Mars Climate Orbiter

Mars Climate Orbiter

Artist's conception of the Mars Climate Orbiter
Mission type Mars orbiter
Operator NASA / JPL
COSPAR ID 1998-073A
Website mars.jpl.nasa.gov/msp98/orbiter/
Mission duration 286 days
Mission failure
Spacecraft properties
Manufacturer Lockheed Martin
Launch mass 338 kilograms (745 lb)
Power 500 watts
Start of mission
Launch date 11 December 1998, 18:45:51 (1998-12-11UTC18:45:51Z) UTC
Rocket Delta II 7425
Launch site Cape Canaveral SLC-17A
End of mission
Last contact 23 September 1999 09:06:00 (1999-09-23UTC09:07Z) UTC
Decay date 23 September 1999
Unintentionally deorbited
Orbital parameters
Reference system Areocentric
Epoch Planned

The Mars Climate Orbiter (formerly the Mars Surveyor '98 Orbiter) was a 338-kilogram (745 lb) robotic space probe launched by NASA on December 11, 1998 to study the Martian climate, Martian atmosphere, and surface changes and to act as the communications relay in the Mars Surveyor '98 program for Mars Polar Lander. However, on September 23, 1999, communication with the spacecraft was lost as the spacecraft went into orbital insertion, due to ground-based computer software which produced output in non-SI units of pound (force)-seconds (lbf·s) instead of the SI units of newton-seconds (N·s) specified in the contract between NASA and Lockheed. The spacecraft encountered Mars on a trajectory that brought it too close to the planet, causing it to pass through the upper atmosphere and disintegrate.[1][2]

Mission background

History

After the loss of Mars Observer and the onset of the rising costs associated with the future International Space Station, NASA began seeking less expensive, smaller probes for scientific interplanetary missions. In 1994, the Panel on Small Spacecraft Technology was established to set guidelines for future miniature spacecraft. The panel determined that the new line of miniature spacecraft should be under 1000 kilograms with highly focused instrumentation.[3] In 1995, a new Mars Surveyor program began as a set of missions designed with limited objectives, low costs, and frequent launches. The first mission in the new program was Mars Global Surveyor, launched in 1996 to map Mars and provide geologic data using instruments intended for Mars Observer.[4] Following Mars Global Surveyor, Mars Climate Orbiter carried two instruments, one originally intended for Mars Observer, to study the climate and weather of Mars.

The primary science objectives of the mission included:[5]

Spacecraft design

The Mars Climate Orbiter bus measured 2.1 meters tall, 1.6 meters wide and 2 meters deep. The internal structure was largely constructed with graphite composite/aluminum honeycomb supports, a design found in many commercial airplanes. With the exception of the scientific instruments, battery and main engine, the spacecraft included dual redundancy on the most important systems.[5][6]

The spacecraft was 3-axis stabilized and included eight hydrazine monopropellant thrusters (four 22N thrusters to perform trajectory corrections; four 0.9N thrusters to control attitude). Orientation of the spacecraft was determined by a star tracker, two Sun sensors and two inertial measurement units. Orientation was controlled by firing the thrusters or using three reaction wheels. To perform the Mars orbital insertion maneuver, the spacecraft also included a LEROS 1B main engine rocket,[7] providing 640N of thrust by burning hydrazine fuel with nitrogen tetroxide (NTO) oxidizer.[5][6]

The spacecraft included a 1.3-meter high-gain antenna to transceive data with the Deep Space Network over the x-band. The radio transponder designed for the Cassini–Huygens mission was used as a cost-saving measure. It also included a two-way UHF radio frequency system to relay communications with Mars Polar Lander upon an expected landing on December 3, 1999.[5][6][8]

The space probe was powered with a 3-panel solar array, providing an average of 500 W at Mars. Deployed, the solar array measured 5.5 meters in length. Power was stored in 12-cell, 16-amp-hour Nickel hydrogen batteries. The batteries were intended to be recharged when the solar array received sunlight and power the spacecraft as it passed into the shadow of Mars. When entering into orbit around Mars, the solar array was to be utilized in the aerobraking maneuver, to slow the spacecraft until a circular orbit was achieved. The design was largely adapted from guidelines from the Small Spacecraft Technology Initiative outlined in the book, Technology for Small Spacecraft.[5][6][9]

In an effort to simplify previous implementations of computers on spacecraft, Mars Climate Orbiter featured a single computer using an IBM RAD6000 processor capable of 5MHz, 10MHz and 20MHz operations. Data storage was to be maintained on 128MB of random-access memory (RAM) and 18MB of flash memory. The flash memory was intended to be used for highly important data, including triplicate copies of the flight system software.[5]

