To address this issue, researchers at NTT Network Innovation Laboratories in Japan created and demonstrated a spectrally efficient, scalable elastic optical transport network architecture.
Conventional optical networks allocate fixed bandwidth to every optical path—regardless of the actual traffic volume and path length on the basis of the “worst-case design policy.” In stark contrast, the NTT researchers’ spectrum-sliced elastic optical path network, known as “SLICE,” is flexible and relies on adaptive spectrum allocation to an optical path based on the traffic volume and path length. It essentially enables allocation of only the necessary minimum bandwidth corresponding to individual requests—providing significant savings of network resources.
The bit rate per distance adaptive feature leads to significant spectral savings and increased network capacity. Elastic optical path networks make it possible to offload IP traffic to an elastic optical layer by using multi-flow optical transponders combined with elastic optical networking technology.
This reduces the number of router interfaces, while keeping router-to-wavelength cross-connect interconnections simple.
The technologies and functionality of elastic optical path networks will become a viable way to achieve highly efficient, cost-effective IP optical networks, according to the NTT researchers.
Talk OTh3B.3, “Spectrally Efficient Elastic Optical Path Networks Toward 1 Tbps Era,” Hidehiko Takara,
2. Graphene-Based Optical Modulators Poised to break speed limits in digital communication.
Looking into future applications, graphene-based modulators could be very compact and potentially perform at speeds up to 10 times faster than today’s technology allows. They may someday enable consumers to stream full-length, high-definition, 3-D movies onto their smartphones within mere seconds.
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