Washington, April 29 (IANS) While NASA has achieved the impossible by flying four identically equipped spacecraft together to capture 3D views of subtle magnetic interactions in space, the $1.1 billion mission is set to beam back valuable data beginning September this year.

During the mission’s first phase, the spacecraft will travel through reconnection sites on the Sun-side of Earth where the orbit extends out toward the Sun to around 47,500 miles.
Nearly one year later, ground controllers then will move the spacecraft to Earth’s night-side or magnetotail where the magnetic fields also reconnect — an orbit that extends away from Earth to almost 99,000 miles, nearly halfway to the moon.
The Magnetospheric Multiscale (MMS) mission was launched aboard a United Launch Alliance Atlas V 421 rocket on March 12 this year.
The aim is to study the high-speed interactions between Earth’s magnetic field and the Sun to learn more about the mechanisms responsible for energy discharges that drive auroras and play havoc with satellite navigation, communications and power grids.
However, science operations can’t begin before the four satellites move into a highly elliptical orbit and assume their pyramid-shape formation that places the spinning spacecraft just 10 km apart.
“It required a breakthrough to accomplish such an exacting formation and the Navigator GPS provided the solution,” said Brent Robertson, deputy project manager of the MMS mission from Goddard Space Flight Center in Greenbelt, Maryland.
The four spacecraft are equipped with 25 sensors and other components provided by more than 40 partner institutions in the US, Europe and Japan.
When fully deployed, each satellite’s booms will sweep out an area the size of a baseball field as the spacecraft slowly rotates. All the four satellites will be arranged in a pyramid formation, flying within about six miles of each other at their closest.
“No one has done what we are going to do,” said MMS deputy mission systems engineer Gary Davis.
Because the MMS spacecraft must maintain a precise formation, the mission also needed the ability to not only determine the immediate locations of the four observatories, but also predict where they would be in the future and how fast they would be travelling.
Providing that predictive data is the Goddard Enhanced Onboard Navigation System (GEONS). Communicating commands to the MMS fleet also required the MMS team to rethink the onboard hardware it would use.
For this, the Goddard team developed a diminutive S-band antenna that met the mission’s communications requirements.
“With this data, we will be seeing more than we could before,” the researchers said, adding that “this mission was a long time coming and we are anxious to reap the rewards”.

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