Tag Archive for IEEE

| October 17, 2013
Comments Off on A Close Look at 802.11ac Wi-Fi

A Close Look at 802.11ac Wi-Fi

TA Close Look at 802.11ac Wi-Fiech pundits argue that the new Wi-Fi standard 802.11ac will replace wired gigabit Ethernet networking. 802.11ac is a supercharged version of 802.11n, offering link speeds ranging from 433 Mbps, up to multiple gigabits per second.

Wi-FiTo make 802.11ac dozens of times faster than 802.11n, the new standard works exclusively in the 5GHz band uses a huge chunk of bandwidth (80 or 160MHz), operates in up to eight spatial streams (MIMO), and a technology called beamforming.

At its core, 802.11ac is essentially an updated version of 802.11n, according to Sebastian Anthony the author of an ExtremeTech article “What is 802.11ac WiFi, and how much faster than 802.11n is it?” 802.11n was a huge performance increase over 802.11a and g. 802.11n introduced some key technologies that brought massive speed boosts. Where 802.11n had support for four spatial streams (4×4 MIMO) and a channel width of 40MHz, 802.11ac can use eight spatial streams and has channels up to 80MHz wide, which can be combined to make 160MHz channels. This means that 802.11ac has 8 x 160MHz of spectral bandwidth to play with, versus 4 x 40MHz – a huge difference that allows 802.11ac to send vast amounts of data across the airwaves.

Beamforming

What is new in Wi-Fi

802.11ac also introduces 256-QAM modulation (up from 64-QAM in 802.11n), which sends 256 different signals over the same frequency by shifting each signal to a slightly different phase. In theory, this quadruples the spectral efficiency of 802.11ac over 802.11n. Spectral efficiency is a measure of how well a given wireless protocol/modulation/multiplexing technique uses the bandwidth available to it.

802.11ac also introduces standardized beamforming Matthew Gast, Director of Product Management at AeroHive Networks published an article, “Investing in Beamforming: Is it worth it?” that explains beamforming.

Aerohive logoRather than transmitting a radio signal in all directions, beamforming figures out where the receiver is, and focus the energy towards the receiver. Instead of spraying radio energy all over the place, send packets as a “rifle shot” directly to the receiver’s antenna Mr.Gast explains.

Beamforming is a two-step process: First, figure out how to “aim” the transmission at the receiver, and second, send the transmission. With beamforming, a transmitter is betting that by paying the cost of the channel measurement process, the data transmission that follows will speed up enough to pay off the cost.

802.11n Beamforming was non-standardized, in 802.11ac, there is only one method of beamforming, called the Null Data Packet (NDP). (rb- Read the AeroHive article for a full description of NDP)

Aerohive’s Gast concludes that by steering the energy towards a receiver, beamforming enables you to take a step up to a higher data rate. Mr. Gast estimates that 802.11-based beamforming gives you a 3-5 dB gain.

802.11ac is speedyIn theory, at the 5GHz band with beamforming, 802.11ac should have the same or better range than 802.11n  However, Mr. Anthony says the 5GHz band, has less penetration power so it doesn’t have the same range as 2.4GHz (802.11b/g). The ExtremeTech article concludes that’s an acceptable trade-off: there simply isn’t enough spectral bandwidth in the cluttered 2.4GHz band to allow for 802.11ac’s gigabit-level speeds.

ExtremeTech‘s Anthony calculates there are two answers to how fast is Wi-Fi 802.11ac, the theoretical max speed, and the practical max speed that mere mortals will get surrounded by lots of signal-attenuating obstacles.

He calculates the theoretical max speed of 802.11ac is eight 160MHz 256-QAM channels, each of which is capable of 866.7Mbps – a grand total of 6,933Mbps, or just shy of 7Gbps. That’s a transfer rate of 900 megabytes per second. Compare this with 802.11n’s max theoretical speed, which was 600Mbps. He then says in practice, the current max speed of 802.11ac devices is 1.7Gbps.

ExtremeTech points out there will be a second wave of 802.11ac devices – due in 2014 after the standard is finalized – before 160MHz channels and multi-gigabit speeds become a reality. The max speed over an 80MHz channel is 433.3Mbps, and there aren’t any 802.11ac chipsets that support up to eight streams.

Broadcom logoKevin Fitchard at GigaOM reports that recently the Wi-Fi Alliance kicked off its 802.11ac certification program. First to get the official Wi-Fi stamp of approval was the Samsung Mega 6.3, followed by two other Samsung models.

