Mars Reconnaissance Orbiter

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Conceptual drawing of Mars Reconnaissance Orbiter over Mars
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Conceptual drawing of Mars Reconnaissance Orbiter over Mars

NASA's Mars Reconnaissance Orbiter (MRO) is a multipurpose spacecraft, launched August 12, 2005 to advance human understanding of Mars through detailed observation, to examine potential landing sites for future surface missions, and to provide a high-data-rate communications relay for those missions. It is intended to orbit for four years, and to become Mars' fourth active artificial satellite (joining Mars Express, Mars Odyssey, and Mars Global Surveyor), and its sixth active probe (the satellites plus the two Mars Exploration Rovers), in a historic scientific focus on the Red Planet.

Contents

Overview

Launch of Atlas V carrying the Mars Reconnaissance Orbiter, 11:43:00 a.m UTC August 12, 2005
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Launch of Atlas V carrying the Mars Reconnaissance Orbiter, 11:43:00 a.m UTC August 12, 2005

MRO will conduct its science mission for an expected two-year period after aerobraking and technical checks are completed in (November 2006). After that, extended science and communications relay missions are expected.

The Mars Reconnaissance Orbiter will lay the groundwork for NASA's planned surface missions: a lander called Phoenix selected in a competition for a 2007 launch opportunity, and the Mars Science Laboratory, a highly capable rover being developed for a 2009 launch opportunity. The MRO's high-resolution instruments will help planners evaluate possible landing sites for these missions both in terms of science potential for further discoveries and in terms of landing risks. The MRO's communications capabilities will provide a critical transmission relay for the surface missions; MRO will even be able to provide critical navigation data to these probes during their landing. Also it may provide evidence which could help to uncover the reasons behind the failure of past Mars missions such as NASA's Mars Polar Lander, and the British Beagle lander.[1].

Active timeline

  • On April 30, 2005, the spacecraft was delivered to the launch site.
  • On August 9, 2005, the earliest launch opportunity on August 10 was postponed due to reliability concerns over the Atlas V's gyroscopes.
  • On August 10, 2005, concerns over the gyroscopes were resolved. Launch was scheduled for 7:50am EST August 11.
  • On August 11, 2005, concerns over weather cause a rescheduling of the launch to 9:00am EST August 11. Conflicting sensor readings during fueling of the Centaur stage's liquid hydrogen fuel tank could not be corrected in time, causing the launch to be scrubbed, rescheduling launch to 7:43am EST August 12.
  • At 7:43am EST August 12, 2005, MRO was launched. There were no significant anomalies reported during launch and deployment into interplanetary transfer orbit.
  • On August 15, 2005, The MARCI was tested and calibrated.
  • Mars Reconnaissance Orbiter was 100 million kilometers away from Mars at August 25, 2005 15:19:32 UTC.
  • On August 27, 2005, The first trajectory correction maneuver was executed on. The burn lasted 15 seconds and used the same main thrusters that are needed for the orbital insertion maneuver and they worked as expected. A velocity change of 7.8 meters per second was achieved.
  • On September 8, 2005, MRO completed calibration and testing of the HiRISE and CTX by taking pictures of the Moon from 10 million km away.

Mission timeline

MRO's transfer orbit and correction maneuvers
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MRO's transfer orbit and correction maneuvers
Artwork of MRO aerobraking
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Artwork of MRO aerobraking

Mars Reconnaissance Orbiter launched on August 12, 2005. Between August 10August 30, two-hour launch windows were available almost every day. It was launched from Space Launch Complex 41 at Cape Canaveral Air Force Station, aboard an Atlas V-401 rocket equipped with a Centaur upper stage. 56 minutes after launch the Centaur completed its burns placing MRO in interplanetary transfer orbit towards Mars.

MRO will cruise in interplanetary space for 7½ months before reaching Mars. Four trajectory correction maneuvers are planned for any need to correct the trajectory for proper orbital insertion upon reaching Mars. Also during the cruise testing and calibrations of most of the scientific instruments and experiments will be conducted.

Orbital insertion will occur as MRO approaches Mars for the first time in March of 2006, passing below the Martian southern hemisphere at an altitude of about 370–400 km (190 mi). All 6 of the orbiter’s main engines will burn for 27 minutes reducing the speed of the probe (relative to Mars at closest approach) from 2900 m/s (6500 mph) to 1900 m/s (4250 mph).