The cost of the mission was $327.6 million total for the orbiter and lander, comprising $193.1 million for spacecraft development, $91.7 million for launching it, and $42.8 million for mission operations.[10]

Scientific instruments

The Pressure Modulated Infrared Radiometer (PMIRR) uses narrow-band radiometric channels and two pressure modulation cells to measure atmospheric and surface emissions in the thermal infrared and a visible channel to measure dust particles and condensates in the atmosphere and on the surface at varying longitudes and seasons.[11] Its principal investigator was Daniel McCleese at JPL/CALTECH. Similar objectives were later achieved with Mars Climate Sounder on board Mars Reconnaissance Orbiter. Its objectives:[12]

The Mars Color Imager (MARCI) is a two-camera (medium-angle/wide-angle) imaging system designed to obtain pictures of the Martian surface and atmosphere. Under proper conditions, resolutions up to 1 kilometer (0.6 miles) are possible.[13][14] The principal investigator on this project was Michael Malin at Malin Space Science Systems and the project was reincorporated on Mars Reconnaissance Orbiter. Its objectives:[13]

Camera Filters[13]
Filter Name Angle Wavelength Sensitivity
UV1 Wide 280 nm N/A
UV2 Wide 315 nm N/A
MA1 Medium 445 nm
WA1 Wide 453 nm
MA2 Medium 501 nm
WA2 Wide 561 nm
MA3 Medium 562 nm
WA3 Wide 614 nm
WA4 Wide 636 nm
MA4 Medium 639 nm
WA5 Wide 765 nm
MA5 Medium 767 nm
MA6 Medium 829 nm N/A
MA7 Medium 903 nm N/A
MA8 Medium 1002 nm N/A
Images of the spacecraft
Diagram of Mars Cliamte Orbiter
Diagram of Mars Climate Orbiter. 
Mars Climate Orbiter during assembly
Mars Climate Orbiter during assembly. 
Mars Climate Orbiter undergoing acoustic testing
Mars Climate Orbiter undergoing acoustic testing. 
Mars Climate Orbiter awaiting a spin test in November 1998
Mars Climate Orbiter awaiting a spin test in November 1998. 

Mission profile

Timeline of travel
Date Time (UTC) Event
11 Dec 1998 18:45:51 Spacecraft launched
23 Sep 1999 08:41:00 Insertion begins. Orbiter stows solar array.
08:50:00 Orbiter turns to correct orientation to begin main engine burn.
08:56:00 Orbiter fires pyrotechnic devices which open valves to begin pressurizing the fuel and oxidizer tanks.
09:00:46 Main engine burn starts; expected to fire for 16 minutes 23 seconds.
09:04:52 Communication with spacecraft lost
09:06:00 Orbiter expected to enter Mars occultation, out of radio contact with Earth.[n 1]
09:27:00 Expected to exit Mars occultation.[n 1]
25 Sep 1999 Mission declared a loss. No further attempts to contact.

Launch and trajectory

The Mars Climate Orbiter probe was launched on December 11, 1998 at 18:45:51 UTC by the National Aeronautics and Space Administration from Space Launch Complex 17A at the Cape Canaveral Air Force Station in Florida, aboard a Delta II 7425 launch vehicle. The complete burn sequence lasted 42 minutes bringing the spacecraft into a Hohmann transfer orbit, with a final velocity of 5.5 km/s relative to Mars, and sending the probe into a 669 million kilometer trajectory.[5][8] At launch, Mars Climate Orbiter weighed 638 kilograms (1,418 pounds) including propellant.[15]

Encounter with Mars

Mars Climate Orbiter began the planned orbital insertion maneuver on September 23, 1999 at 09:00:46 UTC. Mars Climate Orbiter went out of radio contact when the spacecraft passed behind Mars at 09:04:52 UTC, 49 seconds earlier than expected, and communication was never reestablished. Due to complications arising from human error, the spacecraft encountered Mars at a lower than anticipated altitude and disintegrated due to atmospheric stresses. Mars Reconnaissance Orbiter has since completed most of the intended objectives for this mission.

Cause of failure

On November 10, 1999, the Mars Climate Orbiter Mishap Investigation Board released a Phase I report, detailing the suspected issues encountered with the loss of the spacecraft. Previously, on September 8, 1999, Trajectory Correction Maneuver-4 was computed and then executed on September 15, 1999. It was intended to place the spacecraft at an optimal position for an orbital insertion maneuver that would bring the spacecraft around Mars at an altitude of 226 km (140 mi) on September 23, 1999. However, during the week between TCM-4 and the orbital insertion maneuver, the navigation team indicated the altitude may be much lower than intended at 150 to 170 km (93 to 106 mi). Twenty-four hours prior to orbital insertion, calculations placed the orbiter at an altitude of 110 kilometers; 80 kilometers is the minimum altitude that Mars Climate Orbiter was thought to be capable of surviving during this maneuver. Post-failure calculations showed that the spacecraft was on a trajectory that would have taken the orbiter within 57 kilometers of the surface, where the spacecraft likely disintegrated because of atmospheric stresses.

