Mars Climate Orbiter
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The Mars Climate Orbiter (formerly the Mars Surveyor '98 Orbiter) was one of two spacecraft in the Mars Surveyor '98 program, the other being the Mars Polar Lander (formerly the Mars Surveyor '98 Lander). The two missions were to study the Martian weather, climate, and water and carbon dioxide budget, in order to understand the reservoirs, behavior, and atmospheric role of volatiles and to search for evidence of long-term and episodic climate changes.
The Mars Climate Orbiter was destroyed when a navigation error caused the spacecraft to miss its intended 140–150 km altitude above Mars during orbit insertion, instead entering the Martian atmosphere at about 57 km. The spacecraft was destroyed by atmospheric stresses and friction at this low altitude. A review board found that some data was calculated on the ground in Imperial units (pound-seconds) and reported that way to the navigation team, who were expecting the data in metric units (newton-seconds). [1] The systems aboard the spacecraft were not able to reconcile the two systems of measurement, resulting in the navigation error.
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[edit] Science objectives
The Orbiter had as its primary science objectives to:
- monitor the daily weather and atmospheric conditions
- record changes on the martian surface due to wind and other atmospheric effects
- determine temperature profiles of the atmosphere
- monitor the water vapor and dust content of the atmosphere
- look for evidence of past climate change.
Specifically it was to observe and study dust storms, weather systems, clouds and dust hazes, ozone, distribution and transport of dust and water, the effects of topography on atmospheric circulation, atmospheric response to solar heating, and surface features, wind streaks, erosion, and color changes. The orbiter was to use two instruments to carry out these investigations. The Mars Climate Orbiter Color Imager (MARCI) was to acquire daily atmospheric weather images and high resolution surface images and the Pressure Modulated Infrared Radiometer (PMIRR) was to allow measurement of the atmospheric temperature, water vapor abundance, and dust concentration. The orbiter was also to serve as a data relay satellite for the Mars Polar Lander and other future NASA and international lander missions to Mars.
[edit] Spacecraft and subsystems
The Mars Climate Orbiter was a box-shaped spacecraft about 2.1 m high, 1.6 m wide, and 2 m deep, consisting of stacked propulsion and equipment modules. The total spacecraft launch mass of 629 kg includes 291 kg of propellant. An 11 square meter solar array wing, measuring 5.5 m tip-to-tip, is attached by 2-axis gimbal to one side and a 1.3 m diameter high-gain dish antenna is attached by 2-axis gimbal to a mast at the top of the propulsion module. The MARCI and PMIRR instruments, as well as a UHF antenna and battery enclosure, are mounted to the bottom of the equipment module.
Propulsion was achieved via a 640 N bipropellant (hydrazine/nitrogen tetroxide) main engine, mounted with the propellant tanks in the propulsion module, and hydrazine thrusters. The orbiter is 3-axis stabilized. Attitude control and maneuvering capability is provided by four 7 N thrusters (pitch/yaw) and four 0.3 N thrusters (roll) in combination with reaction wheels. Attitude was determined using an inertial measurement unit, a star tracker, and analog Sun sensors with knowledge of 25 mrad and stability of 1.5 mrad/(1 s) and 3 mrad/(3 s).
Spacecraft power was provided by 3 panels of GaAs/Ge solar cells on the 5.5 meter long single-wing solar array which provide 1000 W of power at Earth and 500 W at Mars. Power is stored in nickel metal hydride (NiMH) common pressure vessel batteries. Thermal control is achieved through a combination of louvers, MLI, Kapton, paints, radiators and heater circuits. Communications with Earth were in X band using Cassini Deep Space Transponders and 15 W RF solid state power amplifiers through the 1.3 m high gain antenna for both uplink and downlink, a medium gain transmitting antenna, and a low-gain receiving antenna. A 10 W UHF system was to be used for 2-way communications with the Mars Polar Lander. A RAD6000 processor was used for on-board command and data handling.
[edit] Mission profile
Mars Climate Orbiter was launched on a Delta 7425 (a Delta II Lite launch vehicle with four strap-on solid rocket boosters and a Star 48 (PAM-D) third stage). Launch was at 18:45:51 UT (1:45:51 p.m. EST) on December 11, 1998 from Pad A of Launch Complex 17 at Cape Canaveral Air Station, Florida. After a brief cruise in Earth orbit, the Delta II 3rd stage put the spacecraft into trans-Mars trajectory and about 15 days after launch the largest trajectory correction maneuver (TCM) was executed using the hydrazine thrusters. During cruise to Mars, three additional TCM's using the hydrazine thrusters were performed on March 4, July 25, and September 15, 1999.
