Tag Archive for 802.11ac

| September 24, 2018
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AT&T Still Trying BPL

AT&T Still Trying BPLFresh off its dismantling of net neutrality and its drunken binge of bribing its staff, AT&T (T) has launched two field trials of its AirGig technology, fueling hopes it can gain broader acceptance of its version of the failed broadband over powerline (BPL) technology. The AirGig plan, as AT&T explained in 2016, is to use millimeter-wave radio signals (above 24 GHz) to travel along power lines. Radios on the power lines would regularly refresh the signal as it travels.

At&T kogoFirecetelecom reports that the first trial was with an electricity provider outside the U.S., and the second trial is underway with Georgia Power. Stopping short of revealing a service rollout plan, AT&T will take what it learns from the trials and continue to develop AirGig. Based on its evaluation of the current trials, AT&T will look at expanding more advanced BPL technology trials in other locations. AT&T told Firecetelecom that while “there’s no timeline yet for commercial deployment, we’re encouraged and excited by what we’ve seen so far.”

The service is bullish on AirGig. The telco is touting AirGig’s potential to deliver 1 Gbps speeds via a millimeter-wave signal guided by power lines. Firecetelecom says AT&T’s Ultimate goal with AirGig is to accelerate broadband deployments.

Broadband over power line (BPL)While there have been plenty of BPL failures, AT&T claims AirGig is different. They say it is more efficient than earlier generations of BPL because it runs along, and not within, the medium voltage power lines. The technology differs from earlier BPL technologies, which traveled with the current.

In order to roll out Airgig, AT&T had to develop several new BPL innovations to distribute signals from the power lines to homes and businesses. AT&T labs developed a Radio Distributed Antenna System (RDAS), which uses low-cost plastic antennas, aka mmWave surface wave launchers, along with inductive power devices, which receive power without direct electrical connections (for simplified installation).

The RDAS will reconstruct signals from multi-gigabit mobile and fixed deployments. Those data signals are then transmitted using mmWave over power lines. The mmWave surface wave launchers are inductive power devices that create multi-gigabit signals that travel along or near the medium-voltage wire, not through it.

Maxwells EquationsThe data signal uses the existing pole infrastructures mostly line-of-sight wire paths act as a waveguide that channels the signal and improves the transmission quality, according to Mark Evans, a director on AT&T’s AirGig team. A waveguide is a structure (like an electrical wire) that restricts how much waves can expand over distance, thereby minimizing energy loss. AT&T radio technology engineer Peter Wolniansky explained in a demo that electromagnetic physics make it work,  “The signal energy clings like a glow to this wire, … It’s bound by Maxwell’s equations to stick to this wire.

Millimeter waves are radio waves from 24-300 GHz. The benefit of using these high-frequency bands is access to high bandwidth, between 100-800 MHz, which is 20-100x more than today’s common cellular systems.

AT&T plans to put wireless stations periodically along the route to provide the last-mile connections. For that last communication link to a home or business, AT&T will use more conventional wireless equipment. Customers would use 5G CPE equipment to connect to the AirGig data flow. Once the CPE has received the signal, it can use Wi-Fi (802.11ad or 802.11ac) or an LTE femtocell unit to connect to the end users’ smartphones, tablets, laptops, television, autonomous vehicles or other IoT devices. CNet quotes Mark Evans, a director on AT&T’s AirGig team.”We’re aiming to be ready to deploy it commercially in the 2021 timeframe.

CNET also quotes Gordon Mansfield, AT&T’s vice president of converged access and devices who says they are moving forward. He confirmed that AT&T has contracted with manufacturers to build more refined hardware for a new round of AirGig testing most likely in 2019.

At&T Airgig eggsA key part of the AirGig technology for AT&T is that it is easy to install. Antenna modules — AT&T calls them eggs — clamp in pairs on the power line extending each direction from the power pole. The devices can power themselves via inductive power devices without a direct electrical connection. The eggs configure themselves automatically, and the early test showed it takes people 10 minutes to hook up to the network, said AT&T Chief Technology Officer Andre Fuetsch.

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Kudos to AT&T for trying to figure out how to get everybody else to do their work just like Tom Sawyer..

AT&T can use the existing electrical right of way to bypass local municipality requirements, a long-running tactic of AT&T.

AT&T does not want to be in the business of connecting customers. They want to use the electric company’s infrastructure for free because fiber optic cable is expensive to bury underground or string along telephone poles.

AT&T will be using totally free unlicensed spectrum to sell access back to us at a huge profit.

They don’t even want to pay for electricity to run the equipment. They are using inductive power right off the mainline so it is not metered, which means everybody will have to pay.

 

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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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| March 1, 2018
Comments Off on MIMO Antennas Explained

MIMO Antennas Explained

MIMO Antennas ExplainedWave 2 of the IEEE 802.11ac Wi-Fi standard has been out for a while now. Wave 2 Wi-Fi can support speeds up to 2.3 Gbps. One of the techniques used to generate the increased speeds of the 802.11ac networks is multi-spacial streams or several streams of the same Wi-Fi signal radiating out from several antennas. The multiple antennas are the most noticeable indicator that an access point is 802.11ac capable, especially in the consumer market.

