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| April 16, 2015
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Wi-Fi Charges Up Ethernet

Wi-Fi Charges Up EthernetInformation Technology prognosticators Gartner (IT) predicts that 40% of enterprises will use Wi-Fi as the default connection for mobile and non-mobile devices by 2018 according to Fred Donovan at FierceMobileIT. The prediction says that typically fixed location devices like; desktops, desk phones, projectors, and conference rooms will use Wi-Fi as their primary connection replacing Ethernet.

Wi-FI logoGartner says Wi-Fi is facilitating BYOD. The enterprise Wi-Fi network now allows workers to choose any device and move anywhere in the workplace. Gartner argues that the introduction of security measures like 802.1X augmented with Advanced Encryption Standard (AES) encryption has lessened IT’s worry about security breaches involving the Wi-Fi infrastructure. Ken Dulaney, V.P. and distinguished analyst at Gartner said;

Ethernet cabling has been the mainstay of business workspace connectivity since the beginning of networking. However, as smartphones, laptops, tablets, and other consumer devices have multiplied, the consumer space has largely converted to a wireless-first world

Facilitating BYOD

As the first connection to the enterprise infrastructure, Wi-Fi brings workers the ability to choose any device and move anywhere without worry. VP Dulaney continued;

WI-FI certifiedAs bring your own device (BYOD) has increased in many organizations, the collision of the business and consumer worlds has changed workers’ demands

Furthermore, cabling systems or even peer-to-peer (P2P) wireless solutions using technologies that offer cable replacement have had to deal with a variety of connectors challenges, such as USB and micro-USB, as video systems move beyond Video Graphics Array (VGA). The market research firm also argues that MACD costs will decrease.

MACD costsAdditions, moves, and changes are costly inconveniences that waste time for enterprise IT organizations. A move can sometimes involve cabling changes that can cost as much as $1,000 … With Wi-Fi printers, desktops, and other devices, all that is required is a cable to the power source, leaving workers free to move themselves making reconfigurations of offices easier.

Because of the many benefits of Wi-FI, Gartner VP Dulaney predicts firms are going to change how they connect;

we expect many organizations to shift to a wireless-by-default and a wired-by-exception model.

New Ethernet specifications

In order to deal with the new wireless-by-default reality, changes are needed on the wired network.  at FierceCIO reports that the vendor community is working to address the Wi-Fi first world. Unfortunately, there are two industry groups pushing their own new Ethernet specifications. Mr. Mah says that new Ethernet standards are needed to work with Wave 2 of 802.11ac wireless access points (AP) with a theoretical maximum throughput of up to 3.5Gbps.

NCaptain Ethernetew standards are needed because the existing Gigabit Ethernet is a bottleneck and current alternatives are not attractive. First, link-aggregating two Gigabit Ethernet connections for each Wi-Fi AP would need additional cabling and more expensive managed switches to support it. Using 10GbE would be overkill. Upgrading to 10GbE is a significant investment that includes new Category 6a or Category 7 cables, more power, and more cabling.

One faction, the MGBase-T Alliance, was formed in June 2014 and includes; Avaya, Aruba Networks (ARUN), and Brocade (BRCD) as well as component vendors Broadcom (BRCM) and Freescale Semiconductor. The other group known as the NBase-T Alliance was formed in October 2014. This faction consists of Cisco (CSCO), Intel, Xilinx (XLNX), Freescale, and Aquantia, a company that’s already making 2.5G/5G components.

Little agreement on standards

At the moment, the only agreement between the two factions is that 2.5Gbps and 5Gbps speeds are needed. The IEEE 802 LAN/MAN Standards Committee has set up the P802.3bz 2.5/5GBase-T Task Force to address this issue. The 2015 Q1 CommScope Standards Advisor reports that the 802.3bz Ethernet cablescommittee has decided so far that:

  • 2.5 GBase-T option will run on Cat 5e (Class D) 4 pair UTP up to 100M, and
  • 5 GBase-T option will run on Cat 6 (Class E) 4 pair UTP up to 100M.
  • There is no release date yet

The concern, however, is that vendors could jump the gun by shipping pre-standard products ahead of standards rectification, complicating matters and slowing down the development of the pertinent standards.

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Remember 802.11n? Pre-standard products? Given that there is no guarantee that systems built with components from the two groups will work together. Don’t jump the gun – waiting for the standard to solidify before buying into new 2.5G/5G Ethernet networking hardware.

