Copper Decommissioning Expands Demand for Metro Ethernet

By: John Shepler

If you are still getting by with last mile Internet over DSL, T1 lines, or Ethernet over Copper, you should take a serious look at Metro Ethernet over Fiber. You’ll get more bandwidth, better pricing and… it will continue to be available.

Copper Decommissioning is Now
Copper based telecom services have been the go-to technology for the last century, but not this century. The ubiquitous twisted pair telephone line has supported our needs from the introduction of the telephone through the fevered growth of the commercial Internet. But, like cellphones the size of a brick, the technology has run its course. Copper just can’t keep up with today’s and tomorrow’s needs.

The phone companies know this. The network operators know this. They are well aware that we are way past “peak copper”. As you read this, copper lines nationwide are being retired or “decommissioned”. In some cases the copper is physically ripped out of conduits so that fiber optic cables can be pulled right back in. In other cases the copper bundles in the ground are simply disconnected and left to rust away on their own. In the coming years there will be fewer and fewer copper options available to order, until a copper wireline is as rare as a cranked telephone set.

Fiber is the Future AND the Present
The replacements for copper telco right now are Cable in the form of hybrid fiber/copper systems, Fixed Wireless Access, and Fiber Optic bandwidth. Fiber in cities is also called Metro Fiber or Metro Ethernet. Most urban, suburban and even small town businesses now have access to Metro Ethernet and its flexible options.

Fiber is your most flexible option for several reasons. First, fiber optic strands offer extremely high bandwidths, to 10 Gbps or more. With wavelength division multiplexing, you might get a dozen or more 10 Gbps lambdas, each a virtual fiber in itself. Now, consider that nearly all fiber cables have multiple strands, even dozens, and you can see how fiber bandwidth is nearly unlimited. Once installed, that fiber will likely last as long as you need.

Second, fiber, unlike cable or most wireless, can provide exclusive dedicated line services. You can order private point to point connections and have all of the bandwidth available for your traffic. Compare that to the consumer-oriented broadband services that share bandwidth among many users to keep the cost down. With dedicated Internet access or private point to point lines, you won’t be competing with everybody else for limited resources at high traffic times. This can be especially valuable in connecting your network to a distant cloud provider that hosts business critical applications.

In addition to massive available bandwidth, fiber service is also very scalable. You can typically start off as low as 10 Mbps at pricing comparable with a current T1 line, but with over 6x the bandwidth. Many smaller businesses find that 100 Mbps is plenty, but Gigabit bandwidth is easy to come by and very affordable. If your applications demand it or your workforce is substantial, 10 Gbps is easily available on fiber. Even 100 Gbps is now being offered to larger companies and hospital complexes, content developers, etc.

Why Ethernet over Fiber
The earlier implementations of fiber optic service were based on a telephone company standard called SONET that offered fixed bandwidth levels and was designed for voice calls, not data. While protocol conversion circuitry made SONET the backbone of the Internet, Carrier Ethernet is now the standard to be embraced. This is the same switched Ethernet that runs on your local network, but extended to transport packets over hundreds or thousands of miles.

Metro Ethernet uses the Carrier Ethernet standard running over fiber optic cabling. This makes it virtually plug-and-play with your network. You can even set it up so that your business locations all over the state or country act like they are on one big network. Metro Fiber Ethernet is the new standard for business connections. Network connections within the metro area are often referred to as MAN or Metropolitan Area Network, while those more distant are referred to as WAN or Wide Area Network.

Are you ready to replace aging T1, DS3, DSL or other network services with something more modern that is future-proof and likely less expensive? Check your Metro Fiber Ethernet options for one or more business locations now.

Ethernet WAN is the New SONET

By: John Shepler

High speed communications lines progressed from copper analog to copper digital to fiber optic digital over most of the last century. The technology that drives fiber has also evolved from time sliced synchronous multiplexing to packet based protocols, mirroring the transition to networked computing for nearly every business. While older SONET telco lines still provide effective connections, there are real advantages to be gained by upgrading to Ethernet WAN, the newer technology for fiber optic service.

It Started With Really Fast Phone Lines
SONET, which stands for Synchronous Optical NETwork, is a phone company invention that was developed to bundle or multiplex thousands of individual phone calls onto an optical fiber for long distance transmission. To make operations easier, SONET was made backwards compatible with legacy T1 service that does exactly the same thing with 24 calls over two twisted copper pair… in other words, ordinary telephone line.

SONET allowed the phone companies to bundle T1 line into DS3 lines into OC3 fiber lines and demultiplex or unbundle them anywhere along the way. Everything was compatible down to the single telephone channel.

SONET to Link Computers
So, how did SONET come to support computer networking? The protocol had to be converted between SONET’s time division multiplexing and Ethernet’s packet switching. That was accomplished using protocol conversion on a plug-in module. To the user, It made no difference what was going on under the hood. Packets would go in one router and come out another miles or thousands of miles away.

SONET was developed for fiber and all of the early fiber optic links for computer networks were connected using one of the SONET levels. OC3 was the lowest speed at 155 Mbps. This was the first fiber service that most corporations ordered when they outgrew their T1 and T3 lines. Each increase in speed required swapping out an adaptor module for the particular SONET level.

In fact, the Internet was built on SONET. SONET rings, which offer redundant paths, formed the core of the Internet as it grew. Internet service providers would connect via SONET and then divvy up the bandwidth for multiple 64Kbps dial-up modems or, later, DSL or Cable broadband modems.

The Ethernet Revolution
Ethernet, developed by the Xerox Palo Alto Research Center in the mid to late 1970’s, grew to become the dominant networking protocol, thanks in no small part to the proliferation of the personal computer at the same time. Most small and large users adopted Ethernet, as adaptor cards, cabling, hubs and routers became more and more affordable. Every PC soon came with an RJ-45 Ethernet jack as standard equipment and peripherals, such as printers, did the same for compatibility.

Once Ethernet became the de-facto networking standard and computer data traffic greatly exceeded voice traffic, it started to make sense to just adopt Ethernet for Wide Area Networks as well as Local Area Networks. When business phones became digitized and used VoIP to connect on the same network as the computers, the need for a separate voice network faded away.

Another factor that has moved WAN services from SONET to Ethernet is the rise of competitive network service providers independent of the telephone companies. Since these companies had no legacy analog phone service to support, they could simply focus on offering Ethernet connections to their customers in competition to the telcos.

By this time the original Ethernet protocol has been expanded to provide technical specifications for Carrier Ethernet, which is the same as LAN Ethernet but extended to support the MAN (Metropolitan Area Network) and WAN (Wide Area Network).

What Ethernet WAN Has to Offer
You remember that SONET has distinct service levels, each with it’s own bandwidth and specific adaptor requirements. Ethernet doesn’t have this limitation. Instead, you have an Ethernet port with a maximum bandwidth, say 1 Gbps. It will support any bandwidth up to the max limit of 1 Gbps. You can order 100 Mbps service today and easily upgrade to 500 Mbps or 1 Gbps later. Only if you want a service level above 1 Gbps, will you need to have a higher capacity port installed. This process is so seamless that many providers will let you change service levels at will by logging into your online account.

Ethernet services tend to be less expensive than SONET. Usually, much less expensive. You pay for the service level you want, be it 10 Mbps, 100 Mbps, 1 Gbps, 10 Gbps, and so on. Remember you can change this easily after you have service installed and your bill will be adjusted to the new level you select.

Since there are many, many competing Ethernet MAN and WAN service providers, pricing per Mbps has dropped rapidly over the years and continues to do so. Some of the service providers are the traditional telephone companies, but with much improved pricing. Others are independent carriers serving regional, national, or international areas. They can also provide excellent customer service, high reliability, and very good deals on bandwidth.

There are usually two types of service you’ll be interested in. One is a dedicated connection to the Internet at a bandwidth you select. The other is a point to point dedicated private line that is just like having a very long Ethernet cable connecting two LANs separated by many miles. These are useful for interconnecting main offices and branch offices, warehouse, manufacturing centers and so on with maximum performance and privacy. Another popular application is a direct connection between your offices and your cloud service provider. This avoids the vagaries of Internet performance and makes the cloud seem like it is right down the hall.