The spacecraft reached Mars and executed a 16 minute 23 second orbit insertion main engine burn on September 23, 1999 at 09:01 UT (5:01 a.m. EDT) Earth received time (ERT, signal travel time from Mars will be 10 minutes 55 seconds). The spacecraft passed behind Mars at 09:06 UT ERT and was to re-emerge and establish radio contact with Earth at 09:27 UT ERT, 10 minutes after the burn was completed. However, contact was never re-established and no signal was ever received from the spacecraft. Findings of the failure review board indicate that a navigation error resulted from some spacecraft data being reported in Imperial units instead of metric. This caused the spacecraft to miss its intended 140–150 km altitude above Mars during orbit insertion, instead entering the martian atmosphere at about 57 km. The spacecraft would have been destroyed by atmospheric stresses and friction at this low altitude.
The burn would have slowed the spacecraft and put it into a 14 hour elliptical (~150 × 21 000 km) capture orbit. The orbiter was to begin aerobraking, using the solar panel to provide resistance and continue until a 90 × 405 km orbit was achieved, nominally on 22 November 1999, with periapsis at 89 N. The hydrazine thrusters would be used to change the orbit to a 2-hour, 421 km near-circular polar science mapping orbit on 1 December 1999. The orbit was to be nearly Sun-synchronous, crossing the daytime equator at about 4:30 p.m. local time. The first phase of the mission was to support the Mars Polar Lander from its landing on Mars on 3 December 1999 to the end of the lander primary mission on 29 February 2000. The orbiter would pass over the lander site 10 times per martian day for 5 to 6 minutes each time, communicating via the UHF 2-way relay link at 128 kbit/s. Mars science operations and mapping, involving operation of the MARCI and PMIRR, would initiate on 3 March 2000 and continue for one martian year (687 days). At the end of the mapping mission on 15 January 2002, the orbiter was to be placed in a stable orbit and function as a UHF relay for the Mars 2001 mission.
[edit] The metric mixup
The Mars Climate Orbiter’s reaction wheels were kept within their linear (unsaturated) range through thruster firings in a procedure called Angular Momentum Desaturation (AMD). When an AMD event occurred, relevant spacecraft data was telemetered to the ground, processed, and placed into a file called the AMD file. The JPL operations navigation team used data derived from the AMD file to model the forces on the spacecraft resulting from these specific thruster firings. Modeling of these small forces is critical for accurately determining the spacecraft’s trajectory. Immediately after the thruster firing, the velocity change ("delta-V") is computed using the firing time for each of the thrusters, and an impulse bit, which models each thruster's performance. The calculation of the thruster performance is carried out both on-board the spacecraft and on ground support computers. The flight software installed on the spacecraft correctly computed the velocity change and transmitted it to earth. The ground software, however, was originally written for the Mars Global Surveyor (MGS) mission, and the MGS flight software did not compute nor transmit velocity change information. The ground software, then, discarded the transmitted velocity change and recomputed it. Since the Mars Climate orbiter used a differently-sized thruster than Mars Global Surveyor, an update to the thruster equation in the ground software was necessary. The conversion factor from pound-seconds to newton-seconds was buried in the original equation and not immediately identifiable, and so it was not included in the updated equation. Thus, the ground software reported calculated "impulse bits" which were a factor of 4.45 too large (1 pound force = 4.45 newtons). Subsequent processing of the calculated impulse bit values from the AMD file by the navigation software underestimated the effect of the thruster firings on the spacecraft trajectory by this factor.
This mixup was exacerbated by two factors:
- The lack of end-to-end testing of the AMD data flow before launch
- The lack of an independent navigation algorithm to cross-check the AMD-based algorithm in flight
Both had been performed on previous missions, but deleted from the MCO plan due to budget cuts.
[edit] See also
[edit] References
- Isbell, D., M. Hardin, and J. Underwood, Mars Climate Orbiter Team Finds Likely Cause of Loss. NASA news release, September, 1999. 30: p. 1999.
- Euler, E.E., Jolly, S.D., and Curtis, H.H. "The Failures of the Mars Climate Orbiter and Mars Polar Lander: A Perspective from the People Involved." Proceedings of Guidance and Control 2001, American Astronautical Society, paper AAS 01-074, 2001.
- Mars Climate Orbiter Mishap Investigation Board Phase I Report. November 10, 1999.
- Mars Surveyor Project Readiness Review, Part I. August 26-27, 1998. JPL D-16057-01B, page 65.
[edit] External links
- http://nssdc.gsfc.nasa.gov/database/MasterCatalog?sc=1998-073A
- http://www.jamesoberg.com/mars/loss.html Why "metric-mixup" was just the tip of the problem
Failed & Cancelled missions to the Planet Mars | |
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Failed: | Marsnik program | Sputnik 22 | Mars 1 | Sputnik 24 | Mariner 3 | Zond 2 | Mars 1969A | Mars 1969B | Mariner 8 | Cosmos 419 | Mars 6 | Mars 7 | Phobos 1 | Mars Observer | Mars 96 | Nozomi | Mars Climate Orbiter | Mars Polar Lander | Deep Space 2 | Beagle 2 |
Cancelled: | Voyager | Mars Surveyor 2001 Lander | NetLander | Mars Telecommunications Orbiter |