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Space Topics: Mars Reconnaissance Orbiter

Science Instruments

Click to enlarge > Mars orbiter comparison Mars Reconnaissance Orbiter (MRO) is considerably bigger than the other two orbiters active at Mars, Mars Global Surveyor (MGS) and 2001 Mars Odyssey. In particular, its High Gain Antenna -- the round radio dish -- is more than twice the diameter of the dishes of the other two spacecraft, permitting much higher data transmission rates from Mars to Earth. Credit: NASA / JPL

The spacecraft carries six instruments for probing the atmosphere, surface, and subsurface to characterize the planet and how it changed over time. Two additional scientific investigations will analyze the motion of the spacecraft in orbit to study the structure of the upper atmosphere and the Martian gravity field. MRO boasts the largest radio antenna ever sent to Mars, with a transmitter powered by large solar panels, to return the data home. MRO will be able to send home 10 times as much data per minute as any previous spacecraft.

High Resolution Imaging Science Experiment (HiRISE) is a color camera that will be able to capture images at resolutions of 25-50 centimeters (9.8-19.6) inches per pixel, higher than ever before. The largest diameter telescopic camera ever sent to another planet, HiRISE will be able to reveal rocks and layers as small as the width of an office desk, and will image more than 2% of Mars at resolutions of 1 meter (about 3 feet) per pixel or better. Stereo image pairs will be acquired over the highest-priority locations allowing for a relative vertical precision of 25 centimeters (9.8 inches). Only landers have previously been capable of such high resolution imaging. HiRISE's main function is to map areas on Mars to be explored later by landers.
HiRISE team website »
HiRISE "Zoomify" images »

Compact Reconnaissance Imaging Spectrometers for Mars (CRISM) will break down the visible and near-infrared light (with wavelengths from 400 to 4,050 nanometers) reflected from 18-meter-square (59-foot) pixels on the Martian surface into 560 colors. By analyzing the amount of each color represented in each pixel, scientists will be able to determine the minerals present on the surface, mapping the geology, composition and stratigraphy of surface features, and identifying water-related minerals in patches as small as a baseball infield. CRISM will also be used to examine seasonal variations in dust and ice in the atmosphere.
CRISM team website »

Context Imager (CTX) is a camera that will provide necessary wide-angle images to help place detailed HiRISE and CRISM measurements in their proper context on Mars. CTX will expand the present area of high-resolution coverage by a factor of 10, taking images that span 40 kilometers (25 miles) across at a resolution of 8 meters (26 feet) per pixel.
CTX team website »

Shallow Subsurface Radar (SHARAD) is a ground-penetrating radar supplied by the Italian Space Agency that will peer beneath the surface for layers of rock, ice and, if present, liquid water. SHARAD will send radio waves (15-25 MHz) toward the Martian surface and listen for the echoes. The radio frequency was selected so that strong reflections would occur from subsurface water, enabling SHARAD to map subsurface water deposits to a depth of about 1 kilometer (0.6 miles), a horizontal resolution of about 0.3 to 3 kilometers or 0.1 to 1.86 miles, and a vertical resolution of 15 meters (49 feet).
SHARAD team website »

Mars Climate Sounder (MCS) is a radiometer or atmospheric profiler that will use visible and infrared light to detect vertical variations of temperature, dust, and water vapor concentrations in the Martian atmosphere and study how they change over the course of the mission.
MCS team website »

Mars Color Imager (MARCI) is a camera that will produce daily global images of Mars in six different colors in order to follow changes in weather and ultimately provide global maps of Martian weather. 
MARCI team website »