As with the 802.11n certification process, the Wi-Fi equipment makers are moving faster than the standards bodies. The IEEE is actually still putting the finishing touches on the 802.11ac standard, which is not due until 2014.

Wi-Fi certifiedThe Wi-Fi Alliance expects the first batch of ac devices will support speeds of 433 Mbps and progress into more advanced levels of the standard. The Alliance has pre-certified systems from companies like Broadcom (BRCM), Qualcomm (QCOM), Realtek, and Marvell (MRVL). Cisco (CSCO) was one of the first vendors to get an access point certified.

“AC is going into mobile and portable devices first…,” Wi-Fi Alliance Marketing and Program Management Director Kelly Davis-Felner said. ABI Research estimates that 40 percent of all ac devices shipped in 2013 will be handsets.

rb-

Wi-Fi will replace wired Ethernet networkingWhile tech pundits argue that the new 802.11ac Wi-Fi will replace wired gigabit Ethernet networking at home and in the office. While the consumerization of IT and BYOD are strong forces, the life-cycle of cabling infrastructure is 25 years, a cost not lightly abandoned in the walls. it is more likely to happen at home first. Who wants all the crappy wires running all over the house?

Related articles

 

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.

Category: wi-fi | Tags: , , , , , , , , , , , , , , , , , , ,
| September 12, 2013
Comments Off on PoE Overworked

PoE Overworked

PoE OverworkedGary Audin at No Jitter warns that Power over Ethernet (PoE) is not always a plug-and-play environment and PoE should be monitored, managed, and efficient. In this article, Mr. Audin observes that PoE has evolved into an electrical power device utility platform. POE started out as a centralized power source for IP phones, backed up with an Uninterruptible Power Supply (UPS). (rb- Click here and here for my overview of PoE) Since those early Cisco dominated days. The article says PoE now is called upon to support wireless access points; environmental controls; point, tilt, and zoom cameras; lighting control; clocks; door controls; Bluetooth devices; RFID; now laptops, and still more to come.

The LAN switch is the PoE source, but the article warns it can be overwhelmed with the power drain, which produces headaches for IT. Unless properly managed, the PoE function can experience:

  • power drainA blown-out power supply. Smoke is an indicator of this condition.
  • Reduced power to all devices with degraded service from all the attached devices.
  • An added PoE device does not work.
  • The more power is drawn by PoE, the shorter the UPS battery life. The original UPS design could last 20 minutes. Added PoE devices could shorten this to 3 minutes.

PoE IP phones and other devices can signal to the PoE network what class of device it belongs to and how much power it may need. Class 0 devices, usually older devices, do not indicate their PoE power requirements. These devices may draw any power level from none to maximum. The other standard classes, 1-3, range from very low power to mid-level power consumption.

Class 4 is a newer class of device requiring PoE+ (802.1at) and needs to draw more than the 12.95 Watt maximum provided by the original standard PoE. Class 4 devices must be powered by PoE+ ports and may not function correctly on an 802.3af PoE port. Most IP phones are in class 2. IP phones with color screens and other advanced features may be categorized as class 3 devices.

PoE classes

PoE Access Points Wireless LAN access points are also common PoE devices, many of which started out as class 2 and 3 devices. As the wireless speeds increased, so did the power requirements. The 802.11ac standard means that the access points (AP) will have a 1 Gbps connection back to the switches and routers.

site-surveyAt issue is the PoE required. It is likely that each AP could need 20 to 30 watts, the limit that the 802.1at PoE+ standard delivers. Many installed switches cannot support PoE+. So the enterprise has to buy new switches or power supplies or power injectors. (rb- add this to your site-survey when you plan to implement 802.11ac)

Mr. Audin spoke to Tim Titus, CTO, and founder of PathSolutions, (they happen to sell a network management tool) about what he considers a good approach to monitoring and managing POE. He told No Jitter,

“Regardless of whether there are any PoE or PoE+ devices on a network, it can be very helpful to monitor the health of our network equipment’s power supplies. The best monitoring system watches the status and power consumption of each power supply, what percentage of utilization it is running, and which interfaces are drawing power, so power policing can be achieved.”

He provided this example of missing power management.

