The two main vibration types for light poles are shown in this figure. Both of these two vibration types will create sway that might affect the link performance for small cell microwave backhaul.
There is real concern from operators that utility, streetlight and traffic poles are not designed to meet the minimum twist and sway standards for deploying microwave solutions for small cell backhaul. Our research suggests that not all poles are created equal, however. Under certain circumstances these structures can be an option for deploying microwave backhaul for small cells.
Twist and sway requirements for towers and poles that support microwave backhaul hops are more stringent than for other RF equipment. This is especially true for deployments in frequency bands above 18 GHz where the antenna beamwidth is narrower than below 18 GHz. Standards such as the TIA-222-G set a minimum twist and sway that a structure should be able to endure for hosting a microwave installation. This creates concerns for operators interested in deploying microwave for small cell backhaul on structures including utility, streetlight and traffic poles that are not designed to meet this standard. Although the use of a sturdy structure is always recommended a close look at utility, streetlight and traffic poles suggests that under certain circumstances these structures can be an option for deploying microwave backhaul for small cell.
The installation of any equipment on existing poles—including small cell and backhaul radios and antennas—will necessarily change the weight and wind loading characteristics of the deployment pole. This will require a structural analysis to verify if the existing pole still meets the standards or the commercial criteria set by the pole manufacturer. For more information on Aviat’s analysis of pole sway for small cell backhaul see our PDF.
Marketing Engineering Specialist
Aviat Networks’ Packet Node IRU600 is an example of an all-indoor microwave radio, which is one choice wireless operators should consider for implementations in North America.
There’s a lot of buzz in the microwave industry about the trend toward all-outdoor radios, but those who haven’t been through LTE deployments may be surprised to learn that based on our experience deploying LTE backhaul for some of the world’s largest LTE networks, all-indoor is actually the best radio architecture for LTE backhaul.
We can debate today’s LTE backhaul capacity requirements, but one thing we do know is that with new advances in LTE technology, the capacity needed is going to grow. This means that microwave radios installed for backhaul will likely have to be upgraded with more capacity over time. Although people are experimenting with compression techniques and very high QAM modulations and other capacity extension solutions, the most proven way to expand capacity is to add radio channels because it represents real usable bandwidth independent of packet sizes, traffic mix and the RF propagation environment.
All-indoor radios are more expensive initially in terms of capital expenditures, but they’re cheaper to expand and (as electronics are accessible without tower climb) are more easily serviced. While an outdoor radio connects to the antenna with Ethernet or coax cable, indoor radios usually need a more expensive waveguide to carry the RF signal from the radio to the antenna. So you pay more up front with an all-indoor radio but as the radio’s capacity grows you save money. There are several reasons.
When everything related to the radio is indoors, you just have a waveguide and an antenna up on the tower. To add radio channels with an all-indoor radio you go into the cabinet and add an RF unit. With an outdoor radio, you have to climb the tower, which can cost as much as $10,000. Also, when you add a new outdoor RF unit you may have to swap out the antenna for a larger one due to extra losses incurred by having to combine radio channels on tower….(read the full story at RCR Wireless).
Senior Product Marketing Manager
- July 13, 2012
- 3GPP Long Term Evolution, 4G, backhaul, Broadband, Ethernet, FCC, Federal Communications Commission, FierceWireless, LTE, microwave, public safety, PublicSafety, Telecommunication, Telecommunications network, Time-division multiplexing
(Photo credit: Chance W. Haworth via Wikipedia)
Public safety agencies will soon experience a dramatic improvement in communications capabilities enabled by advances in technology. New broadband multimedia applications will give first responders and commanders alike far better situational awareness, thereby improving both the effectiveness and safety of all personnel charged with protecting the public.
The specific technology, now mandated by the U.S. Federal Communications Commission (FCC) for all new emergency communications networks, is Long Term Evolution, or LTE—a fourth-generation (4G) broadband solution. The FCC has also allocated licensed spectrum to ensure the best possible performance in these new networks. These FCC rulings support the goal of achieving an interoperable nationwide network for public safety agencies.
The FCC chose LTE based on its proven ability to support voice, video and data communications at remarkably high data rates that were previously only possible with wired links. Although there will be some differences in a nationwide public safety network involving capacity and coexistence with Land-Mobile Radio communications, lessons learned from LTE’s deployment in large-scale commercial mobile operator networks will help ensure agencies are able to achieve the FCC’s goal cost-effectively.
