{"id":61180,"date":"2013-10-24T18:30:46","date_gmt":"2013-10-24T22:30:46","guid":{"rendered":"http:\/\/rbach.net\/blog\/index.php\/"},"modified":"2021-08-17T16:21:46","modified_gmt":"2021-08-17T20:21:46","slug":"whats-a-petabit-network","status":"publish","type":"post","link":"https:\/\/rbach.net\/index.php\/whats-a-petabit-network\/","title":{"rendered":"Whats a Petabit Network"},"content":{"rendered":"

\"WhatsSeems like it was a couple of months ago, we were excited about fiber optic cable that twisted light<\/a> to carry data at 1.6 Tbps per strand<\/strong>. Now a Petabit network <\/strong>is\u00a0the new benchmark. U.K. and Japanese researchers mashed up software-defined networking (SDN<\/a>) and multicore fiber to produce the first Petabit pipe according to<\/a> Kevin Fitchard<\/a> at GigaOM<\/a>. <\/em>A Petabit<\/strong> is one quadrillion (1,000,000,000,000,000 or 1015<\/sup>) bytes binary digits or one thousand Terabits<\/a>.<\/p>\n

Petabit network uses multicore fibers<\/h3>\n

\"WhatsThe researchers mashed up multicore fibers<\/strong> and SDN<\/strong> to makes very high-speed networks programmable. GigaOM<\/em> speculates this will allow carriers to adjust the network capacity and latency to meet the needs of traffic traveling over their networks. First, GigaOM<\/em> explains that the fiber is unlike today’s single strands of glass, or cores, that carry a single beam of light down the fiber. Multicore fiber is exactly what its name implies: multiple cores<\/strong> each carrying a single core\u2019s worth of capacity over the same link.\u00a0Professor Dimitra Simeonidou at the University of Bristol<\/a>\u00a0called current single-core fiber a capacity bottleneck.<\/p>\n

Space Division Multiplexed<\/h3>\n

The multicore group<\/a>, led by NICT<\/a> and NTT<\/a> in Japan which built a 450 km (280 miles) section of fiber optics<\/a> using 12 cores in two rings capable of transmitting 409 Tbps in either direction. That\u2019s 818 Tbps in total. Which is within spitting distance of seemingly mythical Petabit speeds according to GigaOM<\/em>. The MCF research relies on Space Division Multiplexed<\/strong> (SDM<\/a>) provided by the multicore fibers.<\/p>\n

\"Researcher\"In order to control the massive bandwidth, a team from the High Performance Networks Group<\/a> at the University of Bristol created an\u00a0OpenFlow<\/a> software-based control element to manage those enormous capacities. The Brits implemented an interface that dynamically configures the network nodes so that it can more effectively deal with application-specific traffic requirements such as bandwidth and Quality of Transport.<\/p>\n

According to the researchers, this was the first time SDN was used on a multicore network. The\u00a0University of Bristol presser<\/a> announcing the new technology says this technology will overcome critical capacity barriers, which threaten the evolution of the Internet.<\/p>\n

rb-<\/em><\/strong><\/p>\n

OK, so that really – really – really fast. We also know from a 2011 New Scientist article<\/a> that the total capacity of one of the world’s busiest routes, between New York and Washington DC, is only a few Terabits per second. With bandwidth-hungry applications like cloud computing, social media, and video-streaming continuously growing it <\/em>forces network planners at firms <\/em>like AT&T<\/a> (T<\/a>),\u00a0Verizon<\/a> (VZ<\/a>), and the NSA to <\/em>find new ways to grow their <\/em>capacity.<\/em>
\n
\n<\/a>\"Data<\/a><\/p>\n

Comcast<\/a> (CMCSA)<\/a> just finished a 1 Tbps network field trial on a production network between Ashburn, VA, and Charlotte, NC. Most likely the first place Pbps networking will be used is in the mega-data centers of the likes of Google<\/a> (GOOG<\/a>), Facebook<\/a> (FB<\/a>), or Microsoft<\/a> (MSFT<\/a>).<\/em><\/p>\n

Related articles<\/h6>\n