The researchers also maintain that the 44.2-Tbps micro-comb (a micro-comb being an optical frequency comb generated by integrated micro-cavity resonators) has the high-speed data processing required to download 1,000 high-definition films in a split second.
According to SUT’s news page, the “technology has the capacity to [simultaneously] support the high-speed internet connections of 1.8 million households in Melbourne ... and billions across the world during peak periods”.
The breakthrough comes when the demand for fast internet capabilities has become unprecedented due to the staggering number of web users now requiring their own consumer internet connections while respecting coronavirus lockdowns at home.
About the Optic Micro-Comb Chip Research
As touched on, the micro-comb chip is an optical technology: it uses infrared pulses of light as a means to channel internet communications. However, while there is nothing new about the internet data processing based on the transmission of light, the Australia-based researchers’ micro-comb chip is nevertheless unique.
The device, which was provided by SUT at the time of the research, is not only more lightweight than traditional internet hardware—it is also able to achieve a multitude of communications channels, each of which acts as a high-quality infrared laser.
Such an achievement was established when the researchers set out to show how much potential optical micro-combs have in optimising communication systems. They did this by load testing the device to reflect the infrastructure of Australia’s National Broadband Network, aka NBN (the country’s future-proofing project that concerns the replacement of its outdated telecommunications systems with high-efficiency internet connectivity).
The optical micro-comb chip is about 3 mm by 5mm. Pictured: a close-up of the device, which sits on an Australian coin for scale. Image Credit: Swinburne University of Technology.
The Micro-Comb Load Test
In what was the first time that a micro-comb has been used for such a grand, out-of-the-lab load test, the scientists set the stage for the research by installing 76.6 kilometres of ‘dark’ optical fibres. This optical fibre loop, funded by Australia’s Academic Research Network, is named ‘the Australian Lightwave Infrastructure Research Testbed’ (ALIRT). Illustrated below, ALIRT runs between RMIT’s Melbourne City Campus and Monash University’s Clayton Campus—and it’s within that infrastructure that the micro-comb was integrated.
According to RMIT’s news page, the research demonstrated that the micro-comb solution successfully “creates a rainbow of infrared light allowing data to be transmitted on many frequencies of light simultaneously, vastly increasing bandwidth”.
The report goes on to say that the result of the micro-comb’s multi-channel ‘rainbow’ achieved “about three times the record data rate for the entire NBN network and about 100 times the speed of any single device currently used in Australian fibre networks”. (The specifics of how the optic data channels performed can be read in the researchers’ Nature Communications publication).
The test was carried out on a 76.6 km optical fibre loop between Royal Melbourne Institute of Technology, or RMIT; and Monash University, in Melbourne. Pictured: a red outline, superimposed on an aerial photograph, represents the Australian Lightwave Infrastructure Research Testbed optical fibre loop. Image Credit: RMIT.
The Applications and Implications of the Optic Micro-Comb
In the words of Professor Moss, director of the Optical Sciences Centre at Swinburne and co-inventor of micro-comb chips himself, this display of the “capability [of] ultra-high bandwidth fibre optic telecommunications ... represents [both] a world record for bandwidth down a single optical fibre from a single chip source, and ... an enormous breakthrough”.
The Australia-based researchers believe that such a leap forward in telecommunications data processing could improve applications—and not just the ever-increasing, data-hungry consumer applications either: many industry areas may benefit, too.
“It’s not just Netflix we’re talking about here: it’s the broader scale of what we use our communication networks for. This data can be used for self-driving cars and future transportation, and it can help the medicine, education, finance, and e-commerce industries”.
The scientists do not believe that future applications end there, moreover. “Long-term,” said RMIT’s distinguished professor Arnan Mitchell, “we hope to create integrated photonic chips that could enable this sort of data rate to be achieved across existing optical fibre links with minimal cost”.