- July 10, 2012
- 3GPP Long Term Evolution, Africa, Ethernet, Internet Protocol, Kenya, Mobile network operator, Safaricom, tdm, Telecommunication, Time-division multiplexing, WiMAX
Burgeoning WiMAX and 3G data traffic from subscriber devices such as Safaricom’s Internet Broadband Dongle (with SIM Card) are driving the mobile operator to migrate from TDM to hybrid microwave backhaul. (Photo credit: whiteafrican via Flickr)
Migrating legacy mobile backhaul networks that were designed for TDM traffic to add support for high-speed Ethernet data for 3G and 4G mobile technologies is one of the biggest challenges for operators worldwide. Each case is unique and poses its own quirks and potential pitfalls. Mobile operators must juggle new technologies, cost pressures and the need to maintain existing services or risk driving customers to the competition.
For Safaricom, the leading mobile operator in Kenya and one of largest in all Africa, the case involved preserving its E1 capacity for voice calls and simultaneously adding Ethernet/IP bandwidth for burgeoning 3G and WiMAX data traffic. As many mobile operators have done in the past, Safaricom built its network over time. Many parts of the network are still legacy 2G TDM technology. However, things are changing rapidly, with 3G subscriber numbers up 85 percent in 2011 year over year.
Many of these subscribers are consuming ever-increasing amounts of data bandwidth. Safaricom’s TDM based backhaul, making use of Ethernet-to-E1 converters, is finding it hard to keep up with demand. To help resolve the situation, the operator called on Aviat Networks, one of its incumbent solution providers. Using its market leading hybrid radio solution, the modular Eclipse microwave networking platform, Aviat Networks enabled Safaricom to add IP data capacity as necessary while keeping E1 capacity for voice calls.
In addition, the stage has been set for Safaricom to make the eventual migration to all-IP backhaul. With the modular Eclipse platform, it can transition on its own schedule. For more information, read the complete Safaricom case study in the frame below or download the PDF:
A standard Quadrature Amplitude Modulation constellation (non-gray code) diagram showing a demonstrative 4-bit binary code pattern. (Phase offset and amplitude values may not represent those used in real life) (Photo credit: Chris Watts via Wikipedia)
There’s a new arms race in the microwave industry, and it’s over who can claim support for the highest QAM level. Now two vendors are out in the market fighting it out over who had 2048QAM first, yet go back a little more than 12 months and 512 or 1024QAM had barely hit the market. We even are seeing mentions of 4096QAM in some conference presentations. We here at Aviat Networks view these advances as a good thing for our industry, but this heavy marketing of 2048QAM does no one any favors, as it focuses purely on only one aspect of high modulations—capacity—and ignores several other aspects that need to be understood, namely:
- Capacity improvement diminishes with every higher modulation step
- High modulations come with much lower radio system performance—requires shorter hops and/or larger antennas
- High modulations are much more sensitive to interference—makes link coordination difficult (if not impossible)
- High modulations need higher Tx power, increased phase noise and linearity—increases radio design complexity cost
So as with most things that are presented as a cureall, higher order modulations are a useful tool to help operators address their growing backhaul capacity needs, but the catch is in the fine print. Operators will need to look at all the tools at their disposal, of which 1024/2048QAM is a useful option, albeit one that will require very careful planning and strategic deployment. In general, operators need practical solutions for capacity increases, as detailed in “Improving Microwave Capacity“. In fact, speaking of practicalities, the real challenges with LTE backhaul has very little to do with capacity…as detailed by this article. For the complete “Modulations Arms Race” article, click here.
Director, Corporate Marketing
Like building out the Interstate Highway System, the real challenge for LTE deployment in the U.S. lies in the actual construction. (Photo credit: Wikipedia)
Like the Interstate Highway system in the 1950s, building out a national LTE infrastructure in the U.S. is a major undertaking. The largest challenges in building out an LTE network consist of planning, staging and deploying the technology at maximum speed and with minimal costs. Mobile operators are in a tight race to build out LTE networks in the U.S. as quickly and cost-effectively as possible, and backhaul is a key component of the job.
There are more than 300,000 2G/3G cell sites in the United States; LTE penetration is at approximately 50,000 sites today. Mobile operators want to have 95% of their footprints covered with LTE within the next year or two, so a massive construction project lies ahead with a tight timeframe for completing it…see the entire article at Telecom Engine.
