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Fibre optic nonlinear technologies

Objective

Fibre-optic communication systems form the backbone of the world’s communication infrastructure as they provide for lion fraction (more than 99%) of the global data traffic. The ongoing exponential growth in network traffic, however, is pushing current technology, whose data rates had increased over several decades, towards its limits. It is widely accepted that the nonlinear transmission effects in optical fibre are now a major limiting factor in modern fibre-optic communication systems. Nonlinear properties of the optical fibre medium limit the conventional techniques to increase capacity by simply increasing signal power. Most of the transmission technologies utilized today have been originally developed for linear (wired or wireless) communication channels. Over the past several decades, significant improvements in data rates were obtained by improvements and modifications within the overall linear transmission paradigm. However, there is much evidence that this trend is going to end within the next decade due to fibre nonlinearity. There is a clear need for radically different approaches to the coding, transmission, and processing of information that take the nonlinear properties of the optical fibre into account. This also requires education and training of a new generation of optical communication engineers and specialists with knowledge on nonlinear methods and techniques.

The EID FONTE R&D goals will be focused on development of disruptive nonlinear techniques and approaches to fibre-optic communications beyond the limits of current technology. The project will make important innovative steps in development of the technique of the nonlinear Fourier transform (NFT) and its implementation in the practical communication systems. The R&D tasks will be carried out along with training of PhD students in the leading research centres in Europe with industry focused projects with 50% of time spent in the world leading telecom centre - Nokia Bell Labs Germany.

Coordinator

ASTON UNIVERSITY
Net EU contribution
€ 273 287,88
Address
Aston Triangle
B4 7ET Birmingham
United Kingdom

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Region
West Midlands (England) West Midlands Birmingham
Activity type
Higher or Secondary Education Establishments
Non-EU contribution
€ 0,00

Participants (4)

NOKIA SOLUTIONS AND NETWORKS GMBH &CO KG
Germany
Net EU contribution
€ 0,00
Address
Werinherstrasse 91
81541 Munchen

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Region
Bayern Oberbayern München, Kreisfreie Stadt
Activity type
Private for-profit entities (excluding Higher or Secondary Education Establishments)
Non-EU contribution
€ 0,00
DANMARKS TEKNISKE UNIVERSITET
Denmark
Net EU contribution
€ 290 081,88
Address
Anker Engelundsvej 1 Bygning 101 A
2800 Kgs Lyngby

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Region
Danmark Hovedstaden Københavns omegn
Activity type
Higher or Secondary Education Establishments
Non-EU contribution
€ 0,00
INSTITUT MINES-TELECOM
France
Net EU contribution
€ 262 875,60
Address
19 Place Marguerite Perey
91120 Palaiseau

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Region
Ile-de-France Ile-de-France Essonne
Activity type
Higher or Secondary Education Establishments
Non-EU contribution
€ 0,00
TECHNISCHE UNIVERSITEIT DELFT
Netherlands
Net EU contribution
€ 255 374,28
Address
Stevinweg 1
2628 CN Delft

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Region
West-Nederland Zuid-Holland Delft en Westland
Activity type
Higher or Secondary Education Establishments
Non-EU contribution
€ 0,00