“Keeping an eye on power supplies avoids unpleasant discoveries. One unlucky network administrator had two power supplies installed in a network chassis (one primary and one backup). Unfortunately, when the primary power supply stopped working, nobody knew, since the backup power supply was doing its job of keeping everything running. The problem wasn’t noticed for over six months. Nobody was in the empty remote wiring closet to notice the lack of lights on the power supply. The users remained blissfully unaware of impending doom until the wee hours of a weekend when the second power supply was shut off by a circuit-breaker trip!” 

Mr. Titus pointed out to Mr. Audin, that monitoring should happen at the port level,

“Not only will a monitoring system show you what mode a PoE port is operating in, but it should also provide a view of relevant error counters.

  • MPS Absent and Invalid Signature errors frequently point to broken or defective powered devices.
  • Overload conditions and short-circuits typically point to wiring problems (or somebody re-wiring devices in use).
  • Denied errors can point to devices asking for more power than the switch has available, and may indicate that it is time to consider adding another power supply to a large Ethernet chassis.”

How did that happen?

Finally, many network engineers try to buy limited PoE due to the cost premium of POE ports, only to find that half of their PoE ports are used by non-PoE devices such as PCs. With a monitoring tool, the engineers could have avoided buying expensive PoE ports or purchased less expensive “ordinary” Ethernet ports.  The engineers should have an up-to-date PoE port inventory and use it to avoid over-buying the PoE by playing safe in their design. (rb- Been there done that, I’ve been in many customer’s closets and found POE switches full of PC and printer access ports.)

rb-

The author warns not to assume that PoE is always a plug-and-play environment. PoE should be handled like a utility–monitored, managed, and efficient.

I have tried to build custom fields by working with reports in SolarWind’s Orion by working with MIBs, it’s not the funnest thing in the world. I wonder if this product does a better job.

Related articles

 

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.

Category: Uncategorized | Tags: , , , , , , , , , , , , , , ,
| September 3, 2013
Comments Off on 802.11ac Wi-Fi Clears the Way for Collaboration

802.11ac Wi-Fi Clears the Way for Collaboration

802.11ac Wi-Fi Clears the Way for CollaborationThe emerging gigabit 802.11ac, Wi-Fi standard is the current darling of the hype machine. The standard will be finalized in February 2014. However, that has not stopped manufacturers from shipping 802.11ac routers, access points, and mobile devices. Shortel (SHOR) recently provided their opinion on what this means for your business.

IEEE 802.11acThe article points out that more people are using mobile apps and devices. Shortel calculates that a typical worker may have three IP addresses, while digital natives may have up to six IP addresses. These stats suggest that mobility has become a must-have and the author claims that 802.11ac can meet the needs of increasing mobility because 802.11ac is faster, more reliable, and delivers more Wi-Fi capacity. 802.11ac is:

  • Faster – 802.11ac is three times faster than 802.11n Wi-Fi. 802.11ac will deliver up to 1.3 Gbps, which is about three times faster than 802.11n. This capacity will be ideal for real-time applications, such as IP voice and streaming video. Faster data throughput means better battery life for mobile devices, too.
  • More reliable – 802.11ac is more reliable with less interference. 802.11ac operates at 5 GHz, which is far less crowded than the 2.4 GHz band that by 802.11b/g/n access points — as well as cordless phones, automatic garage door openers, and other home appliances. That means that there’s less interference from other Wi-Fi-enabled devices, which will result in a better user experience.
  • Improved throughput. 802.11ac uses multiple antennas for transmitting and receiving RF signals, and that means better data throughput. More specifically, MIMO, or Multiple-Input and Multiple-Output, is key to providing wireless performance that is more switch-like, compared to the shared media nature of 802.11n.

W-Fi Alliance logoShortel believes that Gigabit Wi-Fi can be a real asset for unified communications, streaming media, and other bandwidth-hungry apps. They plan to use the greater capacity of 802.11ac to support more devices and more apps. In the workplace, teams want to engage and share without hassle using modern collaboration tools with the devices of their choice creating the need for BYOD.

The newest generation of workers are digital natives, who are more inclined to use videoconferencing for quick chats or to share ideas. In addition, many people use tablets to stream media, and more organizations are turning to streaming media over Wi-Fi for digital signage, training, company meetings, and customer support. And those bandwidth-hungry applications will love the new gigabit Wi-Fi.

