November 9, 2005
For Immediate Release
The Johns Hopkins University
Applied Physics Laboratory
Phone: 240-228-6268 or
NASA Goddard Space Flight Center
The first spacecraft designed to capture 3-D "stereo" views of the sun and solar wind were shipped today from The Johns Hopkins University Applied Physics Laboratory (APL) in Laurel, Md., to NASA Goddard Space Flight Center (GSFC) in Greenbelt, Md., for their next round of pre-launch tests.
The nearly identical twin STEREO (Solar TErrestrial RElations Observatory) observatories, designed and built by APL, were recently tested in APL's vibration lab where engineers used a large shake table to check the structural integrity of the twin spacecraft. These tests simulate the ride into space the observatories will encounter aboard a Delta II launch vehicle from Cape Canaveral Air Force Station, Fla., where they're scheduled for launch in spring 2006.
"Delivery of the twin observatories to NASA is a program milestone," says Ed Reynolds, APL STEREO project manager. "Building two nearly identical spacecraft simultaneously was a technical and scheduling challenge, but one our team welcomed and tackled with extreme professionalism and dedication. With the design, construction and now delivery of the observatories to NASA Goddard, we're very excited to help NASA get one step closer to launch and capturing the first-ever 3-D images of the sun."
During the next three months at NASA GSFC, the twin observatories will undergo additional pre-launch checks including a series of spin tests to check the spacecraft's balance and alignment; thermal vacuum tests to duplicate the extreme temperature and airless conditions of space; and acoustic tests that simulate the noise-induced vibrations of launch. The mission team plans to transport the STEREO observatories to Florida in March 2006 for final launch preparations.
SWINGING INTO ORBIT
During the 2-year STEREO mission, two nearly identical space-based observatories will explore the origin, evolution and interplanetary consequences of coronal mass ejections. These powerful solar eruptions are a major source of the magnetic disruptions on Earth and a key component of space weather, which can greatly affect satellite operations, communications, power systems, and the lives of humans in space.
To obtain unique "stereo" views of the sun, the twin STEREO observatories must be placed into different orbits where they're offset from each other and the Earth. One observatory will be placed ahead of Earth in its orbit around the sun and the other behind. Just as the slight offset between your eyes provides you with depth perception, this placement will allow the STEREO observatories to obtain 3-D images and particle measurements of the sun.
"This is the first time lunar swingbys will be used to place multiple spacecraft into their respective orbits," says APL's Andy Driesman, STEREO system engineer. "Mission designers at APL will use the moon's gravity to redirect the observatories to their appropriate orbits around the sun. This innovative mission design allows the use of a single launch vehicle."
After launch, the observatories will fly in an orbit from a point close to Earth to one that extends just beyond the moon. Approximately two months later, mission operations personnel at APL will synchronize spacecraft orbits, directing one observatory to its position trailing Earth in its orbit. Approximately one month later, the second observatory will be redirected to its position ahead of Earth.
STEREO is the third mission in NASA's Solar Terrestrial Probes Program. STEREO is sponsored by NASA's Science Mission Directorate, Washington, D.C. NASA GSFC's Solar Terrestrial Probes Program Office manages the mission, instruments and science center. APL designed, built and will operate the twin observatories for NASA during the mission.
For more information about STEREO and to download images of the twin observatories, visit http://stereo.jhuapl.edu; click on "gallery" for images.
Video will be available today on NASA TV on the Web (see http://www.nasa.gov/ntv) and at noon, 3, 6, and 10 p.m. EST on an MPEG-2 digital signal accessed via satellite AMC-6, at 72 degrees west longitude, transponder 17C, 4040 MHz, vertical polarization. It's available in Alaska and Hawaii on AMC-7 at 137 degrees west longitude, transponder 18C, at 4060 MHz, horizontal polarization. A Digital Video Broadcast compliant Integrated Receiver Decoder is required for reception.
The Applied Physics Laboratory (APL) is a not for profit laboratory and division of The Johns Hopkins University. APL conducts research and development primarily for national security and for nondefense projects of national and global significance. APL is located midway between Baltimore and Washington, D.C., in Laurel, Md. For information, visit www.jhuapl.edu.