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'Time telescope' could boost up long-distance communications
Tuesday 29th September, 2009
(ANI)
Washington, September 29 : If scientists have their way, then a "telescope" that can magnify time could soon dramatically increase the amount of data that can be sent through fibre optic cables, speeding up broadband internet and other long-distance communications.
Though it isn't possible to speed up the flashes of light that stream through the global network of optical fibres at around 200 million metres per second, more information can be squeezed into each burst of light, according to Mark Foster at Cornell University in Ithaca, New York, using what he and his colleague Alexander Gaeta call a "time telescope" fitted with "time lenses".
"A time lens is essentially like an optical lens," said Foster.
An optical lens can deflect a light beam into a much smaller area of space; a time lens deflects a section of a light beam into a smaller chunk of time.
The Cornell team made their time lenses using a silicon waveguide that can channel light.
An information-carrying pulse made from a series of small laser bursts signalling digital 1s and 0s travels through an optical fibre and into the waveguide.
As it enters, it is combined with another laser pulse from an infrared laser.
The infrared pulse vibrates the atoms of the waveguide, which in turn shifts the frequencies of the data-carrying pulse before it exits the waveguide and passes into an optical fibre beyond.
"The front of the (data-carrying) pulse is shifted down in frequency and the end is shifted up in frequency within the silicon waveguide," said Foster.
Because the speed of light passing through a medium depends on its frequency, the front of the pulse is slowed down while its rear speeds up.
At the time lens's focal point, the rear of the pulse catches up with the front, producing a fleeting image with a spectrum encoding the entire light pulse.
The Cornell team compressed a light pulse carrying 24 bits of data in this way.
They used a second time lens to convert the compressed image back into a 24-bit light pulse like the one they started with.
The second lens was more powerful than the first, however, so the second 24-bit pulse was 1/27th the length of the one that went in: the pulse duration shrank from 2.5 nanoseconds to 92 picoseconds, but no information was lost.
The two lenses work together like the two lenses of a simple telescope or microscope.
A similar device could be used to compress the data passing through the packet-based optical networks that underlie global communications, according to Foster.
"We would be able to send 27 times as much information on the ame wavelength channel," he said.
Tuesday 29th September, 2009
(ANI)
Washington, September 29 : If scientists have their way, then a "telescope" that can magnify time could soon dramatically increase the amount of data that can be sent through fibre optic cables, speeding up broadband internet and other long-distance communications.
Though it isn't possible to speed up the flashes of light that stream through the global network of optical fibres at around 200 million metres per second, more information can be squeezed into each burst of light, according to Mark Foster at Cornell University in Ithaca, New York, using what he and his colleague Alexander Gaeta call a "time telescope" fitted with "time lenses".
"A time lens is essentially like an optical lens," said Foster.
An optical lens can deflect a light beam into a much smaller area of space; a time lens deflects a section of a light beam into a smaller chunk of time.
The Cornell team made their time lenses using a silicon waveguide that can channel light.
An information-carrying pulse made from a series of small laser bursts signalling digital 1s and 0s travels through an optical fibre and into the waveguide.
As it enters, it is combined with another laser pulse from an infrared laser.
The infrared pulse vibrates the atoms of the waveguide, which in turn shifts the frequencies of the data-carrying pulse before it exits the waveguide and passes into an optical fibre beyond.
"The front of the (data-carrying) pulse is shifted down in frequency and the end is shifted up in frequency within the silicon waveguide," said Foster.
Because the speed of light passing through a medium depends on its frequency, the front of the pulse is slowed down while its rear speeds up.
At the time lens's focal point, the rear of the pulse catches up with the front, producing a fleeting image with a spectrum encoding the entire light pulse.
The Cornell team compressed a light pulse carrying 24 bits of data in this way.
They used a second time lens to convert the compressed image back into a 24-bit light pulse like the one they started with.
The second lens was more powerful than the first, however, so the second 24-bit pulse was 1/27th the length of the one that went in: the pulse duration shrank from 2.5 nanoseconds to 92 picoseconds, but no information was lost.
The two lenses work together like the two lenses of a simple telescope or microscope.
A similar device could be used to compress the data passing through the packet-based optical networks that underlie global communications, according to Foster.
"We would be able to send 27 times as much information on the ame wavelength channel," he said.