Orbital insertion will place the orbiter in a highly elliptical polar orbit. The periapsis, the closest point in the orbit to Mars will be 300 km (180 mi). The apoapsis, farthest away from Mars will be 45,000 km (28,000 mi). The orbital period will be 35 h.

Aerobraking will be conducted soon after orbital insertion to bring the orbiter to a lower, quicker orbit. Aerobraking cuts the fuel needed to reach the desired orbit roughly in half. Aerobraking will consist of three steps:

  1. MRO will drop the periapsis of its orbit to aerobraking altitude using its thrusters. Aerobraking altitude will be determined at that time depending on the thickness of the Martian atmosphere (Martian atmospheric pressure changes over the seasons on Mars). This step will take about 5 orbits or 1 Earth week.
  2. MRO will remain in aerobraking altitude for 5½ Earth months, or less than 500 orbits. Correct aerobraking altitude will have to be maintained with occasional corrections in periapsis altitude using its thrusters. Through aerobraking the apoapsis of the orbit will be reduced to 450 km (280 mi).
  3. To end aerobraking, the MRO will use its thrusters to move its periapsis out of the edge of the Martian atmosphere.

After aerobreaking another week or two will be spent to make additional adjustments in the orbit with thrusters. These corrections will likely occur before solar conjunction when Mars will appear to pass behind the Sun from Earth perspective, between October 7 and November 8, 2006. After this science operations will begin. Final or science operations orbit will be at approximately 255 km (160 statute miles) to 320 km (200 mi) above the Martian surface. After reaching science operational orbit the SHARAD will be deployed.

Science operations will be conducted for a nominal period of two Earth years. After this extended mission operations will include communication and navigation for Lander and rover probes.

Instrumentation

Expected data return from MRO
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Expected data return from MRO

The broad goals of the Mars Reconnaissance Orbiter are to search for evidence of water, and characterise the atmosphere and geology of Mars.

Six science instruments are included on the mission along with two "science-facility instruments", which use data from engineering subsystems to collect science data. Three technology experiments are also included to demonstrate new technologies for future missions. [2]

Science instrumentation

HiRISE

The High Resolution Imaging Science Experiment (HiRISE) camera will consist of a 0.5 meter reflecting telescope, the largest of any deep space mission, and has a resolution of 0.3 meter at a height of 300 km. It will image in three color bands, blue-green, red and near infrared.

For comparison purposes, satellite images of earth are generally available to a resolution of 0.1 meter, and satellite images on Google Maps are available to only 1 meter. [3]

To facilitate the mapping of potential landing sites, HiRISE can produce stereo pairs of images from which the topography can be measured to an accuracy of 0.25 meter.

CTX

The Context Imager (CTX) will provide grayscale images (500 nm to 800 nm) up to 40 km wide with a pixel resolution of 8 meters. The CTX is designed to operate in conjunction with the other two imaging devices to provide (as the name describes) context maps for the areas being observed.

The optics consist of a 350 mm focal length Maksutov Cassegrain telescope with a 5064 pixel wide line array CCD, similar to the HiRISE instrument. It has enough memory on board to record a 160 km long "track" before the image is loaded into the main computer with its 20GB storage. [4]

MARCI

Mars Color Imager
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Mars Color Imager

The Mars Color Imager (MARCI) will image Mars in 5 visible and 2 ultraviolet color bands. MARCI will produce a global map to help characterize daily, seasonal and year-to-year variations in Mars' climate, as well as providing daily weather reports for Mars.

CRISM

CRISM Instrument
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CRISM Instrument

The Compact Reconnaissance Imaging Spectrometers for Mars[5] (CRISM) instrument is an infrared/visible light spectrometer, to produce detailed maps of the mineralogy of the surface of Mars. It has a resolution of 18 meters at a 300 km orbit. It will operate from 400 nm to 4050 nm, measuring the spectrum in 560 channels, each 6.55 nm wide.

MCS

The Mars Climate Sounder (MCS) is a 9 channel spectrometer with one visible/near infrared channel (0.3 to 3.0 micrometers) and eight far infrared (12 to 50 micrometers). These channels are selected to measure temperature, pressure, water vapor and dust levels.

