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People keep hearing about the dramatic growth of big data and the resulting surge in traffic on the global carrier's networks
.
For example, Qmee has an interesting infographic, which captured 60 seconds of online traffic in 2013, and its statistics are staggering: 350GB of data uploaded to Facebook, two million Google searches, 24 million emails sent, 278,000 tweets, and many, many more—in just one minute
.
As a result, optical network operators face a huge challenge to redesign the hardware architecture of their networks and scale up their networks to 100G to meet such massive traffic growth while remaining profitable
.
Operators need to evolve their optical networks to include packet switching capabilities and are looking for innovative ways to manage and control networks such as SDN, which has led to a major improvement
in the global optical transport network.
This is where OTN networks emerge.
By effectively virtualizing optical bandwidth, OTN also allows various network traffic to be dynamically allocated
at 1G granularity on 100G optical pipes.
OTN switching provides a cost-effective, scalable, and low-latency tier to address the bandwidth expansion requirements
caused by packet traffic growth.
In other words, OTN switching makes 100G a cost-effective and reliable technology
that can be deployed at scale.
According to Infographics, the vast majority of network operators – 86% – have chosen OTN switching as the best technology
for filling 100G pipelines because OTN switching enables efficient aggregation of multiple services and protocols on a single optical link.
The technology has been adopted and deployed
by network operators in China, Europe and North America.
Especially for metro optical networks, the optical bandwidth can be fully virtualized to make it an efficient, dynamic and shareable resource, so as to realize channelization, exchange, aggregation and transmission at 1G granularity, which fundamentally brings a subversive impact
to the economic considerations of 100G.
People keep hearing about the dramatic growth of big data and the resulting surge in traffic on the global carrier's networks
.
For example, Qmee has an interesting infographic, which captured 60 seconds of online traffic in 2013, and its statistics are staggering: 350GB of data uploaded to Facebook, two million Google searches, 24 million emails sent, 278,000 tweets, and many, many more—in just one minute
.
As a result, optical network operators face a huge challenge to redesign the hardware architecture of their networks and scale up their networks to 100G to meet such massive traffic growth while remaining profitable
.
Operators need to evolve their optical networks to include packet switching capabilities and are looking for innovative ways to manage and control networks such as SDN, which has led to a major improvement
in the global optical transport network.
This is where OTN networks emerge.
By effectively virtualizing optical bandwidth, OTN also allows various network traffic to be dynamically allocated
at 1G granularity on 100G optical pipes.
OTN switching provides a cost-effective, scalable, and low-latency tier to address the bandwidth expansion requirements
caused by packet traffic growth.
In other words, OTN switching makes 100G a cost-effective and reliable technology
that can be deployed at scale.
According to Infographics, the vast majority of network operators – 86% – have chosen OTN switching as the best technology
for filling 100G pipelines because OTN switching enables efficient aggregation of multiple services and protocols on a single optical link.
The technology has been adopted and deployed
by network operators in China, Europe and North America.
Especially for metro optical networks, the optical bandwidth can be fully virtualized to make it an efficient, dynamic and shareable resource, so as to realize channelization, exchange, aggregation and transmission at 1G granularity, which fundamentally brings a subversive impact
to the economic considerations of 100G.
