In the late 1950s and early 1960s, a number of people were working in the realm of fiber optics simultaneously. Charles Kao, who was a scientist with ITT, is often acknowledged as being one of the fathers of fiber optics. Kao theorized that if we could develop a procedure for manufacturing ultrapure, ultrathin filaments of glass, we could use them as a revolutionary new communications pipeline. Thus began the move toward researching and developing optical technology.
In 1970 came the developments that have allowed us to deploy large amounts of fiber. Corning Glassworks introduced the first development, broomsticking, a procedure for manufacturing ultrapure filaments of glass. Glass that has an inner core etched into it is melted at extremely high temperatures, and as the glass melts and drops down the tube, it begins to cool and form a strand. By the time it gets to the bottom of the tube, it is a fiber-optic thread. Being able to create the fiber cable itself solved half the equation. Because the fiber's diameter is minuscule (measured in micrometers, or microns, abbreviated μ), the light source that pulses energy on this tiny fiber also has to be minuscule. In 1970, Bell Labs completed the equation by introducing the first laser diode small enough to fit through the eye of a needle.
Characteristics of Fiber Optics
Fiber optics operates in the visible light spectrum, in the range from 1014Hz to 1015Hz. Wavelength is a measure of the width of the waves being transmitted. Different fiber-optic materials are optimized for different wavelengths. The EIA/TIA standards currently support three wavelengths for fiber-optic transmission: 850, 1,300, and 1,550 nanometers (nm). Each of these bands is about 200 nm wide and offers about 25THz of capacity, which means there is a total of some 75THz of capacity on a fiber cable. The bandwidth of fiber is also determined by the number of wavelengths it can carry, as well as by the number of bits per second that each wavelength supports. (As discussed in Chapter 1, each year, wavelength division multiplexers are enabling us to derive twice as many wavelengths as the year before, and hence they enable us to exploit the underlying capacity of the fiber cables.)
With fiber, today we can space repeaters about 500 miles (800 km) apart, but new developments continue to increase the distance or spacing. Trials have been successfully completed at distances of 2,500 miles (4,000 km) and 4,000 miles (6,400 km).
Components of Fiber Optics
The two factors that determine the performance characteristics of a given fiber implementation are the type of cable used and the type of light source used. The following sections look at the components of each.
Fiber-optic cable is available in many sizes. It can have as few as a couple pairs of fiber or it can have bundles that contain upward of 400 or 500 fiber pairs. Figure 2.8 shows the basic components of fiber-optic cable. Each of the fibers is protected with cladding, which ensures that the light energy remains within the fiber rather than bouncing out into the exterior. The cladding is surrounded by plastic shielding, which, among others things, ensures that you can't bend the fiber to the point at which it would break; the plastic shielding therefore limits how much stress you can put on a given fiber. That plastic shielding is then further reinforced with Kevlar reinforcing materialmaterial that is five times stronger than steelto prevent other intrusions. Outer jackets cover the Kevlar reinforcing material, and the number and type of outer jackets depend on the environment where the cable is meant to be deployed (e.g., buried underground, used in the ocean, strung through the air).
Figure 2.8. Fiber-optic cable
There are two major categories of fiber: multimode and single mode (also known as monomode). Fiber size is a measure of the core diameter and cladding (outside) diameter. It is expressed in the format xx/zz, where xx is the core diameter and zz is the outside diameter of the cladding. For example, a 62.5/125-micron fiber has a core diameter of 62.5 microns and a cladding diameter of 125 microns. The core diameter of the fiber in multimode ranges from 50 microns to 62.5 microns, which is large relative to the wavelength of the light passing through it; as a result, multimode fiber suffers from modal dispersion (i.e., the tendency of light to travel in a wave-like motion rather than in a straight line), and repeaters need to be spaced fairly close together (about 10 to 40 miles [16 to 64 km] apart). The diameter of multimode fiber also has a benefit: It makes the fiber more tolerant of errors related to fitting the fiber to transmitter or receiver attachments, so termination of multimode is rather easy.
The more high-performance mode of fiber, single-mode fiber, has a fiber diameter that is almost the same as the wavelength of light passing through itfrom 8 microns to 12 microns. Therefore, the light can use only one path: It must travel straight down the center of the fiber. As a result, single-mode fiber does not suffer from modal dispersion, and it maintains very good signal quality over longer distances. Therefore, with single-mode fiber, repeaters can be spaced farther apart (as mentioned earlier, they are currently about 500 miles [804 km] apart, with the distances increasing rapidly). But because single-mode fiber has such a small diameter, it is difficult to terminate, so experienced technical support may be needed to perform splices and other work with single-mode fiber.
