Using
a bi-directional configuration, engineers at Nokia demonstrated real-time, high
capacity signal transmission suitable for coupling adjacent data centers with
current compliance standards
SAN DIEGO — A cutting edge, “off-line” signal transmission mechanism,
experimentally demonstrated just a few years ago, is now on-line as a real-time
bidirectional transmission system. At OFC 2018, the single-most important annual event in optical communications,
being held March 11-15 in San Diego California, a research team from Nokia will
report the real-time, bi-directional transmission of 78 interleaved, 400
gigabit per second (Gb/s) channels with a 31.2 terabit per second (Tb/s) fiber
capacity.
At twice the 200 Gb/s standard rate found in most
applications, the C-band signals were transmitted over a single,
90-kilometer-long single-mode fiber. Such a high transmission capacity and rate
would offer a particularly attractive capacity bump to current data center
interconnections, where nearby data centers are coupled together to form a
single, larger center.
Fundamentally speaking, there are two ways to go
about increasing a data center’s capacity: either increase the number of
(parallel) fibers through which the data travels, or increase how much data you
transmit through existing fibers. While the use of additional fibers is a more
straightforward approach (particularly for data centers which usually rent
fibers to use), it is expensive both in price and power consumption.
Perhaps unsurprisingly, there is considerable
interest in finding ways of increasing the transmission capacity of fibers
already in use. As multiplexers (devices that combine multiple signals into
one) and transponders become more sophisticated, so do the available signal
encoding/decoding processes. Current standards for wavelength division
multiplexed (WDM) signals, for instance, can combine up to 96 channels on C
band.
The off-line proof-of-principle experiments first
demonstrating the high capacity, error-free 400 Gb/s WDM transmission
capitalized on a very high spectral efficiency to boost capacity in the fiber.
While this is not the first real-time implementation of 400 Gb/s channels, it
is the first to be successful with an impressive 8 bit per second-per hertz
spectral efficiency.
“So far, three different companies have
demonstrated a real-time 400 Gb/s transponder over the last three years, but we
are the only ones reporting 400 Gb/s with such high spectral efficiency,” said
Thierry Zami, who will be presenting the team’s work. “The spectral efficiency
allows us to provide quite a large fiber capacity. So, in this case we claim
31.2 Tb/s, but in practice, without the limitations in terms of number of
loading channels in our lab, we could have reached about 38 Tb/s over whole C
band. This is really one of the innovative points.”
In addition to using the real-time, commercially
available transponders, the setup used components that are compliant with
current network standards. After testing the unidirectional transmission
configuration, Zami and his team wanted to further improve the resulting Q2 margins, which represent the signal to noise power
ratio.
“It was important for us to maintain simple
amplification, only based on erbium doped fiber amplifiers, and to use standard
fibers,” said Zami. “To increase the system margins observed with the
unidirectional set up, we could have decided to make the same unidirectional
experiment with slightly larger channel spacing, for instance. But we said,
‘no’ because we wanted to remain compliant as much as possible with the
standard grid.”
The team instead developed a bi-directional
transmission set up with the same 90-kilometer fiber, where the even and odd
400 Gb/s channels, with the same 50 GHz grid spacing, transmit in opposite
directions. For this configuration, they measured Q2 margins at least twice as large as for the
unidirectional version. And because it employed two 100 GHz-spaced multiplexers
to the 50 GHz channel spacing, unlike the unidirectional system’s
individual 50 GHz multiplexer, it benefits from wider filtering to exhibit
better tolerance to frequency detuning.