The evolution of applications, services and demands on private broadband networks are creating new requirements for coverage and agility, which will require a new breed of transport for backhaul. The backhaul network must be smarter, simpler and more cost effective to be able to handle the challenge of connecting any device, anywhere.
Things at the Boston Marathon Finish Line in 1910 were much calmer—and simpler—than the 2013 edition sans cell phones and other wireless devices. Author: Unknown. (Image credit: Wikipedia).
As was demonstrated by the tragic events in Boston April 2013, cell phone networks cannot accommodate every potential caller or texter using a mobile access device in times of peak load usage—such as during a crisis occurring in real-time on television and social media. Erroneously, some pundits at the time ascribed the outage to a co-conspiracy to take down the public wireless networks. Or an action by the civil authorities to thwart additional remote control saboteurs as has happened in Spain and other places. However, the simple truth is that demand far outstripped capacity for a time in Massachusetts due to the fact that mobile phone networks are designed to function with a typical level of subscriber activity—calls, text, mobile web, etc. When virtually everyone in the vicinity of the finishline of the Boston Marathon unlocked their iPhone or Samsung Galaxy smartphone and started to communicate the unfolding story to the outside world, it came as no surprise to network designers at the mobile operators that the infrastructure slowed to a crawl then ceased to work for a time. But this was news to the general public.
Aviat: The American Microwave Company and The Trusted Choice for State-Wide Microwave Networks
Aviat is the #1 provider of microwave and microwave routing systems to state/local government networks nationwide with 25 of 50 state-wide networks running Aviat equipment.
- January 23, 2017
- Aviat, Aviat Networks, AviatCare, AviatCloud, backhaul, Carrier Ethernet, Ethernet, IP/MPLS, LTE, Microwave backhaul
In microwave communications—as in all electronic communications mediums—operators trend toward the latest technologies (e.g., IP/MPLS). They all have conditioning to think that newer is better. And by and large that’s right.
However, when it comes to IP/MPLS—one of the most advanced packet technologies—you need to handle this concept with care. Especially in a mixed infrastructure that includes microwave, fiber and other potential backhaul transport.
LTE mobile connectivity now exists in many more urban places than not. Virtually all big cities have multiple choices for LTE and most have at least one choice for LTE Advanced—the real 4G wireless. For example, you can see iPhone and Android users taking advantage of all this high-capacity coverage as they leisurely view high-definition YouTube videos without buffering and actually livestream major league sports in cafes, parks and just walking around at lunch.
- August 7, 2014
- Aviat Networks, backhaul, LTE, microwave, Microwave backhaul, Microwave Radio, Microwave transmission, Mobile network operator, mobile networks, Mobile Technology, technology, voice over lte, volte
As one of the most anticipated network technologies, Voice over LTE (VoLTE) has been discussed by operators for years. The expectation was that deployments would start in 2013, but roll-outs in North America were delayed.
Logo courtesy of YTD2525 Blog
Operators have faced a series of issues that include poor voice quality and long call establishment times. Once these problems are solved, it is expected that VoLTE will allow operators to provide voice and data services using an integrated packet network. As the problems described show, the implementation of VoLTE presents challenges for the entire LTE ecosystem including microwave backhaul.
We have produced a white paper to describe some of the VoLTE requirements that must be met in order to overcome these technical challenges, which must encompass a flexible microwave backhaul as a key factor for a successful transition to all-packet voice and video VoLTE networks. A brief introduction to VoLTE is presented and then different VoLTE backhaul requirements are described with possible solutions.
Click here to download a white paper on this subject titled “VoLTE and the IP/MPLS Cell Site Evolution”.
- January 10, 2014
- Aviat Networks, Jilani, L2, L3, Layer 2, Layer 3, LTE, mobile, mobile networks, MPLS, Multi Protocol Label Switching, Virtual Private Networks, VPN
VPNs are crucial for next-generation mobile networks as they enable 3G and 4G wireless to share a common IP infrastructure as well as support new services, according to Said Jilani, network solutions architect for Aviat Networks. And because Virtual Private Networks (VPNs) can serve multiple sites, multiple applications and multiple customers simultaneously, Jilani believes that they will form the cornerstone for the great expansion of mobile services we are only now beginning to realize.
Serving as one of Aviat Networks’ resident IP experts, Jilani functions as an internal consultant for wireless network deployment and is able to leverage the experience working with different customers in different telecom verticals. And he has seen the impact that VPNs can have in all these markets—not just among mobile operators.
Multi Protocol Label Switching
The great revolution in VPN services for mobile networks is powered by Multi Protocol Label Switching, commonly referred to as MPLS, which offers mechanisms to provide scalable VPN networks, Jilani says. MPLS VPNs come in two main types: L3 and L2 “flavors,” as Jilani terms it.
L3 or IP VPNs, based on Internet Protocol, support very important functionality such as connecting customer sites by emulating a “backbone.” The service provider VPN connects sites in part by exchanging information with customer routers. Offering a robust solution, L3 VPNs easily handle traffic handoff from site to site such as is involved with LTE (Long Term Evolution).
More on L2 VPNs
In the video below, Jilani goes on to elaborate regarding L2 VPN emulation of edge routers and point-to-point Ethernet connections and how L2 and L3 VPNs can function together. Watch it for all the detailed information.
- October 18, 2013
- Aviat Networks, cell phone networks, Hadi Choueiry, Internet Protocol, LTE, Quality of service, tdm, Telecommunications, Time-division multiplexing, Voice over Internet Protocol, Voice over IP
The transition from the Time Division Multiplexing (TDM) cell phone networks of the 2G and 3G mobile era has been a long time coming. However, the mobile industry seems to be at one of its proverbial inflection points where IP (Internet Protocol) technology is ascendant and TDM has begun the long but inevitable decline into legacy status.