The bottom line is that multimode fiber is less expensive than single-mode fiber but offers lower performance than single-mode fiber. Single-mode fiber is more expensive and offers higher performance, and it has been used in most of the long-distance networks that use fiber.
In the realm of light sources, there are also two categories: light-emitting diodes (LEDs) and laser diodes. The cheaper, lower-performer category is LEDs. LEDs are relatively inexpensive, they have a long life, and they are rather tolerant of extreme temperatures. However, they couple only about 3% of light into the fiber, so their data rates are low, currently about 500Mbps.
Laser diodes are capable of much higher transmission speeds than LEDs. A laser diode is a pure light source that provides coherent energy with little distortion. Therefore, laser diodes are commonly used for long-haul and high-speed transmission. Laser diodes offer better performance than LEDs, and they are more expensive, although the cost of these components has been dropping about 40% per year. As the costs drop, performance is also improving; in the very near future, we should see the introduction of light sources that pulse one trillion bits per second and beyond, although this, of course, will require a lot more power.
To carry traffic over the long haul, the best combination is single-mode fiber with laser diodes. For very short implementations, such as in a campus network environment, the cost-efficiencies of multimode fiber and LEDs may make this combination a more appropriate solution. But in general, as we look forward to the new developments in optical equipmentsuch as wavelength division multiplexers, optical cross-connects, and optical switcheswe will need higher-quality fiber to interface to. It appears that roughly 95% of the world's fiber plant is not prepared to operate at the high speed that we are evolving to with optical equipment. Even though we have been actively deploying fiber for years, it is not all compatible with the next generation of optical equipment. This means that we will see new companies laying new highways and using the latest and greatest in fiber, as well as older companies having to upgrade their plants if they want to take advantage of what optical equipment has to offer.
How Fiber-Optic Transmission Works
As shown in Figure 2.9, in fiber-optic transmission, the digital bitstream enters the light source, in this case the laser diode. If a one bit is present, the light source pulses light in that time slot, but if there is a zero bit, there is no light pulse (or vice versa, depending on how it is set up). The absence or presence of light therefore represents the discrete ones and zeros. Light energy, like other forms of energy, attenuates as it moves over a distance, so it has to run though an amplification or repeating process. As mentioned earlier, until about 1994, electronic repeaters were used with fiber, so the optical signal would have to stop; be converted into electrical energy; be resynchronized, retimed, and regenerated; and then be converted back into optical energy to be passed to the next point in the network. This was a major problem because it limited the data rate to 2.5Gbps. But some developments introduced in the early 1990s dramatically changed long-distance communications over fiber. The next section talks about those innovations.
Figure 2.9. Fiber-optic transmission
Innovations in Fiber Optics: EDFAs and WDM
As mentioned in Chapter 1, erbium-doped fiber amplifiers (EDFAs) are optical repeaters made of fiber doped with erbium metal at periodic intervals (normally every 30 to 60 miles [50 to 100 km]). The introduction of EDFAs made it possible for fiber-optic systems to operate at 10Gbps. EDFAs also opened the way for Wavelength Division Multiplexing (WDM), the process of dividing the optical transmission spectrum into a number of nonoverlapping wavelengths, with each wavelength supporting a single high-speed communications channel. Today, undersea cables need to be designed with WDM in mind; until 1998 or so, most were not, which means they have inappropriate repeater spacing. So, again, for the next generation of fiber communications over undersea cables, many systems will have to be replaced or upgraded.
Since the development of WDM, several categories have been introduced, including Dense Wavelength Division Multiplexing (DWDM) and Coarse Wavelength Division Multiplexing (CWDM). There have also been developments in new generations of fiber and amplifiers; all these are discussed in Chapter 11.
Fiber All Around the World
Some years ago there was a fascinating story in Wired magazine, chronicling a project called FLAG that involved a 28,000-km fiber loop around the globe. I encourage you to read it. Its title is "Mother Earth Mother Board: The Hacker Tourist Ventures Forth Across the Wide and Wondrous Meatspace of Three Continents, Chronicling the Laying of the Longest Wire on Earth," and it is available at http://wired-vig.wired.com/wired/archive/4.12/ffglass_pr.html.
