analog tape recorder, with a capacity of 195 million bits, could store television images for subsequent transmission. Other science data was stored on a digital recorder. The command system, consisting of a central computer and sequencer (CC&S), was designed to actuate specific events at precise times. The CC&S was programmed with both a standard mission and a conservative backup mission before launch, but could be commanded and reprogrammed in flight. It could perform 53 direct commands, 5 control commands, and 4 quantitative commands.

Instrumentation

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  1. IR Spectrometer
  2. Two-Channel IR Radiometer Mars Surface Temperature
  3. UV Spectrometer
  4. S-Band Occultation
  5. Thermal Control Flux Monitor (Conical Radiometer)
  6. Mars TV Camera
  7. Celestial Mechanics
  8. General Relativity

See also

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References

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  1. ^ "Mariner 6 - NASA Science". science.nasa.gov. NASA. Retrieved November 30, 2022.
  2. ^ a b c "Mariner 6". nssdc.gsfc.nasa.gov. NASA. Retrieved December 28, 2011.
  3. ^ "Mariner 7 - NASA Science". science.nasa.gov. NASA. Retrieved November 30, 2022.
  4. ^ a b c d "Mariner 7". nssdc.gsfc.nasa.gov. NASA. Retrieved December 28, 2011.
  5. ^ "Opportunity's Southward View of 'McClure-Beverlin Escarpment'". NASA / JPL. 2014.
  6. ^ "Billy McClure obituary". 508th Parachute Infantry Regiment (veterans' association). 2009. Archived from the original on November 24, 2015.
  7. ^ "Charles Beverlin obituary". Dignity Memorial. 2013.
  8. ^ Mariner-Mars 1969: A Preliminary Report. NASA. 1969. p. 21. SP-225.
  9. ^ a b c d e Rod Pyle (2012). Destination Mars: New Explorations of the Red Planet. Prometheus Books. pp. 61–66. ISBN 978-1-61614-589-7.
  10. ^ "From the Archives (August 6, 1969): Ice-filled craters on Mars". The Hindu. August 6, 2019. ISSN 0971-751X. Retrieved August 10, 2019.
  11. ^ Walter Sullivan (August 6, 1969). "Mariner 7 Sends Sharpest Mars Pictures; Mariner 7 Sends Sharpest Mars Photos So Far". The New York Times. ISSN 0362-4331. Retrieved August 10, 2019.
  12. ^ J. B. Pearce; K. A. Gause; E. F. Mackey; et al. (April 1, 1971). "Mariner 6 and 7 Ultraviolet Spectrometers". Applied Optics. 10 (4): 805–812. Bibcode:1971ApOpt..10..805P. doi:10.1364/ao.10.000805. ISSN 0003-6935. PMID 20094543.
  13. ^ a b "Infrared Spectrometer and the Exploration of Mars". American Chemical Society. Retrieved August 10, 2019.
  14. ^ S. C. Chase (March 1, 1969). "Infrared radiometer for the 1969 mariner mission to Mars". Applied Optics. 8 (3): 639. Bibcode:1969ApOpt...8..639C. doi:10.1364/AO.8.000639. ISSN 1559-128X. PMID 20072273.
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