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CURIOSITY, NASA's MARS SCIENCE LABORATORY




NASA's Mars Science Laboratory (MSL), named Curiosity, as seen fully deployed on Friday, Aug. 12, 2011 during a media photo opportunity inside Kennedy Space Center's Kennedy's Payload Hazardous Servicing Facility in Florida.Curiosity Showing Wheels and Mast Fully Deployed; The next time the Curiosity Mars Science Laboratory be in this same configuration — wheels deployed and remote sensing mast and instrument-tipped arm extended — will be after it is deposited on the surface of Mars in August 2012.




Curiosity Side View;At 10 feet (3 meters) long, Mars Science Laboratory has been likened to the size of a Mini Cooper. Curiosity is about twice as long and five times as heavy as NASA's twin Mars Exploration Rovers, Spirit and Opportunity, which launched in 2003 and are still on the Martian surface. Curiosity Mars Rover Showing Payload;Curiosity will carry the most advanced payload of scientific gear ever used on Mars' surface, a payload more than ten times as massive as those of earlier Mars rovers. MSL's assignment: Investigate whether conditions have been favorable for microbial life and for preserving clues in the rocks about possible past life.




Curosity Rover Right Side; The Curiosity Mars Science Laboratory (MSL) inherited many design elements from the earlier Mars Exploration Rovers Spirit and Opportunity, including six-wheel drive, a rocker-bogie suspension system and cameras mounted on a mast to help the mission's team on Earth select exploration targets and driving routes. Unlike earlier rovers, Curiosity carries equipment to gather samples of rocks and soil, process them and distribute them to onboard test chambers inside analytical instruments. Curiosity's "ChemCam"; Curiosity's "ChemCam" (protected here by the red cover) will fire a laser to analyze the composition of vaporized materials from areas smaller than 1 millimeter on the surface of rocks and soils. ChemCam will also use the laser to clear away dust from Martian rocks. Curosity's Antennas; Curiosity is equipped with both low-gain and high-gain antennas to serve as both its "voice" and its "ears." Not only will the rover be able to send messages directly to Earth, but it will also be able to uplink information to other spacecraft orbiting Mars, utilizing mainly the Mars Reconnaissance Orbiter as a messenger who can pass along news to Earth for the Mars-bound rover. The orbiter can also send messages to the rover. In this photo, the high-gain antenna is the hexagon-shape instrument in the center faced away from the camera. The low-gain antenna is the coffee-can shape instrument mounted on the platform at the rover's rear. Curosity's Antennas; Curiosity is equipped with both low-gain and high-gain antennas to serve as both its "voice" and its "ears. " Not only will the rover be able to send messages directly to Earth, but it will also be able to uplink information to other spacecraft orbiting Mars, utilizing mainly the Mars Reconnaissance Orbiter as a messenger who can pass along news to Earth for the Mars-bound rover. The orbiter can also send messages to the rover. In this photo, the high-gain antenna is the hexagon-shape instrument in the center faced away from the camera. The low-gain antenna is the coffee-can shape instrument mounted on the platform at the rover's rear.




Curiosity's "Hand"; At the end of Curiosity's seven-foot arm is a turret, shaped like a cross. This turret, a hand-like structure, holds various tools that can spin through a 350-degree turning range. At the tip of the arm is the turret structure on which five devices are mounted. Two of these devices are in-situ or contact instruments known as the Alpha Particle X-ray Spectrometer (APXS) and the Mars Hand Lens Imager. The remaining three devices are associated with sample acquisition and sample preparation functions. Curiosity's Mars Hand Lens Imager; Mounted at the end of Curiosity's arm, the Mars Hand Lens Imager (MAHLI) will take extreme close-up pictures of rocks, soil and, if present, ice, revealing details smaller than the width of a human hair. It will also be able to focus on hard-to-reach objects more than an arm's length away. Also mounted on the arm, the Alpha Particle X-ray Spectrometer (APXS) will determine the relative abundances of different elements in rocks and soils.




Curiosity's Wheels; The Mars Science Laboratory has six wheels, each with its own individual motor. The wheels are designed to roll the rover over obstacles up to 25 inches (65 centimeters) high and to travel distances up to 660 feet (200 meters) per day on the Martian terrain. Curiosity's Descent Stage; Curiosity will next be integrated with its descent stage, seen here, which will take it to the Martian surface. The rover will use a bold, new landing system. Like Viking, Pathfinder and the Mars Exploration Rovers that came before it, Mars Science Laboratory will be slowed by a large parachute. As the spacecraft loses speed, rockets will fire, controlling the spacecraft's descent until the rover separates from its final delivery system, the sky crane. Like a large crane on Earth, the sky crane touchdown system will lower the rover to a "soft landing" — wheels down-on the surface of Mars, ready to begin its mission.

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