Perhaps you still have legacy SONET service that was installed years ago. It’s been working fine so no one has paid much attention. This would be a good time to see if competing Ethernet WAN services can give you more bandwidth for the same budget or offer a considerable cost savings if you are happy with the bandwidth level you have now. It doesn’t cost anything to look, so why not see what’s available?

Ethernet WAN to Complement Your LAN

By: John Shepler

Traffic on your company’s Local Area Network (LAN) zips along at 1 Gbps or more. In most cases that’s so fast it seems like the network is transparent. Yet, access a resource outside your building and things just seem to creep along. Wouldn’t it be nice to just stretch that LAN across town or to one of your remote locations? Well, maybe you can.

Yes, The WAN is Ethernet
Networks can be divided into two categories: The ones you own and the one’s you lease. You typically install and administrate your company network, called the LAN. When you leave the premises, you connect to another network that operates as a utility. That's the WAN or Wide Area Network. Originally, this WAN was owned and operated by the telephone companies and implemented their proprietary standards. That includes your phone voice lines, ISDN dial-up, T1, DS3, and SONET fiber optic. Connecting to any of these standards requires specialized equipment to do the protocol conversion to and from the Ethernet that runs on the LAN.

These days, most outside lines connect directly to Ethernet without any protocol conversions. The suppliers can be telephone companies or competitive carriers who run their own fiber optic networks. Interoperability is made easy by Carrier Ethernet Standards established the MEF (Metro Ethernet Forum) industry consortium.

Ethernet WAN Services
There are three services typically offered by Ethernet service providers that you’ll want to know about.

E-Line or Ethernet Virtual Private Line is a point to point service that connects two locations as if there was a really, really long Ethernet cable in-between.

E-LAN or Ethernet Virtual Private LAN is for multiple locations that want to communicate as if they are on a private bridged Ethernet network.

E-Tree or Ethernet Virtual Private Tree is also a multipoint service, but used more for broadcasting, streaming or content distribution. It is a one-to-many service with a single root and multiple leaves.

Getting Ethernet WAN Service
Within a metropolitan area, the service is called Ethernet MAN or Metropolitan Area Network. Over longer distances that leave the area, Ethernet WAN or Wide Area Network is the term used.

You’ll contract with a service provider or carrier that has points of presence in the locations you want to connect. You may have several to choose from.

The equipment installed at your location consists of terminal equipment with an Ethernet port that supports the network speed you desire. Unlike older systems that require equipment changes for every change in service level, you can order Ethernet service at many different speeds up to the limit of the installed port. This has the advantage of letting you pay for the service level you need now and then upgrade easily as you need more capacity. Often that’s as easy as making a change via your online service portal or with a simple phone call.

Ethernet to the Internet
The Internet is the ultimate Wide Area Network, connecting just about everybody, everywhere. You can order an Ethernet Dedicated Internet Access to connect your company to the Internet at whatever bandwidth you desire. The advantage of a dedicated connection is that the full bandwidth of the line is at your disposal and not affected by the carrier’s other customers. These lines are also typically symmetrical, meaning that upload and download speeds are identical.

Why not just use the Internet to connect your far flung locations as well as connecting to customers? Many companies do. it’s likely your lowest cost option. What you give up is the ability to establish Class of Service so that sensitive applications like VoIP phone calls and video conferences have priority over less critical applications such as file transfers and backups. Internet performance is also somewhat unpredictable because of unexpected congestion, indeterminate packet routing, jitter, latency and packet loss.

For companies with multiple locations, a hybrid arrangement may work best. Use dedicated Ethernet services to interconnect business locations and the Internet to communicate with supplier and customers.

Does Ethernet WAN sound right for your business? Get a suite of competitive quotes for Ethernet WAN or MAN services now with a single inquiry.

Gigabit Metro Fiber Ethernet Means Business

By: John Shepler

More and more companies are running out of bandwidth as demanding applications eat up every Mbps of LAN, MAN and WAN bandwidth they can access. Are you doomed to fight a losing battle or is there a good technical solution available?

More Bandwidth to the Rescue
Don’t expect to roll back the clock and be able to do business today and tomorrow with the connections you ordered yesterday. X.25 is long gone. T1 lines have about had their last hurrah. Ethernet over Copper is a temporary solution, at best, to buy you time for what you really need to do. That is, connect to the world via fiber optic bandwidth

But What About Cable?
Cable broadband, also called D3 or DOCSIS 3 for the technical standard, is actually a good solution for some applications. Just don’t kid yourself. That cable connection doesn’t really go very far until it hooks up with the cable company’s metro fiber plant. The junction box may be a few blocks away or it might be handing on the utility pole you can see from your office.

The same is true for T3 or DS3 bandwidth, the longstanding upgrade path from T1 lines. The connection to your equipment may be a pair of coaxial cables, but they only go out to the street. At they point they join up with a SONET fiber optic system owned and maintained by the local telephone company.

What’s Special About MetroE Fiber?
Ethernet is the newer and future-proof technology for carrying digital traffic on fiber optic systems. It is based on the same Ethernet standards used for your local area networks. Certain standards have been added to fit with carrier operations, but otherwise it is switched Ethernet.

That means the interface between your LAN and the carrier’s MAN or WAN is trivially simple. Just plug in and go, like you would with any router or switch. No special interface cards are needed. Chances are that the carrier who is providing your service will install a managed router at your business to define the network edge.

Metro vs Internet
Metro Ethernet, strictly speaking, is a network that serves a particular city or city plus suburbs. The most common use has been to interconnect business locations that are geographically close. These may include headquarters, data centers, warehouses and branch offices. Some companies choose to include suppliers and important customers on their MetroE network for high connection speed and security.

Metro Ethernet is a point to point or multipoint service that directly connects particular locations. You can elect to order ELAN service that actually extends your local network to the other locations. It’s just like you ran your own cables across town, but without the prohibitive expense of doing so.

The Internet is another animal. It’s actually a massive worldwide network made up of national, regional and city-wide networks that all agree to a common standard. Metro Ethernet is not the Internet, but it can connect to it. MetroE networks can also connect to each other over longer distances, especially when ordered through the same carrier.

Why Order Metro Ethernet?
You can think of Carrier Ethernet or Metro Ethernet as the new gold standard in telecommunications. It gives you high bandwidth connections that are easily scalable and low in latency, jitter and packet loss. You have exclusive use of the bandwidth you’ve ordered. It’s also generally covered by a service level agreement to ensure that you get the highest level of availability.

That’s important because the tradeoff between Metro Ethernet and Cable Broadband is not so much in the connection method. Cable provides you with a shared bandwidth service that varies in speed depending on how heavy the usage is. Service is generally on a “best effort” basis rather than any particular guarantees of performance or availability. Thus, the lower price for a given bandwidth level. Some businesses, especially smaller ones, find this tradeoff well worth making. Others with large user bases and critical applications may find that only dedicated service is acceptable.

By the way, many Cable companies also offer Metro Ethernet service on their fiber backbones. It’s a different class of service with a different pricing structure than the coax connected business broadband offering.

Is Metro Ethernet For You?
If you are running out of bandwidth or already at the limit, or simply want a service that can easily be upgraded in the future, you should take a serious look at Metro Ethernet for your business. You may be able to get a break on construction costs or even have them waived if you sign a long term contract, have high enough bandwidth requirements or can join forces with other business customers in your building. There are likely multiple carriers serving your area. Find out what each can offer with a set of competitive quotes for Metro Ethernet service now.

Dark Wavelength vs Dark Fiber for 10 GigE

By: John Shepler

Organizations that require extremely high MAN (Metropolitan Area Network) bandwidth or need to run a multitude of protocols have looked to dark fiber as a technical solution. Dark fiber is still a good choice for the most demanding applications, but there is a competitive service you should also be aware of. It’s called dark wavelength or dark lambda. Let’s look at what each has to offer and how they compare with the more common point to point and MPLS network connections.

What is a Dark Wavelength?
We think of wavelengths as colors of light, not something dark. A wavelength with no color would essentially be turned “off” and would be the same as a dark fiber, right?

Not really. The difference is that dark fiber is nothing but the glass fiber strand itself. There is no equipment attached. Somebody, and that somebody is likely you, has to install terminal equipment at each end and turn on one or more laser beams to “light” the fiber. Sometimes "managed" dark fiber is available, where the carrier will provide the terminal equipment but you'll still have exclusive use of the fiber strand.