Wave 1 802.11ac only offers incremental benefits over 802.11nShoretel reassures those that have deployed an 802.11n WLAN recently, you don’t need to be in a hurry to move to 802.11ac. You can be confident in the investment that you made, as the first-generation 802.11ac will offer only incremental benefits over 802.11n. But if you are replacing old Wi-Fi or expanding your wireless LAN or looking to downsize your wired network in favor of wireless, you should weigh the options between 802.11n and the new 802.11ac.

rb-

802.11ac will only get faster, the theoretical max speed of 802.11ac is just shy of 7Gbps, which you will never see in the wild, but don’t be surprised to see link speeds of 2Gbps or more in the next few years. At 2Gbps, you’ll get a transfer rate of 256MB/sec.

To reach such Wi-Fi speeds, chipset and device makers will have to figure out how to make second-generation chipsets with four or more 802.11ac streams in software and hardware. The engineers at Broadcom (BRCM), Qualcomm (QCOM), Marvell (MRVL), and Intel (INTC) are already working on ways to implementing four and eight-stream 802.11ac solutions. A lot of work will need to be done by the chipset and device makers to make sure that advanced features, such as beamforming, comply with the standard and are interoperable with other 802.11ac devices.

In general, then, you can certainly expect some impressive speeds from 802.11ac in situations where you don’t need the performance and reliability of wired GigE. But I do not believe that 802.11ac will replace a wired Gigabit Ethernet network just yet.

What do you think?

Related article

 

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.

Category: Uncategorized | Tags: , , , , , , , , , , , , , , , , ,
| April 30, 2013
Comments Off on 400 Gbps Ethernet Coming

400 Gbps Ethernet Coming

400 Gbps Ethernet ComingThe Institute of Electrical and Electronics Engineers (IEEE), launched an IEEE 802.3 “Standard for Ethernet” study group to explore the development of a 400 Gbps Ethernet standard. The new standard will look to efficiently support an ever-increasing, exponential network bandwidth growth. Ethernet which is celebrating its 40th anniversary this year is defined by the IEEE 802.3 standard. Ethernet is a pervasive standard, driven by the ever-growing needs of the local area, access, and metropolitan area networks around the world.

Expanded reliance on Ethernet

IEEE logoBeyond traditional networks, Help Net Security reports that new application like industrial and automotive networking are expanding their reliance on Ethernet. To better address the needs of these areas, the IEEE 802.3 Ethernet standard is constantly evolving and expanding. John D’Ambrosia is the chief Ethernet evangelist, CTO office, Dell, and chair of the new IEEE 802.3 400 Gbps Ethernet Study Group. He says Ethernet must evolve. “Traffic is growing everywhere … and it’s critical that we move now to create a plan for the Ethernet ecosystem to evolve beyond today’s capabilities, in order to accommodate the burgeoning bandwidth tsunami.

In August 2012, IEEE forecasted that networks will need to support 58% compound annual growth rates (CAGRs) on average. The growth will be griven by simultaneous increases in users, access methodologies, access rates, and services (such as video on demand and social media). IEEE report that networks would need to support capacity requirements of 1 terabit per second (Tbps) in 2015. That number grows to 10 Tbps by 2020 if current trends continue. Alan Weckel, vice president of enterprise and data center market research at Dell’Oro Group said in the article, “Ethernet is an arena of constant innovation, driven by the market demand for support of new ever-increasing bandwidth speeds, as well as new protocols, applications, and media types.

Standards-based networking

EthernetStandards-based networking has worked so far and will be needed as 400 Gbps Ethernet evolves. Mr. Weckel adds, “Global bandwidth requirements are continuing to grow exponentially … Standards-based solutions are integral to maintaining business growth across the Ethernet ecosystem.

David Law, chair of the IEEE 802.3 Ethernet Working Group and distinguished engineer with HP Networking explains in the article, “An IEEE 802.3 study group is formed when there is interest in developing a request to initiate an IEEE 802.3 Ethernet standards-development project.

IEEE 802.3Dell’s D’Ambrosia told Wireless Design Magazine that a host of new technologies and applications have proliferated in the marketplace since the most recent speed jump to 100 Gb/s Ethernet was ratified in 2010. He reminded NetworkWorld that “The iPhone didn’t exist when we started 100G.” Mr. D’Ambrosia concludes that the impact has been felt throughout the Ethernet ecosystem. Data centers, for example, where Ethernet is the primary interconnect technology, are at the center of the bandwidth storm. Pressure is intensifying from all directions:

  • Outside the data center, driven by increasing numbers of users armed with more devices capable of ever-increasing bandwidth consumption;
  • Within the data center, driven by more and faster storage and server technologies, and
  • Across data centers, driven by new applications, new databases, and new architectures.
Related article:

 

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.