Multiple-Input Multiple-Output

The technology behind using several antennas is called Multiple-Input Multiple-Output (MIMO). MIMO antennas have two or more antennas in a single physical package and are designed for use in IEEE 802.11n/ac Wi-Fi networks. MIMO makes antennas work smarter by utilizing multiple antennas to combine data streams arriving from different paths and at different times to increase data throughput and range compared to a single antenna using the same radio transmit power. By transmitting multiple data streams at the same time, wireless capacity is increased.

Additionally MIMO antennas improve link reliability and experience less fading than a single antenna system. MIMO antennas use spatial diversity technology, which puts surplus antennas to good use. When there are more antennas than spatial streams, the antennas can add receiver diversity and increase range.

Radio-wave multipath

Asus AC5600 routerMIMO technology takes advantage of a natural radio-wave phenomenon called multipath to improve wireless performance. In the past, multipath caused interference and slowed down wireless signals. With this iteration, Wi-Fi takes advantage of multipath. With multipath transmitted information bounces off walls, ceilings, and other objects, reaching the receiving antenna multiple times via different angles and at slightly different times

MIMO technology takes a single data stream and breaks it down into several separate data streams and sends it out over multiple antennas. This technique provides redundancy. The receiving MIMO antenna will “look” at each stream being sent to determine the strongest one to choose.

Legacy wireless devices use Single-Input Single-Output (SISO) technology. These devices cannot take advantage of multipath, and can only send or receive one spatial stream at a time.

802.11ac Wave 2 MIMO

A new version of MIMO has been developed. TechHive reports that Multi-user multiple-input, multiple-output (MU-MIMO) technology, enables AP’s to transmit and receive data from multiple Wi-Fi devices at the same time. Although the devices must also support MU-MIMO to utilize it, they aren’t required to have multiple antennas.

MU-MIMO was introduced with 802.11ac Wave 2. Wave 2 MU-MIMO support is required on both the access point and client device to work. It operates in the downstream direction, access point to the client, and allows an access point to transmit to multiple client devices simultaneously. This means networks with a dense number of users in an area, such as public Wi-Fi hotspots, could be able to handle more Wi-Fi devices.

TechHive warns the biggest caveat of MU-MIMO is it doesn’t directly improve the wireless speeds of uplink connections.

Only a handful meet the criteria today

MU-MIMO technologyIt’s also important to note that the only way to gain the full benefit of MU-MIMO is when the technology is supported on both the access point and the device that’s connecting to the AP. So in addition to having an 802.11ac adapter onboard, the client must explicitly support MU-MIMO—there are only a handful of adapters that meet that criteria today.

Finally, TechHive says MU-MIMO works best with stationary Wi-Fi devices. If users are walking around while watching a video on a smartphone or tablet, they are not going to get the full benefit of MU-MIMO even if that device supports it. Your router might even limit that connection to using SU-MIMO, so that the connection doesn’t negatively impact stronger MU-MIMO connections.

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The client issue is the main reason 802.11ac Wave 2 will not be widely used in the enterprise. it is a big issue to keep the clients up to date to match the AP version. In fact, Zeus Kerravala at NetworkWorld points out that many of the high-volume manufacturers, such as Apple and Samsung, are skipping 802.11ac Wave 2 and plan to support IEEE 802.11ax in the future.

So skip Wave 2 devices in the enterprise and stick to an 802.11ac Wave 1 AP, and get exactly the same performance as its higher-priced Wave 2 counterpart.

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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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| November 17, 2015
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Sun Setting on Cat 5e

Sun Setting on Cat 5eThe sun is setting on the Cat 5e cabling standard. The long-standing standard defined how most commercial spaces around the world were cabled for nearly 20 years. Starting in 2017 Cat 5e will be considered obsolete for new installations following a decision by the ISO/IEC cabling standards body.

recommendation for Category 6AIn a recent blog post at CommScope (COMM), the ISO cabling standards body JTC1/SC25 WG3 working group agreed to raise the minimum horizontal cabling requirement. The new standard is stated in ISO/IEC 11801-2. Office space requirements change from Class D (Category 5e) to Class E (Category 6). It includes a recommendation for Class EA (Category 6A). Cat 6A will enable a smooth migration to 2.5, 5, and ultimately 10 gigabits per second (Gbps). In the drafts of 11801-5 (data centers) and 11801-6 (distributed services), the minimum requirement is already Class EA cabling.

Ethernet and IP communications everywhere

The original ISO/IEC 11801 standard enabled the explosive growth and mass deployment of Ethernet and IP communications everywhere. In its first edition, the author says the standard defined Class D balanced cabling based on Category 5 copper components. This standard offered an upgrade path from 10 to 100 megabits per second (Mbps) up to 100 meters. At that time, some experts and industry observers argued that 100 Mbps (100BASE-T) to the desk was overkill for the typical office user.

handful of cablesToday, 100BASE-T technology is in a rapid market decline. 100BASE-T is being replaced with 1000BASE-T (1 Gbps) according to the article. 1000BASE-T is commonplace for desktop and laptop PCs. It also benefits a wide range of other devices such as phones, cameras, and wireless access points (WAPs).

