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New Frontiers in Communication Systems will Transform Networks

By R&D Editors | February 2, 2016

The single passive optical system single-handedly interconnect over one million end points such as, broadband home users, IoT devices, data center servers, while offering at least ten Gb/s per end point.Data centers, such as the ones used by Google and Facebook, are the fundamental backbone for a range of services and applications including cloud and fog computing, big data, Internet of Things (IoT), social networking, weather forecasting, earthquake and tsunami prediction and cyber security. As such, they are a hidden, yet integral part of modern life and human progress. New research has unlocked 80 THz of fiber-optic bandwidth that will enable future exascale data centers and transform 5G networks.

The research on optical communication technologies, wavelength division multiplexing and networks form the backbone of every wired network across the whole Internet. Work until now has been focused and limited to utilizing ~11 THz of bandwidth (C and L Band) centered at 193 THz.

Optical networks based on this frequency have been able to support up to 230 channels at 50 GHz spacing. Due to constant growth of networked infrastructures, from internet of everything to data centers, the fiber capacity is reaching its limits.

The collaboration between the University of Bristol’s Department of Electrical and Electronic Engineering, Keio University and numerous Japanese industrial partners, have designed, developed and prototyped a pioneering all-optical router that can unlock 80 THz of bandwidth across a newly defined frequency band named T-Band (thousand band) and O-Band (original band). The adjacent bands span from 1.0 μm (300 THz) to 1.36 μm (220 THz) and are able to support 1600 channels at 50 GHz spacing. 

Dr. Georgios Zervas, Senior Lecturer in Optical and High Performance Networks in the Department of Electrical and Electronic Engineering, said: “The technology and system proposed and prototyped will unlock the new frequency band and networks to support future exascale data centers, ‘zero-latency’ tactile optical internet, internet of everything, smart cities, fog computing and big data infrastructure among others. This is the outcome of a recent collaboration between Bristol, Keio and other Japanese institutions that brings together people with complementary yet common vision and pioneering concepts.”

The technology fabricated and tested is based on cascaded arrayed waveguide gratings (AWGs) and is designed to potentially construct a 1600 x 1600 wavelength router that can guide data at the speed of light. Also, specially designed quantum dot chips are used for light sources, which were originally developed by NICT, Japan.

This single passive optical system can route immense information offering manifold increase from current systems. It can single-handedly interconnect over one million end points such as, broadband home users, IoT devices, data center servers, while offering at least ten Gb/s per end point. Critically it is also future-proof, since it’s transparent to any communication signal, and it can also potentially consume zero power due to its passive nature.

Hiroyuki Tsuda, Professor of Faculty of Science and Technology at Keio University, added: “The enabling technologies for the new frequency band are the quantum dot-based optical devices and the silica planar lightwave circuits designed for the new band.

“The collaboration between the University of Bristol who has extensive knowledge of the network architecture, and our Japanese research group with device technologies will create an ultra-high capacity, power-saving optical network system, in particular, for data centers.”

Citation: ‘Full-mesh T- and O-band wavelength router based on arrayed waveguide gratings‘ by Nazirul A. Idris, Ryogo Kubo, Georgios Zervas, Hiroyuki Tsuda et al is published in Optics Express [open access]

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