Category: Uncategorized | Tags: , , , , , , ,
| April 2, 2013
Comments Off on What is 4G Mobile Wireless

What is 4G Mobile Wireless

What is 4G Mobile WirelessWireless operators continue to roll out mobile networks built with acronym-heavy standards such as 4G, Long Term Evolution (LTE), IEEE 802.16 (WiMAX), or HSPA+. Stacey Higginbotham at GigaOM says it’s hardly a surprise that every press release is touting 4G, which presumably stands for the fourth generation wireless network. Only, according to InfoWorld, the truth is, neither WiMax nor LTE qualify as 4G technologies, according to the International Telecommunications Union Radiocommunication Sector (ITU-R). For a service to be called 4G by the ITU-R carriers will have to use one of two future mobile wireless technologies.

GigaOM reports that in October 2009, the ITU fielded 6 candidates that could meet the true definition of 4G mobile wireless. The main criteria required speed boosts, but more importantly, new technologies that make more efficient use of spectrum, as well as an ability to work with other radio access systems and fixed wireline networks. The standard also requires that equipment makers offer features that will help guarantee the quality of service on wireless networks. Of the 6 candidates, the ITU declared the upcoming called LTE-Advanced and WirelessMAN-Advanced – also known as IEEE 802.16m the only true 4G mobile wireless technologies.

True 4G wireless calls for peak speeds of 100 Mbps for mobile applications and 1 Gigabit per second for fixed networks. To do such speeds, operators will need five to ten times as much spectrum as most are using now to deploy LTE, as well as complex antenna configurations. The new 8×8 MIMO will need some new antennas at the tower and inside the mobile devices. Some operators won’t ever get to that point. Others might, but it’s going to take four or five years before people start rolling out anything like the ITU’s version of 4G mobile wireless according to the GigaOm article.

IEEE logoThe faux 4G we are getting now, comes in three flavors thanks to a bold marketing effort by T-Mobile writes Ms. Higginbotham. T-Mobile’s HSPA+ network is most assuredly 3G (or maybe 3.5G for some) but as its CTO, Neville Ray, argued with GigaOM founder Om Malik, its real-world mobile wireless speeds are better than those offered by WiMAX and are comparable to the real-world expectations of Verizon’s LTE network. The key to T-Mo’s experience lies in its spectrum resources. As a general rule, the more spectrum an operator has, the more lanes in its highway it can cram bits into. The blog says T-Mobile can use that spectrum to increase capacity or increase speeds. With plans to move from 21 Mbps to 42 Mbps speeds using HSPA+, T-Mo is going for speed to keep up with the wireless mobile Jones.

Laptop reports that other mobile wireless operators do not qualify as 4G either. “… Sprint and Clearwire’s Mobile WiMax (3 to 6 Mbps), T-Mobile’s HSPA+ (5 to 8 Mbps), and even Verizon Wireless’ LTE network (5 to 12 Mbps) don’t even come close to deserving the 4G moniker.

After all, marketers pushing LTE first starting waving the 4G mobile wireless flag several years ago, despite the ITU hadn’t yet decided if LTE was 4G. The first releases weren’t. We’ll have to wait for LTE-Advanced in about four or five years for true 4G. By then, it’s possible we’ll be dealing with 5G mobile wireless networks or something even better the marketers dream up. In the meantime, consumers will buy their faux 4G mobile wireless phones for their faux 4G mobile wireless networks and never sweat the difference GigaOm speculates.

The faux 4G networks are incremental improvements over 3G. As Tolaga Research analyst Phil Marshall told InfoWorld, these wireless mobile networks were designed from day 1 for data, and are all Internet protocol (IP) from end to end. That’s a huge improvement over 3G and it’s a marked change. Despite the improved architecture, Wi-Fi Net News asks if the spectrum is available to meet the 2015 rollout for real 4G. “It looks like the maximum speeds being discussed require extremely wide channels, like 100 MHz. That’s not impossible, but no U.S. carrier has 100 MHz in a chunk that it materializes. The FCC white-spaces rulemaking frees up a bunch of 6 MHz pieces, and that’s the last major realignment after DTV 700 MHz spectrum that I’m aware of. The definition of 4G may now be set, but the ability to roll out 4G at anything like the minimum speeds promised seems highly problematic even in five years.”

Related articles

 

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.

Category: Uncategorized | Tags: , , , , , , , ,
« Older Entries   Recent Entries »