With a dark wavelength, this has already been done. It’s not a fiber with a single color laser at one end and a detector at the other. Instead, the equipment that has been installed is DWDM or Dense Wavelength Division Multiplexing gear. What DWDM does is send multiple non-interfering laser beams down the same fiber strand to create what amount to additional channels equivalent to multiplying the number of fiber strands available.

With DWDM there is still only a single physical glass strand. The multiplexing or creating of multiple virtual fibers out of one is based on the fact that glass is transparent to more than a single color or wavelength of light. You can easily see this with a common prism. Shine white light in one side and bands of color appear on the other side. The prism shows that a number of separate colors can travel through the glass without interfering or canceling each other out.

Say you want to create a dozen different wavelengths on a single fiber. You’ll need a DWDM system that contains a dozen laser transmitters, each tuned to a slightly different wavelength or color. In practice, all the colors are in the infrared part of the spectrum and not visible colors. Nonetheless, they are referred to as colors, wavelengths or lambdas (the Greek letter used to denote wavelength).

Why go to all this trouble and expense? Simple: To multiply the capacity of a fiber cable. There are two ways to get more bandwidth from a fiber bundle. Either add more strands or use more of the inherent capacity of each strand. Adding strands means running an additional cable along the same route or replacing the cable you have with a larger diameter one that has more of the hair-thin glass fibers. Both options are incredibly expensive. Getting more from the infrastructure you already have is very attractive by comparison.

This is why DWDM is so popular. Why pull many miles of new cable at a cost of millions of dollars when you can upgrade your terminal equipment for a fraction of the cost? DWDM is a well established and standardized technology. Why not let technology save you the cost and delays involved in upgrading the physical cable?

The Dark Wavelength vs Dark Fiber Tradeoff
If you lease a dark fiber strand, you have exclusive use of that piece of glass. You have the security of knowing that only your traffic will travel over that strand. There will be other customers using other fiber strands, but there is a physical separation between you and them.

Dark fiber also gives you the flexibility of using any protocol you want and even setting up multiple protocols on the same fiber. How do you do that? By installing DWDM equipment of your own to create multiple independent wavelengths.

You can see how this can get to be expensive fast. A simple one wavelength fiber strand is one thing. You can probably get 10 Gbps bandwidth on that strand with simple equipment. DWDM is another matter. Now you need a fairly sophisticated piece of equipment at each end that you have to install, pay for and manage. For that, you can create multiple independent channels of, say, 10 Gbps each.

Instead, why not let somebody else bear that expense? That’s the basis of dark wavelength services. Someone, the carrier or service provider, has already lit the fiber with DWDM equipment that they own and operate. However, they don’t need all of the wavelength capacity themselves. If there is only enough traffic to use half the wavelengths available, the others can be leased to help pay for the system.

A dark wavelength is simply an unused wavelength on an existing fiber optic system. To be truly dark, the laser for that wavelength may be turned off or there is no card in the system for that particular channel. Either way, once someone agrees to lease the wavelength, service can be turned up fairly quickly. After all, the fiber and the DWDM chassis are already in place and operating.

Why Choose Dark Wavelength?
One reason to opt for dark wavelength service is that it may be all that is available. The owner of the fiber network may not be willing to lease an entire strand. That’s especially true if they have already lit their strands and are using some of the wavelengths.

Another attraction of dark wavelengths is equipment cost and maintenance. In theory, a provider could require you to purchase the channel cards that are compatible with their DWDM system and light the wavelength yourself. More likely, they will handle that themselves. You may or may not be asked to pay a one-time installation fee that includes the cost of the wavelength cards.

If the common carrier turns up the wavelength and maintains the system, you will have exclusive use of that particular wavelength at a bandwidth of 1, 5 or 10 Gbps. Sometimes wavelengths can be aggregated to create higher bandwidths up to 100 Gbps. Either way, only your traffic will be carried on that wavelength as whatever protocol you choose. Other customers will have their traffic on other wavelengths, but the different color beams will not interact.

Other Options
Not everyone needs or wants dark fiber or wavelength service. Many businesses only need 100 Mbps or Gigabit service. Both traditional SONET or the newer Carrier Ethernet protocols are generally available as point to point connections, ports to much larger MPLS optical networks, or Dedicated Internet Access.

What bandwidth option is best for your applications? Why not discuss your needs and get competitive quotes from multiple carriers for a range of services that can meet your needs. Then you can compare costs and benefits and pick the high bandwidth fiber optic service that best meeds your requirements.


Note: Spectrum of light wavelengths though a prism animation courtesy of Wikimedia Commons. 

How Your Port Sets Your Bandwidth

By: John Shepler

As users of MAN and WAN telecom services, we’re acutely aware of the bandwidth we’ve contracted for. What once was seemed like more than adequate line speed now seems a bit confining. In the worst case, applications don’t run right and productivity slows to a crawl as everyone waits on something to download. Now, what’s needed to jack up the bandwidth and get rid of all that congestion?

Every Connection Has its Speed
You can often run any line at less capacity than it is capable of, but not more. Factors that go into the maximum speed include type of transmission medium, such as twisted pair copper, coaxial cable, fiber optic strands, or microwave wireless. They also include the capability of the port on the access router or other customer premises equipment (CPE). Let’s have a look at some common connectivity solutions and their port speeds.

T1 Lines
T1 lines run at a synchronous speed of 1.5 Mbps. Synchronization between source and destination is typical of the TDM or Time Division Multiplexing technologies that include T-Carrier (T1, T3) and SONET (OC-3, OC-12, OC-24, OC-48). The way these lines carry traffic is to chop up a fixed line speed into smaller pieces called channels. T1 happens to have 24 channels of 64 Kbps each. That turns out to be just right for packing one telephone conversation into each channel. For data traffic, all the channels are combined into one large pipe.

It’s easy to see how you can have less than 1.5 Mbps by using fewer channels or rate limiting the data speed. This used to be popular as a cost savings mechanism when T1 lines were very expensive. Nowadays, 1.5 Mbps is considered an entry level broadband at best. So, how do you get more than 1.5 Mbps out of a T1 line?

Short answer: You don’t. Longer answer: You combine or bond two or more T1 lines so they act like a single transmission line. This gives you the option of creating bandwidths from 3 to 12 Mbps. The thing to remember is that every time you want to add another line, it has to be physically installed by the same carrier. They will usually have to change out your CPE as well as connecting the additional line wiring.

T3 Lines or DS3
T3 and DS3 are pretty much the same thing, although there is a hair of technical difference between those designations. They both run at 45 Mbps and are delivered on a pair of coaxial cables to a specific plug-in card on your router. What you don’t see is that the DS3 signal almost always runs multiplexed on a SONET fiber optic service to the curb. All of these are TDM services, like T1 lines on steroids.

SONET Fiber Optic
SONET or Synchronous Optical NETwork is a family of standards that offers an easy upgrade from T-carrier. Yes, SONET still uses the 64 Kbps channels when it is set up for telephone trunking. Otherwise it offers a very large data pipe that can also be used as a SIP trunk.

Like T-Carrier, every flavor of SONET has a different interface. You’ll need specific cards or carrier supplied routers for OC-3 at 155 Mbps, OC-12 at 622 Mbps, OC-24 at 1.2 Gbps, OC-48 at 2.4 Gbps and OC-192 at 10 Gbps. You can sometimes get rate limited bandwidth at each level for some cost savings.

Ethernet over Copper
Ethernet over Copper (EoC) uses the same twisted pair transmission wiring at T1, but is capable of higher speeds, albeit at shorter distances. Typical bandwidth range from 3 on up to at least 10 or 20 Mbps. In special circumstances, this can be increased to 50 or 100 Mbps.

Ethernet is a bit different from TCM in that there are no synchronous channels. Instead, everything is carried by packets. The number of packets that the line will carry each second is its bandwidth. The bandwidth you can get depends on the capability of your carrier and the speed of the installed port on the CPE. Most often this is a managed edge router they install in your premises.