Senior Product Marketing Manager
- March 1, 2012
- 1024QAM, 3GPP Long Term Evolution, Aviat Networks, backhaul, Barcelona, Base station, Mobile World Congress, modulation, small cell backhaul, small cells, Wi-Fi, wtm 3200
¡Hola! again from the final day at Barcelona, where close to 1500 companies have been busily showcasing their products and services since Monday.
Once again microwave backhaul has featured highly with the main development being the widespread adoption of 1024QAM modulation. At least half a dozen new products now support this higher modulation level. Of course we are one of them, showing our new WTM 3200 all-outdoor radio. 1024QAM supports about 25 percent more throughput over the radio path compared to 256QAM, but it does come with a tradeoff in reduced system performance and increased interference sensitivity. These can be somewhat offset by using Adaptive Modulation, so if the link starts to struggle at 1024QAM it can drop back to a lower modulation until conditions improve.
Small cell backhaul has also been a hot topic, with many vendors jockeying for position in this emerging application. Small cells are tiny base stations that can be fitted to lamp posts or the sides of buildings, covering just a few hundred square yards/meters and would provide enhanced coverage and capacity to the network. There is talk of there being literally millions of these small cells being deployed over the next five years, starting in 2014 or so, and the big challenge will be backhauling all that traffic.
Multi-technology small cells (WiFi + LTE) are emerging to enable mobile offload directly at the outdoor mounted small cell. Offload solutions that offload traffic at the building and onto fiber/DSL are designed to relieve the RAN and backhaul networks. This approach however is designed to provide capacity relief to the RAN part of the network only and will use the same backhaul as LTE traffic. The intersection of mobile offload and outdoor mounted small cells will mean backhaul remains a critical part of the offload solution for some time to come.
As with last year, there is still a huge proliferation of new LTE-enabled smartphone and tablet devices. More connections bring more opportunities. This is good for our business as mobile operators will need to upgrade their networks.
Until next year!
- February 29, 2012
- 24 billion wireless connections by 2020, 3GPP Long Term Evolution, Barcelona, Connected Devices, Connected Life, Ford Motor Company, GSM Association, GSMA, Long Term Evolution, LTE, Mobile network operator, Mobile Operator Partnerships, Mobile Technology, Mobile World Congress, MWC12
Another update here from Mobile World Congress in Barcelona. This time we’d like to discuss a little about the trend toward using the next generation of mobile technology—LTE or Long Term Evolution—to support a growing number of connected devices across multiple different industries—not just the traditional mobile operator sector.
Across from our pavilion was the Connected Life booth that showcased how in the future, everyone and everything will benefit from a wireless connection. With more than 6 billion connections globally—and this is expected to grow to 24 billion in 2020—mobile is redefining and transforming the way we communicate and access information—cars, buildings, medical monitors, TVs, game consoles, consumer electronics and household appliances—even exercise equipment. It is all about seamless and intelligent connectivity between people, processes and products to be delivered when and wherever they are required.
By 2020, estimates place total worldwide wireless connections at around 24 billion counting devices such as exercise equipment.
The huge market opportunity offered by the connected life creates benefits for the mobile industry by enabling mobile operators to form partnerships with companies from other sectors to deliver compelling new services to consumers and businesses. The executive chairman of Ford Motor Company noted this in his Mobile World Congress keynote address. Not only does this create more opportunity for the entire industry supporting telecoms, but it will open up opportunities to increase efficiency and introduce smarter ways of working.
The GSMA estimates that the market for connected devices will be worth $4.5 trillion by 2020. By its estimates, the top 10 connected devices will account for 60 percent of the connected devices market by 2020.
Top Ten Connected Applications in 2020:
- Connected Car – $600 billion
- Clinical Remote Monitoring – $350 billion
- Assisted Living – $270 billion
- Home and Building Security – $250 billion
- Pay as you Drive Car Insurance – $245 billion
- New Business Models for Car Usage – $225 billion
- Smart Meters – $105 billion
- Traffic Management – $100 billion
- Electric Vehicle Charging – $75 billion
- Building Automation – $40 billion
Stay tuned to developments in this space as it certainly represents an interesting and incremental market opportunity for mobile operators and those vendors supporting them.