An optical multiplexing hierarchy was the predecessor to WDM: Synchronous Digital Hierarchy (SDH) and Synchronous Optical Network (SONET). SDH/SONET is a time division multiplexed system, and SDH/SONET fiber cables make use of just one wavelength. (SDH/SONET is discussed in detail in Chapter 4, "The PSTN.") DWDM can operate over 16 or more wavelengths. Products that are currently shipping support upward of 192 wavelengths and operate at data rates of 2.5Gbps to 10Gbps. New systems have emerged that operate at 40Gbps. Meanwhile, research is also under way with dense wavelength division multiplexers that will be capable of supporting as many as 15,000 wavelengths. These developments are just the tip of the iceberg of what we can expect in coming years. (WDM and DWDM, as well as many other aspects of optical networking, are discussed in more detail in Chapter 11.)
Forecasting Optical Developments
The basic equation in assessing the development of optics is that every year, the data rate that can be supported on a wavelength doubles and the number of wavelengths that can be supported on a fiber doubles as well.
Applications of Fiber Optics
Fiber has a number of key applications. It is used in both public and private network backbones, so the vast majority of the backbones of the PSTNs worldwide have been upgraded to fiber. The backbones of Internet providers are fiber. Cable TV systems and power utilities have reengineered and upgraded their backbones to fiber as well.
Surprisingly, electric power utilities are the second largest network operator after the telcos. They have vast infrastructures for generating and transmitting electricity; these infrastructures rely on fiber-optic communications systems to direct and control power distribution. After they have put in fiber, electric companies have often found themselves with excess capacity and in a position to resell dark fiber to interested partiesincluding several telcos! When you lease dark fiber, you're basically leasing a pair of fibers without the active electronics and photonics included, so you are responsible for acquiring that equipment and adding it to the network. But with dark fiber, you're not paying for bandwidthyou're paying for the physical facilityand if you want to upgrade your systems to laser diodes that pulse more bits per second, or if you want to add a wavelength division multiplexer to access more wavelengths, these changes will not affect your monthly cost for the fiber pair itself. Power utilities have been big players in the deployment of fiber throughout the world.
Another application of fiber is in the local loop. There are numerous arrangements of fiber in the local loop, including HFC (i.e., fiber to a neighborhood node and then coax on to the subscribers); fiber to the curb with a twisted-pair solution to the home; fiber to the home that terminates on its own individual optical unit; and passive optical networking, which greatly reduces the cost of bringing fiber to the home. Chapter 12 covers the details of these various arrangements.
Another application for fiber is in LANs. Fiber Distributed Data Interface (FDDI) was the first optical LAN backbone that offered 100Mbps backbone capacity, but today it has largely been displaced by the use of twisted-pair 100Mbps Ethernet. Fiber is now used in Gigabit Ethernet and 10 Gigabit Ethernet, although some of the newer revisions also allow the use of twisted-pair (see Chapter 6).
Another application of fiber involves the use of imagery or video when extremely high resolution is critical (e.g., in telemedicine). Consider an application that involves the transmission of images between an imaging center and a doctor's office. Say you went to the imaging center to have an x-ray of your lungs, and in the transmission of your lung x-ray, a little bit of noise in the network put a big black spot on your lung. If that happened, you would likely be scheduled for radical surgery. So, for this type of application, you want a network that ensures that very little noise can affect the resolution and hence the outcome of the analysis. A lot of this use of fiber occurs in early-adopter scenarios where there are applications for imaging, such as universities, health care environments, and entertainment applications.
Another frontier where fiber is now of great interest is in home area networks (HANs). This is a very interesting area because when broadband access comes into your home, you see a shift in where the bottleneck resides, from the local loop to inside the home. Broadband access into the home requires a broadband network within the home to properly distribute the entertainment, data, and voice services that are collectively transported over that broadband access. Many new homes are now being wired with fiber from the start, but it is also possible to retrofit an older home to provide high-quality entertainment and data networks. (HANs are discussed in more detail in Chapter 12.)
Advantages and Disadvantages of Fiber Optics
The advantages of fiber optics are as follows:
The disadvantages of fiber optics include the following:
Part I: Communications Fundamentals
Telecommunications Technology Fundamentals
Traditional Transmission Media
Establishing Communications Channels
Part II: Data Networking and the Internet
Data Communications Basics
Local Area Networking
Wide Area Networking
The Internet and IP Infrastructures
Part III: The New Generation of Networks
Broadband Access Alternatives
Part IV: Wireless Communications
Wireless Communications Basics
WMANs, WLANs, and WPANs
Emerging Wireless Applications