For now, Dell’Oro Group analyst Alan Weckel told FierceCIO is that enterprises will probably be able to buy 2.5G/5G equipment starting in Q2 of 2015. 

 

Ralph Bach has been in IT long enough to know better and has blogged from his Bach Seat about IT, careers, and anything else that catches his attention since 2005. You can follow him on LinkedInFacebook, and Twitter. Email the Bach Seat here.

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| March 27, 2012
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186Gbps Transfer Sets Real-World Speed Record

186Gbps Transfer Sets a Real-World Fiber Speed RecordResearchers have set a new world record for data transfer. The new record was set at the SuperComputing 2011 (SC11) conference in Seattle, Washington. PhysOrg.com reports the international team set the speed record when they transferred 186 gigabits per second (Gbps) of data across 134 miles of an optical network for 11 hours.

Commercially available circuits

SuperComputing 2011The record-setting connection used a commercially available 100 Gbps circuit. The circuit was set up by Canada’s Advanced Research and Innovation Network (CANARIE) and BCNET, a non-profit, shared IT services organization. PhysOrg says the team was able to reach transfer rates of 98 Gbps between the University of Victoria Computing Center in Victoria, BC, and the Washington State Convention Center in Seattle. With a simultaneous data rate of 88 Gbps in the opposite direction, the team reached a sustained two-way data rate of 186 Gbps between two data centers. This broke the team’s previous peak-rate record of 119 Gbps set in 2009.

California Institute of Technology (Caltech) led the team of high-energy physicists, computer scientists, and network engineers from the University of Victoria, the University of Michigan, the European Center for Nuclear Research (CERN), and other partners.

transport large quantities of data across global networks of optical fibersAccording to PhysOrg, the achievement will help set up new ways to transport increasingly large quantities of data. More and more data traverse continents and oceans via global networks of optical fibers. The next generation of network technology needs new methods to transfer rates of 40 and 100 Gbps—that will be built in the next couple of years.

Our group and its partners are showing how massive amounts of data will be handled and transported in the future,” Harvey Newman, professor of physics and head of the high-energy physics (HEP) team told PhysOrg. “Having these tools in our hands allows us to engage in realizable visions others do not have.”

“The 100 Gbps demonstration at SC11 is pushing the limits of network technology by showing that it is possible to transfer petascale particle physics data in a matter of hours to anywhere around the world,” adds Randall Sobie, a research scientist at the Institute of Particle Physics in Canada and team member told PhysOrg.

The speed record equipment was not sexy

memorex guyExtremeTech points out that the achievement is quite significant. It is significant because the scientists used a commercially available 100 Gbps link and not “over private networks under laboratory/testbed conditions.” The equipment was not particularly sexy either. ExtremeTech lists Dell (DELL) servers with Intel (INTC) Sandy Bridge-based server motherboards with PCIe 2.0 and 3.0 solid-state drives. They used 10 and 40 Gbps LAN connections, and Force10 Z9000 and Brocade (BRCD) MLXe-4 switch-routers. The gear was able to achieve a disk to disk transfer rate of 60 Gbps, around 7.5 gigabytes per second. The 186 Gbps record was a memory-to-memory transfer between the servers. The max per-computer speed was 35 Gbps. Tested.com calculates that 4.42 petabytes traveled across the network during the transfer test.

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So why does anyone need to move two million gigabytes per day? This is fast enough to transfer nearly 100,000 full Blu-ray disks—each with a complete movie and all the extras—in a day.

CERN needs faster transfer rates. CERN needs to move the huge amounts of data coming from the Large Hadron Collider (LHC). The LHC has already generated more than 100 petabytes of data. The data is processed, distributed, and analyzed at 300 computing and storage facilities at laboratories and universities around the world. Scientists believe the data volume will rise a thousand-fold as physicists crank up the collision rates and energies at the LHC in their attempt to cause the end of the world (Not)

FierceTelecom predicts that service providers will deploy 100Gig when the price of 100Gig is double the price of 40Gig. They believe that will take place in 2013.

This massive amount of bandwidth running on commodity Internet pipes with available hardware seems to spit in the eye of current bandwidth providers who can’t seem to provide a 10 Mbps circuit reliably.

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Ralph Bach has been in IT long enough to know better and has blogged from his Bach Seat about IT, careers, and anything else that catches his attention since 2005. You can follow him on LinkedInFacebook, and Twitter. Email the Bach Seat here.

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