This guide will help you get started by providing very basic information (we will also point you to more advanced studies) and demonstrating that you don't need to break the bank to break into the field.
It's the communications technology that works by sending signals down hair-thin strands of glass fibre (and sometimes plastic fibre.) It began about 35 years ago in R&D labs (Corning, Bell Labs, ITT UK, etc) and was first installed in Chicago, US in 1976. By the early 1980s, fibre networks connected the major cities on each coast.
By the mid-80s, fibre was replacing all the telco copper, microwave and satellite links. In the 90s, CATV discovered fibre and used it first to enhance the reliability of their networks, a big problem. Along the way, the discovered they could offer phone and Internet service on that same fibre and greatly enlarged their markets.
Computers and LANs started using fibre about the same time as the telcos. Industrial links were among the first as the noise immunity of fibre and its distance capability make it ideal for the factory floor. Mainframe storage networks came next, the predecessors of today's fibre SANs (storage area networks.)
Other applications developed too: aircraft, ship and automobile data busses, CCTV for security, even links for consumer digital stereo!
Today fibre optics is either the dominant medium or a logical choice for every communication system.
Whenever you read an article or talk to someone about fibre optics, you need to know the point of view of the writer. Fibre optics, you see, is not all the same. Is the writer discussing "outside plant" fibre optics as used in telephone networks or CATV. Or is the article about "premises" fibre optics as found in buildings and campuses?
Just like "wire" which can mean lots of different things - power, security, HVAC, CCTV, LAN or telephone - fibre optics is not all the same. And this can be a big source of confusion to the novice. Lets define our terms.
Telephone companies, CATV and the Internet all use lots of fibre optics, most of which is outside buildings. It hangs from poles, is buried underground, pulled through conduit or is even submerged underwater. Most of it goes relatively long distances, from a few thousand feet to hundreds of miles.
Outside plant installations are all singlemode fibre (see optical fibre for fibre information), and cables often have very high fibre counts, up to 288 fibres. Cable designs are optimised for resisting moisture and rodent damage. Installation requires special pullers or ploughs, and even trailers to carry giant spools of cable.
Long distances mean cables are spliced together, since cables are not longer than about 4 km (2.5 miles), and most splices are by fusion splicing. Connectors (SC, ST or FC styles) on factory made pigtails are spliced onto the end of the cable. After installation, every fibre and every splice is tested with an OTDR.
If this sounds like big bucks, you are right! The installer usually has a temperature controlled van or trailer for splicing and/or a bucket truck. Investments in fusion splicers and OTDRs can add up to over $100,000 alone.
Contractors doing outside plant work are few and far between. Most outside plant telephone installs are done by the telco themselves, while a small number of large, specialised installers do CATV work.
By contrast, premises cabling- cabling installed in a building or campus - involves short lengths, rarely longer than a few hundred feet, with 2 to 48 fibres per cable typically. The fibre is mostly multimode, except for the enlightened user who installs hybrid cable with both multimode and singlemode fibres.
Splicing is practically unknown in premises applications. Cables between buildings can be bought with double jackets, PE for outside plant protection over PVC for building applications requiring flame retardant cable jackets, so cables can be run continuously between buildings. Today's connectors often have lower loss than splices, and patch panels give more flexibility for moves, adds and changes.
Most connectors are ST style with a few SCs here and there. Termination is by installing connectors directly on the ends of the fibres, primarily using adhesive technology or occasionally some other variety of termination method. Testing is done by a source and meter, but every installer should have a flashlight type tracer to check fibre continuity and connection.
Unlike the outside plant technician, the premises cabler (who is often also installing the power cable and Cat 5 for LANs too!) probably has an investment of less than $2,000 in tools and test equipment.
There are thousands of cabling installers who do fibre optic work. They've found out it isn't "rocket science," and their small initial investment in training, tools and test equipment is rapidly paid back.
Few installers do both outside plant and premises cabling. The companies that do are usually very large and often have separate divisions doing each with different personnel. Most contractors do nothing but premises cabling.
If you are already terminating copper wire then you are well along in learning to install fibre.