You simply plug into the Ethernet port on the router using a standard RJ-45 Ethernet cable. Port speeds follow the Ethernet standards of 10 Mbps and 100 Mbps. If you have the 100 Mbps port installed, you can specify the bandwidth you want in fairly small increments up to the technical capability of the connection. Better yet, you can tell the carrier to change your bandwidth at any time and it will be done quickly. Some carriers even let you make the change yourself through your web browser.

Ethernet over Fiber
Ethernet over Fiber (EoF) works just like Ethernet over Copper except that it runs on fiber optical cabling all the way and offers nearly unlimited speed options. Your access ports can be copper or fiber connections. Twisted pair copper jacks make sense for 10 Mbps, 100 Mbps and 1000 Mbps ports. Fiber connections are used for 10 Gbps and above.

Fiber has become far more economical in just the last few years. Today it makes sense to install Ethernet over Fiber service as low at 10 Mbps. With a typical 1000 Mbps port, you typical have all the expansion capacity you’ll need for the foreseeable future. There won’t be any equipment changes needed until you breach the Gigabit Ethernet bandwidth level. Then it’s likely you’ll move up to a 10 GigE port. By that time, 100 GigE ports may be rule rather than the exception.

Cost Considerations
TDM services such as T1, T3 and SONET are proven technologies, but they represent the past in telecommunications and networking. The new competitive carrier networks are designed around Ethernet for scalability and compatibility with the Ethernet protocol that runs nearly every company network. In most cases, you’ll find that Ethernet offers a cost savings over TDM in both the copper and fiber formats. That cost savings can be as much as half or more depending on what’s available in your area.

Is your current connectivity starved for bandwidth? Clearly, it’s time to consider an upgrade. Get competitive quotes on copper and fiber optic services available for your location and be sure to specify a port speed that will handle both your current and expected needs.

The Software Defined Network Comes to Austin

By: John Shepler

The Software Defined Network (SDN) has been one of those nebulous concepts that is coming someday to do something better than current IT technology. Well, that day has arrived and here’s what SDN is going to do for your company.

Why Software?
Like software everything, the software defined network is intended to replace fixed hardware functions with reprogrammable software. It’s not really a simplification process. The hardware may be more generic, like microprocessors and digital signal processors, but if you include the lines of code, the component count shoots through the roof. The beauty of software is that all those “soft” parts can be replicated instantly at little or no cost. Even more importantly, software can be changed from afar as needed.

The Idea of Virtualization
You’ve probably run into virtualization in the IT racks. Not that long ago, a server was a stand-alone computer with its own operating system and software load. Each server had a designated function. If it was overloaded, you needed to buy a more powerful computer and swap out the boxes. If the application wasn’t that demanding, the server would loaf along most of the time.

In this type of environment everything needs to be planned up-front and changes are time consuming and sometimes expensive. There’s also a poor utilization of resources. You may need a lot of lightly loaded servers all cooking in the racks in order to run your myriad of business applications.

Virtualization changes all that. The server is no longer a hardware appliance but a software function running on one or more processors. The computer hardware might not look much different, but what used to be one server may now be a dozen running on the same box. Huge applications might span several boxes to get the job done. It’s just a matter of how much in the way of resources an application needs.

Some of what virtualization has accomplished is to reduce the number of physical computers needed since each box is running at a higher capacity. Even more important, a new virtualized server can be installed in minutes since it is simply a software “instance” running on the hardware already in the racks. Don’t need a server anymore? Simply have the software release the resources back into the pool. You don’t even have to set foot in the data center to make this all happen.

Does this sound like “The Cloud”? Virtualization on a huge scale is the magic behind cloud data centers and cloud services.

Virtualization for the WAN
Now consider your telecommunications network connections. Like all hardware based approaches, there are many specialized functions implemented by very specific equipment cards and boxes. Some are in the central office, some in the network path and some at the customers premises. It takes a long time to provision a new service and get everything wired up correctly so that you get the service you pay for and don’t interfere with others or have them interfere with you. The term “nailed up” goes back to the days when physical copper wires were literally nailed up on a board while they were assigned to a particular customer.

If you’ve ever tried to upgrade service, you know what a pain it can be. You need to submit a new order that needs to be processed. The changes to the network for your extra bandwidth have to be engineered. Then a truck has to roll to your location delivering a CPE (Customer Premises Equipment) box with the proper interface for the new service. Bandwidth is typically available in major increments and you better get your order placed well in advance of running out of current capacity.

Now, what if the network could be virtualized like the servers? The hardware becomes more of a life support system for the software. That software can be changed, upgraded or supplemented at will. All of a sudden, network changes become fast and easy. That’s the software defined network.

What AT&T is Doing in Austin
AT&T is launching its software defined network in Austin, Texas with the moniker AT&T Network on Demand. That’s pretty much what it’s all about. Businesses will be able to increase or decrease the bandwidth of their broadband speeds in near real time. In olden days (before SDN) this could take hours maybe days in the case of Ethernet services or weeks or longer for legacy SONET and T-Carrier.

The Carrier Ethernet services over copper and fiber that have appeared on the scene recently were engineered with more of the software defined network idea in place. One of their bragging points is that you can usually get a bandwidth increase by simply calling your service provider and making the request over the phone. No need to keep watching out the window for the service truck to roll in. As long as you have enough port capacity, the carrier will make the changes “invisibly” while you are doing other things.

In fact AT&T’s SDN will let them provision new communication ports in days compared to weeks. That’s an extension of the software-defined philosophy that separates physical hardware from software. Once again, as long as the installed hardware has the capability of handling the demands placed on it, what it does is really a function of software parameters and apps. Look for this approach to expand rapidly throughout the industry. It will be a matter of competitiveness among the communication carriers and other service providers.

Are you limited by your current MAN or WAN network capability? The service offerings are changing fast. Chances are that you can get more capacity and flexibility without a cost increase with MAN and WAN Network Services available now.


Note: Photo of Austin, Texas at night courtesy of Daniel Mayer on Wikimedia Commons.

Connectivity Should Be Invisible

By: John Shepler

Buffering videos, garbled VoIP phone calls, slow loading web pages, interminable waits for files to download, jerky video conferencing, hesitation in response from the cloud. They’re all symptoms of connectivity that makes us painfully aware of its presence.

That’s not what you want. You want connectivity to be invisible, like other utilities. Flip a switch and the lights come on. Turn the faucet handle and out comes the water. Unless something goes horribly wrong, this is how it works every time. So, why do we have lower expectations of our bandwidth connections?

Not So Great Expectations
Perhaps its because so many of us who are in a position to do something about it were around to watch the blossoming of the Internet from a backwater mail service for academics to the primary way we do business and communicate. Perhaps it’s because the technology is still evolving. This is especially true in mobile applications and remote locations, where bandwidth is still a precious commodity and limited in both speed and availability.

Otherwise, it is quite possible to achieve that goal of making network operations a background activity for business users. You can then treat your connected devices as appliances. You turn then on and every function works the same way, all the time. Nothing happens to break your stream of consciousness or give the impression that something is “broken.”

What to Know
You need to be aware of the some key performance characteristics of your network. No, not your LAN. I assume that you’ve already optimized your in-house network. The real Achilles heel is those outside connection, the MAN and the WAN.

The first parameter of importance is bandwidth. The idea behind having “big pipes” is that the conduits are always larger than the quantity of bits per second that you are sending through them. When the circuits can’t handle the volume of traffic, they become congested. It’s like too many cars trying to enter a superhighway. At some point it all clogs up and things slow to a crawl.

Networks, including the Internet, are good at preserving the integrity of the traffic but not so good at keeping the flow moving at top speed when congested. Buffers fill up as each node waits its turn. At some point, packets can no longer be accepted until those in process move on. Does this sound like a busy airport during a snowstorm? The analogy is close.

How Much BW is Enough?
What this all means is that you need to order the level of bandwidth consistent with your current and near-term needs. “Of course,” you say. “That’s obvious.”

Well, it is an it isn’t. There are a numerous ways you can get caught without the bandwidth you need. One is application demand that is creeping up. Those T1 lines you ordered a decade ago have been working reliably until recently. The carrier says they still are. What’s happened is that you’ve added employees, moved applications to the cloud and depend on the Internet for more of your communications. The lines are still working fine. They’re just overloaded. You need more bandwidth.

