Summary
Sustained 2-digit growth in internet traffic is raising the need for new photonic technologies enabling Petabit/s network capacities, whereas suppressed operator margins call for new concepts to make these networks more efficient. QAMeleon aims at a holistic solution towards scaling metro/core networks to the next decade. A new generation of SDN-programmable photonic components, modules and subsystems will be delivered, employing sliceability as a means of optimizing resource utilization and cutting operator costs by >30%.
At the transponder side, QAMeleon will develop components for 2 generations ahead: Operating at 128 Gbaud, they will bring significant savings in footprint (>13×), energy/bit (10.4×) and cost/bit (>4.3×). At the ROADM side, QAMeleon will develop large-scale flex-grid wavelength-selective switches (1×24 WSS) and transponder aggregators (8×24 TPA), reducing footprint and cost/port by more than 40% and 28% respectively, with energy savings per ROADM node reaching 4×. Addressing the emerging needs of 5G network backhaul and datacenter interconnect (DCI) metro-access networks where dynamicity is pivotal, QAMeleon will develop an integrated flex-grid 1×4 WSS with nanosecond-scale switching time. The fast 1×4 WSS will be scalable to large channel counts (i.e. full C-band) and will enable savings in footprint, energy consumption and cost by 20×, 11.5× and 36% respectively.
QAMeleon will integrate its innovative photonic components into functional subsystems: A 3 Tb/s sliceable bandwidth-variable transponder (S-BVT), a flexible ROADM with large-scale WSSs and TPAs, and a fast ROADM for metro-access. All necessary SDN software extensions, plugins and application interfaces will be developed, providing a complete functional SDN framework for the sliceable “white box” subsystems. QAMeleon’s devices will be integrated with the SDN software and validated in scalable demonstrators at Nokia’s lab infrastructure and on TIM’s deployed regional network fiber plant
At the transponder side, QAMeleon will develop components for 2 generations ahead: Operating at 128 Gbaud, they will bring significant savings in footprint (>13×), energy/bit (10.4×) and cost/bit (>4.3×). At the ROADM side, QAMeleon will develop large-scale flex-grid wavelength-selective switches (1×24 WSS) and transponder aggregators (8×24 TPA), reducing footprint and cost/port by more than 40% and 28% respectively, with energy savings per ROADM node reaching 4×. Addressing the emerging needs of 5G network backhaul and datacenter interconnect (DCI) metro-access networks where dynamicity is pivotal, QAMeleon will develop an integrated flex-grid 1×4 WSS with nanosecond-scale switching time. The fast 1×4 WSS will be scalable to large channel counts (i.e. full C-band) and will enable savings in footprint, energy consumption and cost by 20×, 11.5× and 36% respectively.
QAMeleon will integrate its innovative photonic components into functional subsystems: A 3 Tb/s sliceable bandwidth-variable transponder (S-BVT), a flexible ROADM with large-scale WSSs and TPAs, and a fast ROADM for metro-access. All necessary SDN software extensions, plugins and application interfaces will be developed, providing a complete functional SDN framework for the sliceable “white box” subsystems. QAMeleon’s devices will be integrated with the SDN software and validated in scalable demonstrators at Nokia’s lab infrastructure and on TIM’s deployed regional network fiber plant
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More information & hyperlinks
| Web resources: | https://cordis.europa.eu/project/id/780354 |
| Start date: | 01-01-2018 |
| End date: | 31-10-2022 |
| Total budget - Public funding: | 7 999 558,00 Euro - 7 999 558,00 Euro |
Cordis data
Original description
Sustained 2-digit growth in internet traffic is raising the need for new photonic technologies enabling Petabit/s network capacities, whereas suppressed operator margins call for new concepts to make these networks more efficient. QAMeleon aims at a holistic solution towards scaling metro/core networks to the next decade. A new generation of SDN-programmable photonic components, modules and subsystems will be delivered, employing sliceability as a means of optimizing resource utilization and cutting operator costs by >30%.At the transponder side, QAMeleon will develop components for 2 generations ahead: Operating at 128 Gbaud, they will bring significant savings in footprint (>13×), energy/bit (10.4×) and cost/bit (>4.3×). At the ROADM side, QAMeleon will develop large-scale flex-grid wavelength-selective switches (1×24 WSS) and transponder aggregators (8×24 TPA), reducing footprint and cost/port by more than 40% and 28% respectively, with energy savings per ROADM node reaching 4×. Addressing the emerging needs of 5G network backhaul and datacenter interconnect (DCI) metro-access networks where dynamicity is pivotal, QAMeleon will develop an integrated flex-grid 1×4 WSS with nanosecond-scale switching time. The fast 1×4 WSS will be scalable to large channel counts (i.e. full C-band) and will enable savings in footprint, energy consumption and cost by 20×, 11.5× and 36% respectively.
QAMeleon will integrate its innovative photonic components into functional subsystems: A 3 Tb/s sliceable bandwidth-variable transponder (S-BVT), a flexible ROADM with large-scale WSSs and TPAs, and a fast ROADM for metro-access. All necessary SDN software extensions, plugins and application interfaces will be developed, providing a complete functional SDN framework for the sliceable “white box” subsystems. QAMeleon’s devices will be integrated with the SDN software and validated in scalable demonstrators at Nokia’s lab infrastructure and on TIM’s deployed regional network fiber plant
Status
CLOSEDCall topic
ICT-30-2017Update Date
27-10-2022
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Organisations
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| INSTITUTE OF COMMUNICATION AND COMPUTER SYSTEMS (Coördinator)
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| ALCATEL-LUCENT INTERNATIONAL SA
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| ALTER TECHNOLOGY TUV NORD UK LIMITED
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| ARISTOTELIO PANEPISTIMIO THESSALONIKIS
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| DANMARKS TEKNISKE UNIVERSITET
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| Eindhoven University of Technology
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| FINISAR GERMANY GMBH
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| FRAUNHOFER GESELLSCHAFT ZUR FOERDERUNG DER ANGEWANDTEN FORSCHUNG E.V.
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| Finisar Sweden AB
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| III-V LAB
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| INTERUNIVERSITAIR MICRO-ELECTRONICA CENTRUM VZW
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| NEXTWORKS
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| SMART PHOTONICS BV (SMART)
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| TELECOM ITALIA SPA
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| VARIO-OPTICS AG