Twenty years ago, fibre was just being introduced and required PhDs from Bell Labs to install it while copper wire was easy to install. Today it is often the opposite. Because fibre is so powerful, at today's network speeds fibre is hardly working hard at all and can look to the future of ten gigabit speeds with confidence. Copper on the other hand, can handle gigabit Ethernet but only if it is carefully installed and tested with very expensive test equipment and components. Even the experts have to be very careful because it has little "headroom".
Also, if you are currently working with copper, you also have to know that LAN copper cable is delicate. It only has a 25-pound pulling tension limit and kinks will ruin the high speed performance. With fibre - even though it's glass fibre - it has more strength and greater tolerance to abuse than copper wire. (What do you think gives the strength to your "fibreglass" boat?)
OK, you might say, I can buy everything you've said so far, but isn't fibre more expensive?
Telcos and CATV operators use fibre because it's much cheaper. They optimise their network to take advantage of fibre's speed and distance advantages. In LANs, you need to follow the new EIA/TIA 568 B.3 standard to optimise the fibre usage, and then it can be cheaper than copper. How about test equipment? Guess again; fibre optic test equipment costs lots less than Cat 5e/6 testers. See Networks where we will show you how the setup for a fibre network has some surprising savings.
You wouldn't try to drive a truck or fly a plane without taking lessons. Likewise for improving your golf or tennis game. Well, the secret to fibre optics is training too. With some basic knowledge and hands-on practice gained in a training course, fibre is pretty easy to install.
Well, you can start right here, of course! But this guide is only designed to get you started and you should have "hands-on" training leading to a recognised certification program to be qualified to install fibre. First, check out our training section for information on advanced training and organisations that offer training and also check out the Fibre Optic Association for the leading fibre optic certification program in the industry. Finally, take advantage of the training offered by manufacturers and distributors whenever you can, often this training is free or cheap! (but limited to the equipment being "pushed" of course.)
See Training for more information.
Most of what we call standards are voluntary standards, created by industry groups to insure product compatibility. They are not "codes" or actual laws that you must follow to be in compliance with local ordinances.
Standards like EIA/TIA 568B ( from the Electronic Industries Alliance/Telecommunications Industry Association) which covers all of the things you need to know to install a standard premises cabling network are good guidelines for designs, but just guidelines - they are not mandatory. Standards for fibre optic components and testing have been set by several groups, but most in the US follow the EIA/TIA developed FOTPs (Fibre optic test procedures) for testing. Some of the EIA procedures are also called OFSTP (optical fibre system test procedures) like OFSTP-14 for the installed cable plant.
Standards for optical power measurements are set by NIST (the US National Institute of Standards and Technology).
The only common mandatory standard is the NEC 770 (National Electrical Code). The NEC specifies fire prevention standards for fibre optic cables. If a cable doesn't have a NEC rating - don't install it - it won't pass inspection!
A complete listing of the EIA/TIA standards is on the website of The Fibre Optic Association. Information on the EIA/TIA standards can be found on the website of most of he suppliers of structured cabling hardware.
You might think that eye damage from working with lasers would be the big concern in fibre optic installations. The reality is that high power lasers burning holes in metal or burning off warts mostly have little relevance to your typical fibre optic installation. Optical sources used in fibre optics are of much lower power levels (The exception is high power DWDM or CATV systems). Of course, you should always be careful with your eyes, especially when using a fibre optic microscope. NEVER look into a fibre unless you know no light is present - use a power meter to check it - and anyway, the light is in the infrared and you can't see anything anyway!
The real safety lecture will always be about small scraps of glass cleaved off the ends of the fibres being terminated or spliced. These scraps are very dangerous! The cleaved ends are extremely sharp and can easily penetrate your skin. If they get into your eyes, they are very hard to flush out. Don't even think about what happens if you eat one. Safety glasses are a must!
Always follow these rules when working with fibre:
With fibre optics, our tolerance to dirt is near zero. Airborne particles are about the size of the core of SM fibre - they absorb lots of light and may scratch connectors if not removed! Dirt on connectors is the biggest cause of scratches on polished connectors and high loss measurements!