So, you go out and order a high speed satellite link that has 10x your old bandwidth. File transfers seem to be working fine, but you can’t carry on a telephone conversation because you have to pause for a second between talking and listening. Your cloud business applications also seem to run a lot slower than they did when you ran your own data center. How much bandwidth does it take to fix this situation?

The Latency Speed Bump
No amount will be enough. That’s because your problem is latency, not bandwidth. Latency is a time delay between source and destination. In-house the speed of electrons through wires and photons through fiber is so fast that you’ll be hard pressed to detect it. But, when those locations are connected by a radio wave path that goes up over 22,000 miles to a satellite and back down 22,000+ miles, the delay is noticeable, if not downright annoying. A round trip takes something like half a second… even at the speed of light.

Network congestion can contribute to latency, but an uncontested network can still have latency issues depending on path length and any buffering delays introduced by equipment in the path.

Other Sources of Network Congestion
Congestion can also be caused by contention between your needs and those of other companies sharing the MAN or WAN network. You may have installed more than enough bandwidth for your needs, but the network doesn’t have enough for yours plus everyone else’s. This is a classic issue with the Internet and mobile cell towers. Too many users at once can overwhelm the system and force everyone to take turns using the limited resources.

What can you do about that? First, keep your in-house communications on dedicated private lines or through an MPLS network that guarantees performance. Choose symmetric services with the same bandwidth in the upload and download directions unless your are sure your needs are asymmetrical.

For Internet connections, which we all need, you can bypass most of the “information slow lane” problems with a dedicated Internet connection. This gives you the best performance in terms of bandwidth, latency, jitter and packet loss. The actual core of the Internet is really pretty good. It’s the last mile connections, especially those shared with other users on “best effort” services like DSL, Cable and cellular, that get easily overloaded.

How to Choose
Ultimately, it’s a cost vs performance tradeoff. Cable broadband works great for residential and home office users and can work just fine for businesses that don’t have critical requirements. Most medium and larger businesses, however, need to move up to private lines and dedicated Internet connections if they want their connectivity to become invisible to users.

Do you wish your connectivity was more invisible that it is now? Look into high performance MAN and WAN bandwidth options that are available for your business location.

WAN Network Connections From Copper to Fiber

By: John Shepler

LAN, MAN and WAN speeds continue to rise as content demands more and more bandwidth. This is increasing pressure on both copper and fiber based telecommunication networks for more frequent speed upgrades. Let’s take a look at what the options are for both traditional TDM (Time division Multiplexing) and IP (Internet Protocol) networks.

The Legacy of Copper Telecom Lines
Copper has been the mainstay of electronic communications, starting with the telegraph and then the telephone networks. The telegraph, of course, is long gone. The telephone is undergoing a technology shift where voice is becoming a converged network service. With the implementation of 4G LTE wireless, even cellular phone will soon move away from voice only channels to integration with data.

Clearly, analog POTS (Plain Old Telephone Service) is in its twilight years. What will remain for decades to come is its installed base of twisted pair copper lines that connect to nearly every building, commercial and residential. That copper still has value because it can transport digital signals as well as analog.

Digital T1 Lines
The oldest digital protocol for data transmission on twisted pair copper (not including telegraph) is still going strong. It’s the T1 line used for telephone trunking, point to point data, and dedicated Internet connections. T1’s history is that it was developed to transport multiple phone conversations digitally using existing telephone cabling. T1 can transport service over wide areas using signal regenerators to clean up the signal every 6,000 ft. You can get T1 nearly anywhere you can get landline phone service. The one limitation is its 1.5 Mbps bandwidth.

While 1.5 Mbps used to be considered broadband, it’s no longer adequate except for PBX telephony, casual Web access, email and point of sale credit card verification. This bandwidth is similar to 3G wireless. Wireless is rapidly moving to 4G wireless, with speeds an order of magnitude higher. Wired services are also moving to 10 or 15 Mbps as a minimal requirement.

Bonding T1 Lines & Ethernet over Copper
T1 is enjoying continued usefulness by bonding the bandwidth of multiple T1 lines to make one larger service level. This is practical up to 10 or 12 Mbps, but gets too expensive and hard to find available bundles of unused copper pair above that. What’s needed is a different technology that gets more bandwidth out of the same copper.

That technology is now available and called Ethernet over Copper or EoC. Ethernet is a departure from T1 in the way the bits are organized on the line, but serves the same purpose. It uses exactly the same copper pair cabling with multiple pairs bonded to increase bandwidth. The differences are that EoC is available in increments from about 3 to 45 Mbps and it is distance limited. Near the central offices, high speeds are available. A few miles away there may be no EoC service at all. In between, there are different service levels possible.

There have been some major advances in transmission of data over copper pair wiring, with some installations supporting bandwidths as high as 100 or 200 Mbps. These are uncommon. Another copper technology, Cable broadband using coaxial copper cables and a modulation scheme called DOCSIS 3, can reliably deliver 100 Mbps or more bandwidth. Even 1 Gbps is not unheard of, although not that widely available. Another service called DS3 or T3 offers 45 Mbps over a pair of coaxial lines where available.

Fiber Optic Services for Unlimited Bandwidth
What really gets the job done at higher bandwidths is fiber optic cabling. Fiber bandwidth is nearly unlimited, especially when wavelengths are bonded to create very large services. Like, copper, fiber also has a legacy history and a newer technical approach.

Traditional fiber optic service is based on a telephony standard called SONET (Synchronous Optical NETwork). Familiar service levels are OC-3 at 155 Mbps, OC-12 at 622 Mbps and OC-48 at 2.4 Gbps. Higher levels include 10 Gbps and 40 Gbps.

Ethernet over Fiber (EoF) is a Carrier Ethernet service like EoC, but using fiber rather than copper transmission. Fiber Ethernet is highly cost competitive and readily available from 10 Mbps on up to 10 Gbps. Today’s most popular service levels are 100 Mbps Fast Ethernet and 1,000 Mbps Gigabit Ethernet (GigE). In some areas, 100 Gbps service is available to businesses.

Wavelengths Options
Fiber enjoys another advantage over copper in that it supports multiple 10 Gbps wavelengths through a process called WDM or Wavelength Division Multiplexing. This means you can run different protocols on completely separate wavelengths within the same fiber strand. This provides a high degree of flexibility for financial institutions and others with demanding applications.

As you can see, there are a wide variety of options on both copper and fiber transmissionall currently available. What works best for your organization is a function of application requirements, scale and budget. You’ll likely have multiple technologies and multiple vendors to choose from.

Fractional and Full Gigabit Ethernet Options

By: John Shepler

Today’s demanding application push for higher and higher bandwidths. Right now 10 Mbps is considered entry level and most businesses need at least 100 Mbps WAN bandwidth to ensure that real-time (VoIP, videoconferencing) and latency sensitive (cloud connections) applications won’t succumb to degradation from network congestion at peak load times. Technology intensive businesses and medium to large scale operations can easily require Gigabit connections. Fortunately, they are easy to come by and relatively inexpensive compared to times past.

One major technology upgrade in the last decade is the standardization and deployment of Carrier Ethernet. This represents a major change in MAN (Metropolitan Area Network) and WAN (Wide Area Network) bandwidth. The legacy services are SONET/SDH, a TDM (Time Division Multiplexing) switched circuit technology originally developed for massive telephone trunking between central offices. Carrier Ethernet acknowledges the fact that packet switched traffic is dominant on networks worldwide. With Ethernet on the local networks, it seems logical to keep everything in the Ethernet protocol from end to end.

Carrier Ethernet can be transported on both copper and fiber lines. The lower bandwidth offerings are found on EoC or Ethernet over Copper. This is a twisted pair technology that uses the same installed cabling that supports T1 and analog phone lines. EoC typically starts at 1 to 3 Mbps and goes up to 10 or 20 Mbps, although there are special situations that will support 50 and even 100 Mbps Ethernet over Copper. These tend to be locations very close to the telco CO where the termination equipment is installed. Copper based Ethernet loses bandwidth capacity rapidly with distance.

Ethernet over Fiber is the logical solution for many, if not most, high performance applications. Bandwidth typically starts at 10 Mbps and goes up to 10 Gbps. Popular service levels are 10 Mbps, 100 Mbps and 1 Gbps. These mirror the LAN speeds of standard, fast and gigabit Ethernet.

