Curiosity Rover’s arrival on Mars revives interest in space innovation

Curiosity Rover’s arrival on Mars revives interest in space innovation View Photo Gallery — Rover Curiosity explores Mars: NASA’s rover Curiosity is rolling about deep in a Martian crater after a picture-perfect descent and landing, beginning what promises to be one of the most ambitious planetary missions in history. Text Size PrintE-mailReprints By Marjorie Censer, Monday, August 27, 4:58 AM The computer selected to power Curiosity — the Mars rover hailed as proof America can still make big technological strides — wasn’t the cutting-edge device one might expect. ¶In fact, it was more of a workhorse, a single-board computer that dates back to 2000, traveled on its first mission in 2005 and now runs some 30 satellites. Another 50 will be carrying the technology within about two years.¶Yet the RAD750, built in Manassas by BAE Systems, is precisely the sort of component that allowed Washington’s government contracting community to do what it does best: turn tried-and-true technology into a sophisticated explorer that will now spend the next two years on the Red Planet conducting groundbreaking experiments. The innovation is in the integration. 0 Comments Weigh InCorrections? Personal Post Video The Post’s Marc Kaufman, author of “Mars Landing 2012: Inside NASA’s Curiosity Mission,” explains the importance of the Curiosity mission, which is being hailed “the mission of the decade” by NASA’s chief scientist. Video The NASA rover Curiosity made its first test drive Wednesday on Mars. The rover moved forward about 15 feet, rotated to a right angle and reversed a short distance. The RAD750, measuring just 3.5-by-6 inches across its face, is the kind of part that makes the sum all the more powerful. NASA’s jet propulsion laboratory “selected a standard, known, solid design that they could count on,” said Vic Scuderi, manager of satellite electronics at BAE. “You don’t want a $2.5 billion mission suddenly dependent on ... some new fancy technique.” Lots of Washington area shops contributed technology to create Curiosity. Its landing was the equivalent of their London Olympics, the culmination of years of largely anonymous work all packed into “seven minutes of terror” — the term used to describe the time it took the Curiosity to enter the atmosphere around Mars, descend and then make its difficult landing on the planet. “It’s that coming together part ... where easy, simple, I-wish-I-hadn’t-done-that kind of mistakes can happen,” Scuderi said. Tried and true Jim Armor, vice president of strategy and business development for ATK’s Beltsville-based space systems division, was up late watching the landing from his home. The company developed a range of spaceflight hardware, including the deployment mechanism for a remote sensing mast that allows the Curiosity to use several cameras. The deployment mechanism is best thought of as a complex knuckle that allows the Curiosity to lift its equivalent of a finger — in this case, an arm equipped with cameras. “We’ve done much more complicated ones than this, but this one had to be fairly rugged [and] designed to work in a dusty environment,” Armor said. The company also helped NASA’s jet propulsion laboratory design one of the Curiosity’s scientific instruments, known as the chemistry/mineralogy — or CheMin — instrument, which analyzes the rocks and soil on Mars. Both McLean-based ITT Exelis and Bethesda-based Lockheed Martin saw the Mars mission use some of their time-tested technology. Exelis operates and maintains multiple antennae at Goldstone Deep Space Communications Complex, the California home to an antenna about the size of a football field that communicates with multiple spacecraft, including the Voyager spacecraft that launched almost three decades ago. It and another antenna also helped the Mars rover during its final approach into Mars’s atmosphere.