Abstract
The high capacity demand, to support broadband services and everything-to-internet connectivity is pushing the limits of both access and metro networks, requiring the adoption of novel strategies for the optical transceiver modules. This represents an opportunity for the adoption in these network scenarios of novel photonic technologies based on single-mode vertical cavity surface emitting lasers (VCSELs) at long wavelengths. On one hand, the access network evolution requires a line rate increase beyond 10 Gb/s, targeting 50 Gb/s propagation in passive optical networks (PONs) over a few tens of kms in standard single mode fiber (SSMF) with simple, cost effective and energy efficient transceivers. On the other hand, the future metropolitan area network (MAN) will need to handle multi-Tb/s traffic in a very dynamic scenario, over variable distances up to hundreds of kms while promoting sustainability, reducing the CapEx and OpEx costs and power consumption. Both needs can be fulfilled by adopting VCSEL direct modulation with multicarrier modulation formats such as discrete multitone (DMT), in combination with distinct transmitter architectures and receiver solutions to support different aggregate capacity requirements and transmission reaches. In any case DMT with bit/power loading enables flexible rate and adaptive distance for metro network applications and link adaptation and PON resource usage optimization for future access networks. In this work, we report our recent results on the adoption of VCSEL technology in both scenarios, with special focus on the receiver and transmitter adopted architectures.
Highlights
Nowadays, most of the total data traffic is concentrated in less of the 5% of the geographical area, this situation impacts the operation of access networks, e.g. passive optical networks (PONs), and metropolitan area networks (MANs)
IEEE and ITU are looking for the candidate modulation formats and technologies for the 50-Gbit/s PON (50G-PON)[1]: it would be beneficial to rely on the pre-existence of mature high-volume technologies for data center intra-connect (DCI), PON links need to address much higher power budget and longer reaches with respect to point-to-point DCI optical links; it is mandatory to adopt alternative solutions[1]
The answer to the above requirements can be given by the adoption of novel strategies for the optical transceiver modules, employing advanced photonic technologies based on single-mode (SM) vertical cavity surface emitting lasers (VCSELs) at long wavelengths (LW) and direct modulation (DM) with multicarrier modulation formats such as discrete multitone (DMT)
Summary
Most of the total data traffic is concentrated in less of the 5% of the geographical area, this situation impacts the operation of access networks, e.g. passive optical networks (PONs), and metropolitan area networks (MANs). As MANs are concerned, beside the capacity increase, optical transport technologies should enable the development of agile solutions, different from the model of long-haul transmission, that can flexibly adapt to the path/traffic conditions, In both segments, the answer to the above requirements can be given by the adoption of novel strategies for the optical transceiver modules, employing advanced photonic technologies based on single-mode (SM) vertical cavity surface emitting lasers (VCSELs) at long wavelengths (LW) and direct modulation (DM) with multicarrier modulation formats such as discrete multitone (DMT). The exploitation of DM with DMT modulation[6] at the transmitter is combined with coherent detection (COHD) at the receiver side to allow propagation in hundreds of kilometers links In both cases DMT with bit/power loading enables a flexible rate, achieving a sliceable bandwidth and bitrate variable transceiver (S-BVT) able to adapt to metro network applications[7] and link adaptation and PON resource usage optimization for future access networks.
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