If a spacecraft carried the means to detect the pulses, it could compare their arrival times with those predicted at a reference location. This would enable the craft to determine its position to an accuracy of just five kilometres anywhere in the galaxy. "The principle is so simple that it will definitely have applications," said Prof Werner Becker from the Max-Planck Institute for Extraterrestrial Physics in Garching.
"These pulsars are everywhere in the Universe and their flashing is so predictable that it makes such an approach really straightforward".
The proposed technique is very similar to that employed in the popular Global Positioning System, which broadcasts timing signals to the user from a constellation of satellites in orbit. But GPS only works on, or just above, the Earth so it has no use beyond our planet.
Currently, mission controllers wanting to work out the position of their spacecraft deep in the Solar System study the differences in the time it takes for radio communications take to travel to and from the satellite. It is a complex process and requires several antennas dotted across the Earth. It is also a technique that is far from precise, and the errors increase the further away the probe moves. For the most distant spacecraft still in operation - Nasa's Voyager satellites, which are now approaching the very edge of the Solar System, some 18 billion km away - the errors associated with their positions are on the order of several hundred km. The current system is not very efficient.
Stellar beacons for navigation
Pulsars are a type of neutron star.....Produced in huge stellar explosions.....Remnant core is highly magnetised....Radiation focused into intense beams....Beams sweep around as dead star spins....Pulsars appear like ticks to observer...Stability of ticks rivals atomic clocks
Navigation by pulsar beacon will take a few years, at least, to develop. The telescope hardware for detecting X-rays in space has traditionally been bulky and heavy. Engineers will need to miniaturize the technology to make a practical pulsar navigation unit. This is on the way for the next generation of X-ray telescopes. Current mirrors have a 100 times more weight and would be completely unusable.
The scientist believes his navigation solution will certainly find use on Solar System probes, providing navigation for interplanetary missions and perhaps for future manned ventures to Mars where high performance systems will be an absolute requirement for safety reasons. But he also likes the idea of humanity one day pushing out across interstellar space.
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