There are factors that make Carrier Ethernet more affordable and more flexible than the longstanding SONET services. Numerous competitive carriers have deployed their own regional and national fiber networks independent of the public telephone system. They own the fiber and terminal equipment, including last mile drops to your building. This is a very competitive field right now and lease prices per Mbps have plummeted in recent years.

Another real cost savings opportunity arises from the easy scalability designed into Carrier Ethernet services. TDM based bandwidth is technically unique at each service level. T1, DS3, OC3, OC12, OC48 and other installations require specific terminal equipment. If you wish to upgrade to a faster service, you need different equipment installed. That helps drive costs and leads to long installation times.

Carrier Ethernet bandwidths are somewhat arbitrary. Everything works the same regardless of how much traffic is being transported. In other words, Ethernet is Ethernet. What’s important is the speed of the installed port at your location. It is the maximum capacity of the port that sets a limit on the bandwidth you can order. A Fast Ethernet port is good up to 100 Mbps. A Gigabit Ethernet port raises that ceiling to 1000 Mbps.

There is nothing that prevents you from operating your network connection at a speed less than the maximum port capacity. Fractional line speeds that are rate limited by the service provider have been available for other services, such as DS3 or OC3. There are cost savings available with these, but they are not nearly as dramatic as what you’ll find with Ethernet.

In fact, scalability is a big selling point with Carrier Ethernet. Many carriers offer bandwidth upgrades with only a phone call required. The additional capacity can be online in a matter of hours or days. That compares with weeks or months for equipment changes on older services.

This is where Gigabit Ethernet makes sense even if you don’t need that much capacity today. The idea is to install a Gigabit Ethernet port, which is commonly available with a managed router provided by the carrier. The output is a standard copper or fiber Ethernet jack. You can then place your initial bandwidth order at 100 Mbps, 200 Mbps or some other level that represents your current need. When you need more bandwidth, that phone call will get you 500 Mbps, 750 Mbps or one of many other increments. These fractional Gigabit speeds can be increased until you are at the full Gigabit capacity of the port.

Is Gigabit Ethernet still too restrictive? The answer, as you may suspect, is to order a 10 GigE or even 100 GigE port. That’s the practical limit today. As bandwidth demands continue to increase, carriers will upgrade their core networks to Terabit per second and higher speeds. Soon afterwards these speeds will be available to business or organization customers with highly demanding applications.

Are you being squeezed for metro and long haul bandwidth to support your organization? If so, it is well worth your while to look into the availability and cost of fractional and full Gigabit Ethernet services, and higher if needed.

Is Your Network Capacity Drying Up?

By: John Shepler

It can sneak up on you without warning. One day, the network is running smoothly. Next day it’s all congested. How did that happen? More importantly, what can you do about it?


Network capacity, especially MAN and WAN network capacity, can dry up quickly as applications become more demanding. Video is a major bandwidth hog. Backups to remote data centers can also chew up a lot of your capacity. Worst of all is The Cloud. You might think that your troubles are over when you outsource your applications to cloud service providers. What is often forgotten is that all that user bandwidth supplied by your LAN must now be supplied by the WAN. Not just any bandwidth, mind you. It needs to be low latency bandwidth or you’ll still have troubles.

Why low latency? You know that latency is critical for sensitive real time apps like VoIP telephony or high definition video conferencing. But how about those business applications that moved from the local data center to the cloud? Latency is easy to control locally. It can be an issue on long distance connections, especially if you elected to use the Internet as your cloud connection service. Latency shows up as hesitation in cloud response. A little can be annoying. A lot can be a major productivity killer.

Fortunately, high bandwidth low latency connectivity is easier than ever to fit into your IT budget. Prices have plummeted in recent years on everything from old school T1 lines on up to the SONET/SDH and fiber optic Ethernet. Even MPLS networks for connecting multiple business locations may cost less than you think.

If you haven’t gone out for competitive price quotes in a few years, you’re in for a pleasant surprise. You may find that you can double your MAN or WAN bandwidth for the same telecom budget that you have now. By upgrading from TDM based SONET fiber optic services to Ethernet over Fiber, you may well be able to afford a lot more capacity than you have now. The cost per Mbps or Gbps is much more attractive for Carrier Ethernet, especially if you get your service from a competitive provider who can provide both core network and last mile connections on their own network.

Could you use a bandwidth upgrade soon? Perhaps even right now? Get fast bandwidth quotes customer tailored to your particular needs now.

Why Fiber Optic Metro Ethernet Makes So Much Sense

By: John Shepler

You know that there are multiple options for connecting your headquarters, branch offices, warehouses, factories, stores, schools or medical centers. Are you sure that you have an optimum solution for the network performance you need? Let’s take a closer look at at Metro Ethernet networks and see why they might be exactly what you need.

Metro Ethernet or Metro E networks are a special implementation of Metro Area Networks (MAN). MEN instead of MAN give you two big advantages or other networking options. First is that your network protocol remains as Ethernet from end to end. Second is the pricing advantage that optical Metro Ethernet networks have over other solutions.

The Ethernet in Metro Ethernet is also called Carrier Ethernet. It’s the same switched Ethernet protocol that you have running on your local area networks, but extended for transport over longer distances. The big difference between LANs and MANs or WANs is that once the traffic leaves the network you own, it needs a telecom carrier to get it across town or across the country. You can’t provide this transport on your own. You need to contract with a carrier or service provider that has the long distance connectivity.

If you have been using T1 lines, DS3 bandwidth or SONET/SDH fiber optic services to carry your traffic, you know that a protocol conversion is involved. These telecom services are based on circuit switched technology rather than the packet switched technology running on your network.

The protocol conversion is done inside an appliance or, more often, a plug-in module for your network edge router. This makes the MAN setup unique to the service and bandwidth level that’s engineered for your specific needs. Anytime you need to change something, like make a bandwidth increase, equipment and perhaps network design needs to change. This takes a lot of time and sometimes a bundle of money to implement.

Metro Ethernet networks take a different approach. The core network is IP or MPLS (Multi-Protocol Label Switching) so that it can easily transport Ethernet packets without having to convert to and from one of the TDM (Time Division Multiplexing) protocols. This opens up the opportunity to connect your networks at the layer 2 switching rather than the layer 3 routing level.

The three layer 2 Ethernet services you should be aware of are Ethernet Line (E-Line), Ethernet LAN (E-LAN) and Ethernet Tree (E-Tree). Ethernet Line is a private line connection from point A to point B. This can directly replace older technology T1, DS3 or OCx connections.

E-LAN is a meshed multipoint to multipoint service that is often the best answer for how to easily and securely connect multiple business locations on a single private network. All locations can talk to each other but each location only needs a last mile connection to the Metro Ethernet network.

E-Tree is a special service of interest to service or content providers. It is a one to many network topology that transfers files form your root out to dozens or hundreds or thousands of “leaves” that can communicate with you but not each other.

Metro Ethernet networks have a cost advantage over dedicated point to point services when you need more than a single line. You pay for use of the multi-tenant metro network plus the last mile connectivity for each location. There is another valuable cost and performance savings that comes from all-fiber solutions.

Remember that traditional Metropolitan Area Network connections are set up specifically for a certain bandwidth level. It’s hard to scale much because of equipment changes that are needed when you jump from one standard bandwidth to another. Carrier Ethernet works differently. An Ethernet connection can handle any bandwidth up to the maximum speed of the installed port. If you have a 10 Mbps port, you can have any bandwidth up to and including 10 Mbps. A 100 Mbps port will handle all bandwidth levels up to 100 Mbps. The service levels are easily scalable, often in increments as small as 1 Mbps.

What this means is that you don’t have to order all the bandwidth you think you’ll ever need just to be sure that you can quickly accommodate increases in business levels. You simply order ports (10 Mbps, 100 Mbps, 1000 Mbps or 10,000 Mbps) to support your expected requirements. Then order the bandwidth you need now with the knowledge that your ports have the reserve to quickly scale up later.

Why do all-optical Metro Ethernet solutions make sense? One advantage is that fiber can easily handle any bandwidth you require now or in the future. Another, more subtle, reason is that many service providers can connect you on fiber they own rather than something they have to lease from the local phone companies. This one-provider solution offers a significant cost savings as well as a single responsible service provider for all issues.

