News Article
Data-transfer speeds reach new heights
SiGe and VCSELs combined could lead to a new era in short-range data transmission
Researchers at IBM have set a new record for data transmission over a multimode optical fibre, a type of cable that is typically used to connect nearby computers within a single building or on a campus. The achievement demonstrated that the standard, existing technology for sending data over short distances should be able to meet the growing needs of servers, data centers and supercomputers through the end of this decade, the researchers said.
Sending data at a rate of 64 gigabits per second (Gb/s) over a cable 57 meters long using aVCSEL, the researchers achieved a rate that was about 14 percent faster than the previous record and about 2.5 times faster than the capabilities of today's typical commercial technology.
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In the foreground are 2 Chalmers VCSELs. The one on the left has a 6um aperture and could operate error free up to 62Gb/s while the one on the right has a 5um aperture and set the equipment limited record of 64Gb/s. Behind the two VCSELs is IBM's BiCMOS8HP VCSEL driver IC. On either side of the IC are the decoupling capacitors and connecting wirebonds. (Credit: IBM)
To send the data, the researchers used standard non-return-to-zero (NRZ) modulation. “Others have thought that this modulation wouldn't allow for transfer rates much faster than 32 Gb/s,” notes researcher Dan Kuchta of the IBM T.J. Watson Research Centre in New York.
Many researchers thought that achieving higher transmission rates would require turning to more complex types of modulation, such as pulse-amplitude modulation-4 (PAM-4).
"What we're showing is that that's not the case at all," Kuchta continues. Because he and his colleagues achieved fast speeds even with NRZ modulation, he added, "this technology has at least one or two more generations of product life in it."
Kuchta will describe these results at the 2014 OFC Conference and Exposition, being held March 9-13 in San Francisco.
To achieve such high speeds, the researchers used the VCSELs developed at Chalmers University of Technology in Sweden and custom SiGe chips developed at IBM Research. “The receiver chip is a unique design that simultaneously achieves speeds and sensitivities well beyond today’s commercial offerings,” Kuchta explains. “The driver chip incorporates transmit equalisation, which widens the bandwidth of the optical link. While this method has been widely used in electrical communication, it hasn't yet caught on in optical communication,” he says.
“Researchers typically rely on a rule of thumb that says the usable data-transfer rate is about 1.7 times the bandwidth,” Kuchta explains. “That means that with the VCSEL laser, which has a bandwidth of about 26 GHz, the rate would be only about 44 Gb/s.What we're doing with equalization is we're breaking the historical rule of thumb," Kuchta adds.
The fast speeds only worked for a distance of 57 metres, so this technology isn't designed for sending data across continents. Instead, it's most suitable for transmitting data within a building, he said. About 80 percent of the cables at data centres and most, if not all, of the cables used for typical supercomputers are less than 50 metres long.
This new technology, Kuchta says, is ready for commercialisation right now.
The presentation Th3C.2, titled “64Gb/s Transmission over 57m MMF using an NRZ Modulated 850nm VCSEL,” will take place on Thursday, March 14th at 1:30 p.m. in room 121 of the Moscone Centre.
Sending data at a rate of 64 gigabits per second (Gb/s) over a cable 57 meters long using aVCSEL, the researchers achieved a rate that was about 14 percent faster than the previous record and about 2.5 times faster than the capabilities of today's typical commercial technology.
In the foreground are 2 Chalmers VCSELs. The one on the left has a 6um aperture and could operate error free up to 62Gb/s while the one on the right has a 5um aperture and set the equipment limited record of 64Gb/s. Behind the two VCSELs is IBM's BiCMOS8HP VCSEL driver IC. On either side of the IC are the decoupling capacitors and connecting wirebonds. (Credit: IBM)
To send the data, the researchers used standard non-return-to-zero (NRZ) modulation. “Others have thought that this modulation wouldn't allow for transfer rates much faster than 32 Gb/s,” notes researcher Dan Kuchta of the IBM T.J. Watson Research Centre in New York.
Many researchers thought that achieving higher transmission rates would require turning to more complex types of modulation, such as pulse-amplitude modulation-4 (PAM-4).
"What we're showing is that that's not the case at all," Kuchta continues. Because he and his colleagues achieved fast speeds even with NRZ modulation, he added, "this technology has at least one or two more generations of product life in it."
Kuchta will describe these results at the 2014 OFC Conference and Exposition, being held March 9-13 in San Francisco.
To achieve such high speeds, the researchers used the VCSELs developed at Chalmers University of Technology in Sweden and custom SiGe chips developed at IBM Research. “The receiver chip is a unique design that simultaneously achieves speeds and sensitivities well beyond today’s commercial offerings,” Kuchta explains. “The driver chip incorporates transmit equalisation, which widens the bandwidth of the optical link. While this method has been widely used in electrical communication, it hasn't yet caught on in optical communication,” he says.
“Researchers typically rely on a rule of thumb that says the usable data-transfer rate is about 1.7 times the bandwidth,” Kuchta explains. “That means that with the VCSEL laser, which has a bandwidth of about 26 GHz, the rate would be only about 44 Gb/s.What we're doing with equalization is we're breaking the historical rule of thumb," Kuchta adds.
The fast speeds only worked for a distance of 57 metres, so this technology isn't designed for sending data across continents. Instead, it's most suitable for transmitting data within a building, he said. About 80 percent of the cables at data centres and most, if not all, of the cables used for typical supercomputers are less than 50 metres long.
This new technology, Kuchta says, is ready for commercialisation right now.
The presentation Th3C.2, titled “64Gb/s Transmission over 57m MMF using an NRZ Modulated 850nm VCSEL,” will take place on Thursday, March 14th at 1:30 p.m. in room 121 of the Moscone Centre.