The primary cause of this discrepancy was that one piece of ground software supplied by Lockheed Martin produced results in a United States customary unit, contrary to its Software Interface Specification (SIS), while a second system, supplied by NASA, expected those results to be in SI units, in accordance with the SIS. Specifically, software that calculated the total impulse produced by thruster firings calculated results in pound-seconds. The trajectory calculation software then used these results - expected to be in newton-seconds - to update the predicted position of the spacecraft.[16]

The discrepancy between calculated and measured position, resulting in the discrepancy between desired and actual orbit insertion altitude, had been noticed earlier by at least two navigators, whose concerns were dismissed. A meeting of trajectory software engineers, trajectory software operators (navigators), propulsion engineers and managers, was convened to consider the possibility of executing Trajectory Correction Maneuver-5, which was in the schedule. Attendees of the meeting recall an agreement to conduct TCM-5, but it was ultimately not done.[17]

See also

Notes

  1. 1 2 Planned but unaccounted for event.

References

  1. Stephenson, Arthur G.; LaPiana, Lia S.; Mulville, Daniel R.; Rutledge, Peter J.; Bauer, Frank H.; Folta, David; Dukeman, Greg A.; Sackheim, Robert; Norvig, Peter (November 10, 1999). Mars Climate Orbiter Mishap Investigation Board Phase I Report (PDF). NASA.
  2. "Metric mishap caused loss of NASA orbiter". CNN. September 30, 1999. Retrieved March 21, 2016.
  3. Panel on Small Spacecraft Technology, National Research Council (1994). Technology for Small Spacecraft. Washington D.C.: National Academy Press. ISBN 0-309-05075-8. Retrieved January 13, 2011.
  4. Committee on Planetary and Lunar Exploration, Commission on Physical Sciences, Mathematics, and Applications, National Research Council (1995). The Role of Small Missions in Planetary and Lunar Exploration. Washington D.C.: National Academies Press. Retrieved January 13, 2011.
  5. 1 2 3 4 5 6 7 "Mars Climate Orbiter Arrival Press Kit" (PDF) (Press release). NASA / JPL. September 1999. Retrieved January 13, 2011.
  6. 1 2 3 4 "Mars Climate Orbiter Flight System Description". NASA / JPL. 1998. Retrieved January 13, 2011.
  7. LEROS 1B
  8. 1 2 "1998 Mars Missions Press Kit" (PDF) (Press release). NASA / JPL. December 1998. Retrieved January 13, 2011.
  9. Panel on Small Spacecraft Technology, National Research Council (1994). Technology for Small Spacecraft. Washington D.C.: National Academy Press. pp. 121–123. ISBN 0-309-05075-8. Retrieved January 13, 2011.
  10. "Mars Climate Orbiter Fact Sheet". NASA-JPL. Archived from the original on October 3, 2012.
  11. "Pressure Modulated Infrared Radiometer (PMIRR)". NASA / National Space Science Data Center. Retrieved February 19, 2011.
  12. Albee, Arden L. (1988). "Workshop on Mars Sample Return Science". Lunar and Planetary Inst.: 25–29. Bibcode:1988msrs.work...25A. Retrieved March 20, 2011.
  13. 1 2 3 Malin, M.C.; Bell (III), J.F.; Calvin, W.M.; Caplinger, M.A.; Clancy, R.T.; Harberle, R.M.; James, P.B.; Lee, S.W.; Ravine, M.A.; Thomas, P.; Wolff, M.J. (2001). "Mars Color Imager (MARCI) on the Mars Climate Orbiter" (PDF). Journal of Geophysical Research. 106 (E8): 17,651–17,672. Bibcode:2001JGR...10617651M. doi:10.1029/1999JE001145. Retrieved January 13, 2011.
  14. "Mars Color Imager (MARCI)". NASA / National Space Science Data Center. Retrieved February 19, 2011.
  15. "1998 MARS CLIMATE ORBITER ARRIVES AT NASA'S KENNEDY SPACE CENTER FOR FINAL LAUNCH PREPARATIONS" (Press release). NASA MEDIA RELATIONS OFFICE. September 14, 1998. Retrieved January 3, 2011.
  16. "Mars Climate Orbiter Mishap Investigation Board Phase I Report" (PDF) (Press release). NASA. November 10, 1999. Retrieved February 22, 2013.
  17. Oberg, James (December 1, 1999). "Why the Mars Probe went off course". IEEE Spectrum. IEEE. Retrieved 13 July 2016.

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