It will observe the atmosphere on the horizon of Mars (as viewed from MRO), breaking it up into vertical slices, and taking measurements within these slices at heights separated by about 5 km (3 miles).

These measurements will be assembled into daily global weather maps, showing the basic variables of Martian weather: temperature, pressure, humidity and dust density.

SHARAD

An artist's concept of MRO using SHARAD to "look" under the surface of Mars
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An artist's concept of MRO using SHARAD to "look" under the surface of Mars

The orbiter's Shallow Subsurface Radar (SHARAD) experiment is designed to probe the internal structure of Mars' polar ice caps, as well as to gather information planet-wide about underground layers of ice, rock and, perhaps, liquid water that might be accessible from the surface.

SHARAD operates between 10 and 30 MHz HF radio waves. It will have a vertical resolution as low as 7 m and penetration depth up to 1 km deep. It will have a horizontal resolution as low as 0.3 by 3 km. SHARAD is design to operate in conjunction with Mars Express's MARSIS radar which has lower resolution but much greater penetrating depth. Both instruments were made by the Italian Space Agency.[6]

Science facility

Gravity Field Investigation Package

Variations in the gravitational field of Mars can be deduced from variations in MRO's velocity. The velocity of the MRO will be detected using the doppler shift of the Orbiter's radio signal as received on Earth.

Atmospheric Structure Investigation Accelerometers

Sensitive accelerometers aboard the Orbiter will be used to deduce the in situ atmospheric density. It is unclear whether this experiment will only be conducted during aerobraking (when MRO is lower, in denser parts of the atmosphere) or throughout the mission.

Technology experiments

Electra

The Electra, an UHF antenna, is designed to communicate with spacecraft as they land on Mars, aiding pinpoint landings. [7]

Optical Navigation Camera

The Optical Navigation Camera will image Phobos and Deimos against background stars, to precisely determine MRO's orbit. This isn't mission critical, and has been included to test the system for future orbiting and landing spacecraft as a means of making more accurate orbital insertions and landings. [8]

Engineering data

Size comparison of MRO with predecessors
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Size comparison of MRO with predecessors

Structure

Workers at Lockheed Martin Space Systems in Denver, assembled the spacecraft structure and attached instruments. The instruments were built for it at the University of Arizona, Tucson; at Johns Hopkins University Applied Physics Laboratory, Laurel, Md.; at the Italian Space Agency, Rome; at Malin Space Science Systems, San Diego, Calif.; and at JPL.

The structure is made of mostly carbon composites, as well as aluminium honeycombed plates. The titanium fuel tank takes up most of the volume of the structure and provides a large percentage of structural load and integrity.

  • Total weight is less than 2,180 kg (4,806 lb)
  • Dry mass (without fuel) is less than 1,031 kg (2,273 lb)

Power systems

Mars Reconnaissance Orbiter's solar panel
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Mars Reconnaissance Orbiter's solar panel

Mars Reconnaissance Orbiter gets all of its electrical power from two solar panels. Each panel can move independently around two axes of movement (up-down, or left-right rotation). Each solar panel measures 5.35 × 2.53 m and on the front side, 9.5 m² (102 ft²) of the surface of each panel is covered with 3,744 individual photovoltaic cells. The very high efficiency triple junction solar cells are able to convert more than 26% of the Sun's energy directly into electricity, and are connected together so that the power they produce is at 32 V, which is the voltage that most devices on the spacecraft need in order to operate properly. At Mars, the two panels together produce 2,000 watts of power (6,000 watts in Earth orbit).

Mars Reconnaissance Orbiter uses two nickel metal hydride rechargeable batteries. The batteries are used as a power source when the solar panels are not facing the Sun (such as during launch, orbital insertion and aerobraking) or when Mars blocks out the Sun during a period in each orbit. Each battery has an energy storage capacity of 50 ampere-hours (180 kC). The spacecraft can't use this total capacity, because as the batteries discharge their voltage drops. If the voltage drops below about 20 volts the computer will stop functioning. So only about 40% of the battery capacity is planned to be used.

Electronic systems

Mars Reconnaissance Orbiter’s main computer is a 133 MHz, 10.4 million transistor, 32-bit, RAD750 processor. This processor is a radiation hardened version of a PowerPC750 or G3 processor, with a specially built motherboard. The RAD750 is a successor to the RAD6000. This processor may seem underpowered in comparison to a modern PC or Mac processor but it is extremely reliable and resilient, and can function in solar flare ravaged deep space.