The 11801 standard now includes more cabling classes that were introduced to enable support of up to 10 Gbps. The new classes include Class E (Category 6), Class F (Category 7). Even more recently, Class EA (Category 6A) and Class FA (Category 7A).

Technology trends

According to the CommScope blog, a number of technology trends made ISO choose to upgrade the minimum recommendation for horizontal cabling in offices. Some of the trends recognized by the committee that are driving the adoption of speeds beyond one Captain Ethernetgigabit on the horizontal cabling include:

The rapid growth of BYOD is driving infrastructure upgrades to accommodate IEEE 802.11ac. As I have covered before, new IEEE specifications are being developed to accommodate 802.11ac wireless. 2.5GBASE-T is targeted at installed Class D cabling and 5GBASE-T is targeted at installed Class E cabling. It is expected that a sizable percentage of the installed base will be able to support the faster speeds, however, some installed Class D and Class E systems may require some mitigation steps.

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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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| April 28, 2015
Comments Off on Wi-Fi Marches On

Wi-Fi Marches On

Wi-Fi Marches OnKevin Fitchard at GigaOm lays out where Wi-Fi is headed. Now that the second wave of 802.11ac Wi-Fi equipment is hitting the market, new pans are happening. The Wi-Fi Alliance and the Institute of Electrical and Electronics Engineers (IEEE) have begun to look ahead to 802.11ac successor. This time around, the wireless industry is turning its focus away from overall network capacity to real connection speed to the device.

IEEE logoMr. Fitchard explains that the huge gigabit-plus numbers often attributed to 802.11ac can be a bit misleading. They represent the overall capacity a Wi-Fi network can support. For instance, 1.3 Gbps in today’s most advanced routers, but only in the rarest of circumstances would any single device actually be able to connect at such high rates. The author argues that 802.11ac technologies improvements will be able to pack more high-speed connections into a single router and take advantage of bigger swaths of unlicensed spectrum.

Fair share

However, individual connections are still peaking at just over 300 Mbps. Assuming the broadband connection that can even support those speeds. Typical connection speeds are far slower. 802.11ac channel widthWith 802.11ax, though, wireless engineers are making sure the individual, not just the network, gets its fair share of attention, said Greg Ennis, VP of Technology for the Wi-Fi Alliance.

Wi-Fi Alliance logoThough the IEEE is still in the early stages of developing the 801.11ax specifications (we likely won’t have a ratified standard until at least 2018), it has begun setting priorities for the new technology, the Wi-Fi Alliance’s Ennis said. And at the top of that list is a 4X increase in speed to the device, possibly pushing individual device connections into the gigabit range.

MIMO-OFDA

GigaOm speculates that the IEEE is hoping to do this with a new radio technology called MIMO-OFDA. MIMO, or multiple input-multiple output, uses multiple antennas to send multiple streams of data to the same or different devices, while OFDA is a variant of the orthogonal frequency division multiplexing (OFDM) technologies used in 4G mobile and earlier Wi-Fi standards. The idea is to create a more powerful and efficient radio that can shove more bits into the same transmission. That would create a bigger data pipe to the individual devices, which would, in turn, add up to greater overall network capacity and better Wi-Fi performance even in the sketchiest of conditions, Mr. Ennis said. “The goal here is not just to increase average throughput, but the average throughput users would actually see in the real world, even in the densest environments,” Ennis said.

IEEE 802.11axChinese equipment maker Huawei (002502) — which is heading up the IEEE 802.11ax working group — is already doing trials of MIMO-OFDA systems and it’s hitting 10.53 Gbps in the lab using Wi-Fi’s traditional 5 GHz band. Whether that means a 10 Gbps to your smartphone or tablet remains to be seen, but it hardly seems relevant given it’s difficult to comprehend what any device could possibly do with a 10 Gbps connection (much less a home broadband connection capable of supporting a high-capacity link).

 

IEEE 802.11ah

Faster simultaneous Wi-Fi connections

But if 802.11ax lives up to its promise, the author says it should be able to squeeze a lot more and a lot faster simultaneous connections out of a single router or hotspot, which would mean a far better experience for everyone on a crowded network. Though the IEEE won’t ratify 802.11ax until 2018 or later, we might see the Wi-Fi Alliance certify “draft-ax” devices and equipment beforehand just as we saw “draft-n” and “draft-ac” devices before their respective 802.11 standards were finalized. It all depends on how far the wireless industry has progressed with the underlying technology in the coming years, Ennis said. A range comparison for different Wi-Fi technologies. And long before we see the “ax” suffix stamped onto any gadget or router, other combinations of the Wi-Fi alphabet will make an appearance.

The Alliance will begin certifying the first 802.11ad, or WiGig, devices next year, supporting extremely close range but very high-capacity links between gadgets and peripherals. A bit further down the road is 802.11ah, which will take Wi-Fi to the 900 MHz band where it will provide narrowband but long-range connectivity to the internet of things.

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Techie wireless alphabet  – IEEE, N, AC, AD, AH, AX, MIMO, OFDM, EI, EIO, O!

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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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| 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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