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Saturday, December 16, 2017

NASA, Norway to Develop Arctic Laser-Ranging Station

August 9, 2017

The scientific base of Ny-Ålesund, Svalbard, as seen from the sea. The future Satellite Ranging Station will be located between the two antennas visible in the image. Credits: Norwegian Mapping Authority/Per Erik Opseth. Photo: NASA

The scientific base of Ny-Ålesund, Svalbard, as seen from the sea. The future Satellite Ranging Station will be located between the two antennas visible in the image. Credits: Norwegian Mapping Authority/Per Erik Opseth. Photo: NASA

 NASA and the Norwegian Mapping Authority are partnering to develop a state-of-the-art satellite laser ranging station 650 miles from the North Pole that will produce high-precision locations of orbiting satellites, help track changes in the ice sheets and improve the efficiency of marine transportation and agriculture.

 
The Arctic station will be the latest addition to a global network of space geodetic stations, which measure and monitor the size and shape of Earth, its orientation in space, the exact location of points on its surface and how these locations change over time. Space geodesy has a decades-long history at NASA due to its important role in the positioning and navigation of satellites.
 
“This partnership with Norway is an important step for NASA and the scientific community in building the next generation space geodetic network,” said Benjamin Phillips, program scientist for NASA's Space Geodesy Program in Washington. “This network provides fundamental data for satellite and spacecraft navigation and underpins many of NASA’s Earth-observing missions and science.”
 
Under the new agreement signed on Aug. 7, Norway and NASA will build and install a satellite laser ranging facility in the scientific base of Ny-Ålesund, Svalbard. NASA will also provide expert consultation on how to operate the instruments. 
 
The ground-based laser transmits ultrashort laser pulses aimed at satellites specially equipped with a retroreflector, an array of special mirrors that bounce the pulses back. The system measures the time it takes for the light to travel back to its point of origin, which is used to determine the position of the satellite with respect to the ground station with an accuracy of around 0.04 inches (1 millimeter).
 
Combined with measurements from other geodetic instruments at the Ny-Ålesund Geodetic Observatory and all over the globe, the laser ranging observations will help refine the Global Geodetic Reference Frame, the basis for setting coordinates for all locations on Earth’s surface. 
 
The reference frame is used to measure the position of objects in space with respect to the Earth, as well as to precisely monitor motions of Earth’s crust, changes in sea level, and to support satellite positioning technology like GPS, which is used in many aspects of our daily lives.
 
“From the NASA perspective, laser ranging is important to understanding where our spacecraft are, as well as where on Earth their measurements are located,” said Stephen Merkowitz, space geodesy project manager at NASA’s Goddard Space Flight Center in Greenbelt, Maryland. “Laser ranging is needed for satellites that require very precise positioning measurements. Today we’re tracking over 90 satellites, not only from NASA, but also from other space agencies with this technique.”
 
The new Norwegian geodetic station will be the northernmost of its kind and will be invaluable for tracking satellites that follow polar orbits, as many of NASA’s Earth-observing missions do.
 
To make sure the laser ranging system is able to work in Arctic conditions, NASA will use a telescope dome strong enough to open and break the ice that might accumulate on top during Svalbard’s frigid winters.
 
The telescope will be mounted on a pointing gimbal that can still move when exposed to very cold temperatures. To be able to work during the Arctic summertime, when the constant sunlight makes it difficult to observe the stars needed to calibrate the telescope, NASA specified that this telescope has to be stable for months at a time.
 
The Norwegian Mapping Authority started construction work on the new scientific base in 2014. The current goal is to have all systems in operation by 2022.
 
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