Data is stored in a 160 Gbit (20 GB) flash memory module consisting of over 700 memory chips, each with 256 Mbit capacities. This memory capacity is not actually that large, considering how much data is going to be acquired; for example, a single image from HiRISE camera can be as big as 28 Gbit. [9]

The operating system software is VxWorks and has extensive fault protection protocols and monitoring.

Navigation systems

Navigation systems and sensor will provide data on position, course and attitude throughout the mission.

  • Sixteen Sun sensors (eight are backups) are placed around the spacecraft to measure the direction of the Sun relative to the spacecraft's orientation.
  • Two star trackers are used to provide full knowledge of the spacecraft orientation and attitude. Star trackers are simple digital cameras used to map the position of catalogued stars autonomously.
  • Two inertial measurement units are onboard (the second for backup purposes) provide data for any spacecraft movement. Each inertial measurement unit is a combination of three accelerometers and three ring-laser gyroscopes.

Telecommunications system

MRO High Gain Antenna installation
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MRO High Gain Antenna installation

The Telecom Subsystem uses a large antenna to transmit at the normal Deep Space communications frequency (X-band, 8 GHz), as well as demonstrating the use of the Ka-band, at 32 GHz, for high data rates. Maximum transmission speed from Mars is projected to be as high as 6 Mbit/s, a rate ten times higher than previous Mars orbiters. Two amplifiers for the X-band radio frequency transmit at 100 watts, the second is a backup. One amplifier Ka-band radio frequency transmits at 35 W. Two transponders are carried in total.

Two smaller low-gain antennas are present for lower-rate communication during emergencies and special events, such as launch and Mars Orbit Insertion. These antennas do not have focusing dishes and can transmit and receive from any direction.

Propulsion system

A 1175 L (310 US gallon) fuel tank filled with 1187 kg (2617 lb) of hydrazine monopropellant. Fuel pressure is regulated by adding pressurized helium gas from an external tank of helium. Seventy percent of the fuel will be used for orbital insertion alone.

A total of 20 rocket engine thrusters.

  • 6 large thrusters, mainly meant for orbital insertion. Each producing 170 N (38 lbf) of thrust; total 1,020 N (230 lbf) of thrust. (These thrusters were originally designed for the Mars_Surveyor_2001_Lander.)
  • 6 medium thrusters, for performing trajectory correction maneuvers and attitude control during orbit insertion, each producing 22 N (5 lbf) of thrust.
  • 8 small thrusters, for attitude control during normal and all operations, each producing 0.9 N (0.2 lbf)

Four momentum wheels are also used for precise attitude control, such as during high-resolution imaging, where the slightest unwanted motion could cause blurring of the image. Each wheel is used for one axis of motion. The fourth wheel is for backup, in case one of the other 3 wheels fails. Each wheel weighs 10 kg (22 lb), and can be spun as fast as 100 Hz (6000 rpm).

See also


References

  1. ^ "Mars Reconnaissance Orbiter Overview". Mars Reconnaissance Orbiter Website. URL accessed on February 11, 2005.
  2. ^ "Spacecraft Parts: Instruments". Mars Reconnaissance Orbiter Website. URL accessed on February, 2005.
  3. ^ "Google Earth FAQ" Google Earth Website.
  4. ^ "MRO Context Imager (CTX) Instrument Description". Malin Space Science Systems website. URL accessed on 17 August 2005.
  5. ^ "CRISM Instrument Overview". CRISM Instrument Website. URL accessed on April 2, 2005.
  6. ^ "Spacecraft Parts: SHARAD". Peer Review Papar website (PDF Format). URL accessed on August, 2005.
  7. ^ "Spacecraft Parts: Electra". Mars Reconnaissance Orbiter Website. URL accessed on February, 2005.
  8. ^ "Spacecraft Parts: Optical Navigation Camera". Mars Reconnaissance Orbiter Website. URL accessed on February, 2005.
  9. ^ "Spacecraft Parts: Command and Data-Handling Systems". Mars Reconnaissance Orbiter JPL Website. URL accessed on 17 August 2005.

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