Aviat Networks has been there all along the way, helping operators design and deploy aggregation systems. We’ve seen and learned a lot as some of the leading mobile phone carriers have upgraded their networks. Now as LTE works its way into mainstream status, cell phone networks are transitioning to full-IP, the underlying technology of LTE.
- August 9, 2013
- Africa, backhaul, Cape Town, device availability, LTE, microwave, network investments, Nigerian Communications Commission, South Africa, technology
Africa’s only dedicated LTE event, LTE Africa 2013, took place in Cape Town this July 2013, bringing operators, vendors, mobile device makers, regulators and standardization bodies together under one roof to discuss LTE. On the agenda were the opportunities LTE can bring, obstacles to deployment, monetization challenges, current African success stories and future directions that LTE may take in Africa.
At the conference, operators grappled with the opportunity they face with LTE. What emerged as the main challenges for operators were spectrum, monetization and device availability—at the right price—for the African market.
In many exchanges, policymakers and regulators were beseeched to make spectrum available for LTE. Dr. Ernest Ndukwe, former CEO of the Nigerian Communications Commission, said, “Unless African leaders create an environment which encourages broadband network investments and makes it easy for companies to roll out broadband services, the situation is unlikely to change in the near future.” Operators were equally concerned about monetization of LTE so as to be able to recover their CAPEX—not to mention OPEX. (Others have not fully recovered their investments on 3G yet!)
Nonetheless, they are now expected to move to LTE. It was clear that operators would need to innovate how they do business by implementing new pricing strategies such as “value bundling” solutions, which would move them away from the cost-per-megabyte pricing tariff they firmly cling to today. Finally, a mobile device priced correctly for the African market has been earmarked as the enabler needed for massive adoption of LTE in Africa.
However, the conference was not all gloom and doom as operators who have successfully implemented LTE, such as Smile, MTC and others, shared information on how they made it possible. They highlighted how they implemented LTE. One of the key areas they focused on was in what way they backhaul LTE traffic.
Successful implementations revealed that for Africa—considering Africa’s demographics—practical and cost-effective implementation of LTE does not allow for 100 percent fiber backhaul, especially since realistic throughput demands of a typical three-sector LTE site max out at about 150 Mbps. With microwave systems easily able to reach 400 Mbps and even 2Gbps, microwave is more than capable of catering to an LTE site’s requirements and is undoubtedly the technology of choice for LTE backhaul except at sites where fiber already exists.
Microwave has cost benefits when deploying in areas lacking fiber, and it can be a cost-effective way to connect rural areas. Microwave also has the benefits of being quicker-to-deployment compared to the trenching needed for fiber. By 2017, industry analysts foresee that microwave backhaul will account for more than 50 percent of all LTE cell sites in Africa.
Technical Marketing Manager, South Africa
- July 11, 2013
- ACM, Africa, backhaul, Cell C, IP, LTE, MIMO, mobile cellular networks, MTN, Quality of service, South Africa, throughput improvement, Time-division multiplexing, Vodacom
LTE has been moving more and more to the forefront in mobile cellular networks around the world. Africa, and particularly the Republic of South Africa, is the latest hotbed of LTE rollouts, with the leading country operators of Vodacom, MTN and Cell C coming online since late in 2012. In conjunction with these LTE access rollouts, our technical marketing manager in the region, Mr. Siphiwe Nelwamondo, has been authoring a series of columns on enabling LTE in a leading regional technology media Internet site, ITWeb Africa.
Naturally, his focus has been on backhaul. In the first installment of his series, Mr. Nelwamondo looked closely at the backhaul requirements of LTE. Chief among these requirements are speed, Quality of Service (QoS) and capacity. He concluded that it is too early to close the book on the requisite parameters for supporting LTE backhaul. Part two of the features, he examined the basis on which microwave provides the technical underpinnings for LTE backhaul—especially as related to capacity. More spectrum, better spectral efficiency and more effective throughput were Mr. Nelwamondo’s subpoints to increasing capacity.
Having more spectrum for microwave backhaul is always nice, but it’s a finite resource and other RF-based equipment from satellites to garage door openers is in competition for it. Bettering spectral efficiency may be accomplished by traditional methods such as ACM and might be increased through unproven-in-microwave techniques like MIMO. Throughput improvement has wide claims from the plausible low single digit percentage increases to the more speculative of upping capacity by nearly half-again. Data compression and suppression are discussed. The truth is LTE, while data-intensive, probably will not require drastic measures for backhaul capacity until at least the next stage of LTE-Advanced.
If indeed capacity increases are necessary in the LTE backhaul, number three and the most current piece of Mr. Nelwamondo’s contains additional information. Nothing is better than having something bigger than normal or having many of the standard model. As the analogy applies to LTE microwave backhaul, bigger or wider channels will increase capacity, of course. A larger hose sprays more water. Or if you have two or three or more hoses pumping in parallel that will also support comparatively more water volume. The same is true of multiple microwave channels.
However, the most truly and cost effective capacity hiking approach is proper network planning. Mr. Nelwamondo points out that in Africa—more than some places—mobile operators are involved in transitioning from TDM planning to IP planning. While TDM planning was dependent on finding the peak traffic requirement per link, IP planning allows the flexibility to anticipate a normalized rate of traffic with contingencies to “borrow” capacity from elsewhere in a backhaul ring network that is not currently being utilized. Along with several other IP-related features, this makes determining the capacity a lot more of a gray area. Some operators solve this by simply “over-dimensioning” by providing too much bandwidth for the actual data throughput needed, but most cannot afford to do this.
The fourth and final entry in Mr. Nelwamondo’s series will appear soon on other LTE backhaul considerations of which you may not have thought. Sign up below to be notified when it is available. [contact-form-7 404 "Not Found"]