Do you need connectivity to multiple locations within one or more metropolitan areas? Learn more about your available Metro Ethernet options and pricing now.


Note: Photo of city lights courtesy of Wikipedia Commons.

100 Mbps Business Ethernet vs OC3 SONET Bandwidth

By: John Shepler

Many high tech companies and large corporations got into fiber optic bandwidth service years ago. The service they chose was the one available: OC3 SONET. Since then, many have upgraded to higher speeds, also in the SONET family of service, or simply stuck with the OC3 that has been performing reliably over the years.

The entrance of 100 Mbps and higher Ethernet MAN and WAN bandwidth is challenging the dominance of SONET fiber service. Long time users are taking a closer look at the competition. Companies upgrading or ordering bandwidth the for first time are doing their homework before choosing one technology over the other.

SONET (Synchronous Optical NETwork) in the SDH (Synchronous Digital Hierarchy) became the core of most metropolitan, wide area and international networks over the last decades. It was originally developed as a massive telephone trunking technology designed to bundle hundreds and thousands of simultaneous phone calls for long distance transport. With the rise of computer to computer communications and the Internet, SONET services were the logical choice to carry data packets as well as voice channels.

What does SONET have going for it? It is a very mature and well supported technology understood by all of the telephone companies and most network carriers. It is highly reliable and can survive certain fiber cuts and equipment failures. There are a number of service levels available between 155 Mbps and 100 Gbps. Costs have also come down over the years to the point where even smaller companies can consider the entry level OC3 SONET service.

Why throw over a winning service for a newer technology like Carrier Ethernet? It comes down to cost, service features and scalability.

In case you haven’t noticed, just about everything that can communicate uses Ethernet. This includes nearly every corporate LAN, all PCs, printers, scanners, routers, network switches and wireless access points. That’s expanding now to telephones, televisions and any other equipment that is joining the “Internet of Things.” Why not an all-Ethernet world?

The brand of Ethernet that leaves your property is called Carrier Ethernet. It has been standardized by and industry group, the Metro Ethernet Forum (MEF), so that it works over long distances, has the operations and maintenance features needed for carrier operations and is compatible from provider to provider.

Let’s compare two very common bandwidth services: 100 Mbps Ethernet vs OC3 SONET. Both are provided over fiber optic strands and delivered to your organization at a specified demarcation point. For Ethernet you use a simple Ethernet copper or fiber patch cord to connect your equipment to the carrier’s demarc. OC3 requires a special interface module that plugs into a router to convert between the Ethernet on your LAN and the SONET that runs on the carrier lines.

This is one reason why SONET is losing ground to Ethernet. If your network and everything on it is running Ethernet, why do a protocol conversion from Ethernet to SONET and back again at the far end just to send Ethernet packets from point to point over to the Internet? There are inefficiencies associated with that conversion process. Plus, you need a specific interface module for each SONET level. An OC3 module won’t work for OC12 or OC48.

SONET has specific service levels, although you can sometimes get fractional or rate limited services below the maximum line speed. Ethernet is scalable by design. The carrier provides an Ethernet port with a maximum speed, typically 100, 1,000 or 10,000 Mbps. Your actual service level can be any speed up to the capacity of the port. You pretty much pay for the bandwidth you are actually using rather than the capability of the circuit.

Scalability can also save you money. A 100 Mbps or Fast Ethernet connection on a 1,000 Mbps Gigabit Ethernet port can be scaled up or down easily. With SONET you start out at 155 Mbps for the entry level OC3. That sounds like 50% more bandwidth and it is. However, many companies really need 50 or 100 Mbps but had to buy 155 Mbps because it was that or nothing. If your 100 Mbps Ethernet connection bogs down, you can call the service provider and ask for an upgrade to 150 or 200 Mbps and have it in a matter of hours or days. If you tap out an OC3 connection, you have to wait days or weeks for an upgrade to the next generally available SONET level of OC12 at 622 Mbps.

Besides being able to order just the bandwidth you need now while knowing that you can easily upgrade when the need arises, Ethernet service tends to be less expensive than SONET on a per Mbps basis. But how about the quality of service? Both can deliver your packets with high reliability, low latency, and rock solid bandwidth. SONET tends to have fewer “flavors” available. It’s usually a protected ring arrangement with symmetrical dedicated bandwidth and five-nines (99.999%) reliability.

With business Ethernet, you need to be aware of what you are ordering. You can now get Carrier Ethernet with the same redundant path protection as SONET to ensure that if one circuit fails, the system will automatically switch to the other path in under 50 mSec. You can also get the same 99.999% reliability, low latency & jitter, and symmetrical dedicated bandwidth that you’ve come to expect with SONET services. However, if your applications aren’t so critical and you are more interested in saving money than in having the ultimate in performance, be aware that you can also order Ethernet services with asymmetrical bandwidth, shared bandwidth and unprotected circuits. These flavors of Ethernet work well for general Internet usage and casual PC backup to the cloud and are considerably cheaper.

Is SONET or Ethernet the best choice for your business bandwidth needs? Get free consulting help from a bandwidth expert who can also get you the best pricing from multiple carriers who offer services for your location. Also get instant online quotes for many bandwidth services up to 1 Gbps.

Ethernet over Copper FAQ - Part 3

Ethernet over Copper FAQ - Part 3

Ethernet over Copper bandwidth service may well be the perfect solution to your business needs. Here are some additional FAQs that might help answer some of the questions you may have about this relatively new technology.

Q: Can Ethernet over Copper be used for business telephone?

A: While EoC is not a direct replacement for traditional analog or ISDN PRI telephone lines, it can be a cost effective upgrade and offer increased call capacity. Ethernet over Copper easily supports VoIP and SIP Trunking because it is a packet rather than channel based line service. EoC offers low jitter, latency and packet loss to preserve voice quality. Many of today’s PBX systems now interface to SIP trunks as well as ISDN PRI to provide multiple outside phone lines at a cost savings. This gives you a wide choice of telephone line options.

Q: Does EoC work for video conferencing?

A: Ethernet over Copper is a good solution for video conferencing because it offers higher bandwidths needed for today’s high definition real-time video along with symmetrical bandwidth that provides the same speed in both directions. EoC also works well for downloading or streaming video.

Q: How does EoC support cloud services?

A: Cloud services over the Internet and by direct connection need higher bandwidth levels, symmetrical bandwidth and low latency. EoC is a dedicated business grade service that supports the cloud communication needs of small and medium size organizations. Larger companies will want Ethernet over FIber to provide the necessary bandwidth to support the productivity of many employees

Q: What is Fast Ethernet over Copper?

A: Fast Ethernet over Copper or FastE is a 100 Mbps dedicated symmetrical bandwidth service that supports the maximum speed of many network devices. FastE is now suitable for even smaller companies that have moved their IT infrastructure to the cloud. While some companies have Fast Ethernet MAN and WAN service brought in on multiple copper pair, Fast Ethernet over fiber optic link is a more popular way to get bandwidths of 100 Mbps or more.

Q: What is a combination copper-fiber solution?

A: Copper and fiber can combine to give you a reasonable bandwidth level quickly while you wait for the higher bandwidth fiber provides but isn’t immediately available. How it works is that you order both a copper and fiber solution from one provider who agrees to cancel the copper contract at no penalty as soon as the fiber is up and running.

Q: When does Ethernet over MPLS make sense?

A: The beauty of MPLS or Multi-Protocol Label Switching networks is that they can transport nearly any protocol of traffic. In fact, they routinely transport multiple protocols without any customer being aware that other customers are also using the network. Ethernet over MPLS often has cost savings benefits, especially over nationwide and international distances. With Ethernet Virtual Private LAN service, you can connect a dozen or hundreds of business sites around the world as if they were on the same corporate LAN.

Are you ready to improve your company’s connectivity or get the same performance you have now at a lower price? If so, you should check availability and pricing for Ethernet over Copper services suitable for your commercial location.


You may also be interested in reading Ethernet over Copper FAQ (Part 1) and Ethernet over Copper FAQ (Part 2).

CloudEthernet Forum Ensures Ethernet Will Dominate

After 40 years you’d think that Ethernet pretty much owns the network space. You’d be right. Token Ring...gone. Token Bus...gone. Fibre Channel... not so fast. SONET... alive and well. T-Carrier...still going strong. It’s not an Ethernet world yet, but it will be if some disrupting technology like, say, the cloud doesn’t spoil the party.

This is the impetus to the formation of a new industry standards group called CloudEthernet Forum. Founded just last month, this spinoff of the highly successful Metro Ethernet Forum (MEF) looks to “address the need for scaling and enhancing Ethernet technology to meet the stringent demands of delivering cloud services.”

What’s threatening to derail Ethernet-everything is something that Bob Metcalfe couldn’t have foreseen back in the 70’s. It’s the massive expansion of networks from hundreds to thousands to millions to billions of machines all talking at the same time. In the case of virtual machines, they are all talking within the same data center. The rise of the “Internet of Things” is only making this situation worse. Pretty soon everything manufactured will have intelligence, even if it is subtly hidden from view.

The old collision domain Ethernet protocol has long given way to a collision-free topology implemented with switches and routers. This eliminated the throughput degradation caused by all those crashing packets and had the additional advantage of doubling network capacity in full duplex mode. Physical layer Ethernet has evolved from thick coaxial cables to unshielded twisted pair telephone-type wiring to fiber optic strands. The next desperately needed improvement was allowing Ethernet to escape from the LAN into the MAN and the WAN.

This is where the Metro Ethernet Forum came into being. The MEF is an industry standards group comprised of over 200 stakeholders including telecommunications service providers, cable MSO’s, network equipment manufacturers, software developers, semiconductor producers and testing companies. Their 10 year mission has been to extend the Ethernet standards to get past the distance limitations needed to extend Ethernet outside the building or campus. They’ve been so successful that Carrier Ethernet services are now common in Metropolitan Area Networks, nationwide fiber optic networks and worldwide communications. The E-NNI or Ethernet Network to Network Interface ensures that carriers can seamlessly exchange traffic, expanding the service footprints of all participants.

What’s been good for the MAN and WAN is surely good in the cloud, where multi-tenant data centers are rapidly replacing in-house server racks. While it’s possible to build a small cloud with a few racks of equipment, what’s really happening is the building of exponentially larger data centers that need to be located near available sources of power to ensure that they can get the electricity they need to operate. These secure facilities house thousands upon thousands of physical servers that morph into millions and millions of virtual machines. Start of the art Ethernet networks are in danger of straining under the new loads.

What sort of improvements does the CloudEthernet Forum expect to make? VLAN scaling, past the current 4,096 VLAN number limit is on the list. The forum intends to recommend enhancements to minimize the effort required to setup and operate virtual machines. They’ll also work on increasing layer 2 performance that can be degraded by broadcast multicast and unicast traffic. Another initiative will be to support cloud storage requiring connections that are highly resilient with extremely low latency. The big plan is to enable millions of virtual servers and storage devices to work effectively over regional and global networks.

The initial members of the CloudEthernet Forum include Alcatel-Lucent, Verizon, Tata Communications, Spirent, PCCW, Juniper Networks, HP, Equinix and Avaya. This august group will no doubt be expanding soon as standards work gets underway.

What can we expect from Ethernet in the future? Right now the switchover from telecom-based standards such as T1, DS3 and SONET to Ethernet, Fast Ethernet and Gigabit Ethernet is accelerating. There are big advantages in linking multiple business sites with Ethernet services that can create a single bridged LAN for the entire corporation. Scalable Ethernet connections allow companies to order the bandwidth they need today while knowing that they can quickly ramp up their WAN speed when the need arises.

Ethernet is proving itself as a reliable connection to the cloud when high speed and low latency are necessary to maintain productivity. The CloudEthernet Forum will no doubt ensure that communications to and within the cloud are able to expand as fast as needed to meet the growing demands of information technology.

Are you missing out on the performance improvements and cost savings offered by Ethernet connections? Check out the expanded services and pricing available for your business locations.

FastE Fiber as MetroE for Business Ethernet Service

Business bandwidth demands are not only rising, but rising fast. What’s a good solution for fast data transfer? Fast Ethernet is an excellent option. It is readily available and affordable over fiber optic connections nationwide. Let’s take a closer look at how FastE works and how it fits into your bandwidth strategy.

Chances are that you’ve been using Fast Ethernet or FastE for years on your own network. Fast Ethernet is another name for 100 Mbps Ethernet. Standard Ethernet is 10 Mbps, Fast Ethernet is 100 Mbps and Gigabit Ethernet is 1,000 Mbps. Network Interface Cards (NICs) in every device with an Ethernet jack, also called a port, support one or more of these Ethernet speeds. For instance, a 10/100 port supports Ethernet communications at 10 Mbps and also 100 Mbps. A 10/100/1000 port includes 10 Mbps, 100 Mbps and 1000 Gbps.

Nearly every computer, switch, router, modem, firewall, printer, NAS (Network Attached Storage) Disk and other network device supports 10/100 Ethernet. The 10/100/1000 spec is becoming more and more prevalent. In both cases, these devices support Fast Ethernet at 100 Mbps.

So, what doesn’t support Fast Ethernet communication? Many MAN and WAN connections come nowhere close. Clearly computer technology has accelerated faster than communications technology. Actually, support for 100 Mbps communication over long distances has been available for a long time. It’s just that you needed special interfacing and the cost was beyond what most businesses were willing to pay.

High priced proprietary data communications are a legacy of the telephone industry. Nearly every company has ordered a DSL or T1 line to be able to communicate between business locations and connect to the public Internet. The cost of those lines has fallen dramatically in recent years. Even so, the limited bandwidth is starting to become an uncomfortable constraint on even smaller operations.

What’s changed the game recently is the introduction of Carrier Ethernet services. Carrier means that you lease these lines from a service provider, a carrier, rather than stringing the wires yourself. Any connection that goes beyond your property is handled by carriers. At one time the only carrier available was the local telephone company. Deregulation has allowed other service providers, called competitive carriers, to enter the marketplace and compete on technology and price.

Carrier Ethernet is one of those competitive services, although you’ll now find it offered by incumbent as well as competitive carriers. What’s allowed Carrier Ethernet to grow by leaps and bounds is standardization by an industry group called the MEF or Metro Ethernet Forum. Any provider that meets the MEF standards will be compatible with Carrier Ethernet equipment and interconnection with other provider networks.

Fast Ethernet is one of the Carrier Ethernet services you can order in both metropolitan and long haul connections. These are known as MAN or Metropolitan Area Networks and WAN or Wide Area Networks. The difference is really one of scale. The MAN serves a local geographical area that includes a city and surrounding suburbs. The WAN joins cities and may cross state and national borders. International WANs use undersea fiber to link far-flung destinations worldwide.

Metro networks based on Ethernet rather than the older SONET technology are sometimes referred to as MEN or Metro Ethernet Networks. You’ll hear them referred to as MetroE networks. These networks are almost always based on fiber optic rather than copper lines. Increasingly, so are the connections to the network. It’s fiber all the way for FastE and above.

What kind of connection can you make to a MetroE network. One of the most popular is the Fast Ethernet or FastE connection at 100 Mbps. Another popular service level is GigE at 1000 Mbps. What’s just emerging now as a business service level is 10 GigE at 10000 Mbps or 10 Gbps.

Going Ethernet all the way through your network, across the metro or wide area networks and to another LAN at the far end, has some real benefits. The interface is trivially easy. Your handoff from the carrier is a standard fiber or copper Ethernet jack. You’ll also be able to order both point to point connections called E-Line and meshed multi-location connections called E-LAN. Don’t think that you are stuck with only the standard Ethernet speeds either. You can generally get many increments between 10, 100, 1000 and 10000 Mbps.

The biggest advantage of all is cost savings. You’ll pay far less per Mbps for Ethernet than other services. The difference is sometimes half as much for Ethernet as SONET or other telecom services. This easily allows you to afford the bandwidth you really need for today’s communication-intensive applications such as cloud services.

Is your business bandwidth constrained? No need to be stuck at low copper technology speeds when fiber connections to high bandwidth metro and wide area networks are available and affordable. Check now for bandwidth services and prices available for your business location.