Category: Fiber Transceivers

Optical transceivers, Active Optic Cables, data center switches, and cable management in data centers.

The Difference Between Types of Fiber Optic Cable

by http://www.fiber-mart.com

What Are The Three Types Of Fiber Cable Available In Enterprise Networks Today?
There are three type of fiber cable in Enterprise networks today – Multimode, Singlemode, and Laser-Optimized Multimode. Which fiber cable is better? The answer depends on the parameters of the network: the applications the network will need to support over the next few years and the length of the links. It also depends on whether you are evaluating a new installation or upgrading from an installed base.
Historically there were three types of fiber cables commonly used in cabling systems: 62.5/125 µm multimode fiber (OM1), 50/125 µm multimode fiber (OM2), and singlemode fiber (OS1 or OS2). The other type of 50/125 µm fiber, optimized for low-cost 850 nm laser applications (OM3 or 4), in now probably the most common specified in cabling and LAN application standards worldwide.
The main performance difference lies in the fibers’ bandwidth, or information-carrying capacity, and in the power-coupling efficiency to light-emitting-diode (LED) sources. Bandwidth is actually specified as a bandwidth-distance product with units of MHz-km, and as the data rate goes up (MHz), the distance that data can be transmitted (km) at that rate goes down. Thus, a higher fiber bandwidth can enable you to transmit at higher data rates or for longer distances.
But while fiber bandwidth is important in determining link length and data rate, transmitter and receiver characteristics also play a critical role. Any statements on the distance capabilities of a particular fiber cable type must be made in the context of the full suite of specifications for a given application.
EXTENDING THE CAPABILITIES OF OPTICAL FIBER
There are multiple ways to extend the capability of the different types of fiber cable, some of which optical fiber standards have not yet make the most of:
Copper based-LANs for example use multi-level coding which increases transmission capacity and uses less bandwidth. This technique has yet to be used widely on multimode fiber cables.
Fiber cables can also take advantage of wavelength division multiplexing (WDM), which uses different colours/wavelengths of light across the same fiber to provide more channels.
Parallel transmission is another way of increasing link speeds, with multiple fibers used to transmit data. Also, devices such as short wavelength lasers and vertical cavity surface emitting lasers (VCSELs), are capable of providing cost-effective gigabit-rate data links over multimode fiber.
As network speeds continue to evolve ever higher, these new technologies and approaches will continue to be developed and deployed.
HOW DO YOU COMPARE MULTIMODE FIBER TYPES?
How fiber is qualified and tested should be one of the first questions asked in any situation. The bandwidth of a fiber is always specified in MHz-km and at specific wavelengths (i.e. 850 nm); however, test methods differ.
Historically, multimode fiber was tested and bandwidth specified using the OFL (Overfilled Launch) method. This method was optimized for use with LEDs. But as the gigabit networking era kicked in, lasers (VCSELs) were needed to transmit speeds above 1 Gbps, so a new test method was required called DMD (Differential Mode Delay).
In the DMD process, a laser is used to transmit pulses across the entire fiber core. As each of these pulses is received by a high-speed detector at the far end, the pulse delay is plotted and the DMD is calculated. This process is automated and covers all laser launch modes.
It is important to note that “laser” bandwidth, also referred to as Effective Modal Bandwidth (EMB), is NOT the same as “overfilled” bandwidth (OFL). For instance, 50 micron multimode fiber with an OFL bandwidth of 500 MHz-km at 850 nm does not automatically equate to a laser bandwidth of 500 MHz-km; that can only be proven by laser testing.
The standard DMD measurement process involves scanning the output from a singlemode fiber across the core of the sample multimode fiber core in radial launch positions separated by incremental steps of 2 µm. Some DMD testing facilities use a more precise laser and extract even higher resolution information by reducing the step size to 1 µm, effectively doubling the number of scanning positions. It has been shown that this ‘High Resolution DMD’ provides greater assurance of adequate bandwidth for a wider set of fibers and laser launch conditions. As vendors look for looser laser specifications to reduce cost for 10G, 40G and 100G optoelectronics, HRDMD will become more important.

How Fiber Optic Cables Work & How Engineers Use Them To Send Messages

by http://www.fiber-mart.com

first, let me show you how fiber optic cables work.

I have a bucket that I modified with a window in front and on the other side, I put a stopper in this hole right here. I have a bottle of propylene glycol, with just a little bit of creamer in it. A ring stand and of course a laser pointer. Now, keep your eye on this plug when I turn out the lights.

That’s wonderful. The light follows the liquid flow all the way to the bucket. Amazing. It does this because of total internal reflection. As the light enters the stream, it is reflected as soon as it hits the interface between here and liquid.

You can see here the first reflection and then the second and the third. This occurs because there’s a difference between the index refraction of the guide material, here propylene glycol, and the outside air in this case. Recall that anytime light strikes a surface, it can either be absorbed by the material, reflected from it or passed into and through it, the latter we call “refraction”.

It’s easier to see from a top view. Reflection and refraction could happen at the same time. But if a light ray hits the surface at an angle greater than the critical angle, it will be completely reflected and not refracted.

For this propylene glycol and air system, as long as a beam hits the surface at an angle greater than 44.35 degrees, measured from the normal, it will propagate down the stream via total internal reflection. To create the same effect in an optical fiber, engineers create a core of glass, usually pure silicon dioxide and an outside layer called “cladding,” which they also typically make from silicon dioxide but with bits of boron or germanium to decrease its index of refraction.

A one percent difference is enough to make fiber optic cables work. To make such a long, thin piece of glass, engineers heat a large glass preform. Its center is the pure core glass and the outside the cladding. They then draw or pull a fiber by winding the melt on to a wheel at speeds up to 1600 meters per second. Typically these drawing towers are several stories tall. The height allows the fiber to cool before being wound onto a drum.

One of the greatest engineering achievements was the first ocean spanning fiber optic cable called TAT-8. It extended from Tuckerton, New Jersey, following the ocean floor over 3500 miles until branching out to Widemouth, England and Penmarch, France.

Engineers designed the cable carefully to survive on the ocean floor. At its center lies the core. Less than a tenth of an inch in diameter, it contains six optical fibers wrapped around a central steel wire. They embedded this in an elastomer to cushion the fibers, surround it with steel strands and then sealed it inside a copper cylinder to protect it from water. The final cable was less than an inch in diameter, yet it could handle some 40,000 simultaneous phone calls.

The essence of how they send information through a fiber optic cable is very simple. I could have a pre-arranged signal with someone at the other end. Perhaps we will use Morse code and I just block the laser, so that the person at that end sees flashes that communicate a message.

To transmit an analog signal, like voice from a phone call along the cable, engineers use Pulse Code Modulation. We take an analog signal and cut it up into sections and then approximate the wave’s loudness or amplitude as best we can.

We want to make this a digital signal, which means discrete values of loudness and not just any value. For example, I will use four bits, which means I have 16 possible values for the loudness. So the first four sections of the signal could be approximated by about 10, 12, 14 and 15.

We then take each section and convert its amplitude to a series of ones and zeros. The first bar of value 10, when encoded, becomes one, zero, one, zero. We can do this for each section of the curve.

Now instead of looking at the green wave form or even the blue bars, we can think of the signal as a series of ones and zeros organized by time. It is that sequence that we send through a fiber optic cable of flash for one and nothing for a zero. Now of course, the exact method of encoding is known at the receiving end. So it is a trivial matter to decipher the message.

Now you may be wondering how a laser pulse can travel nearly 4000 miles across the ocean. It doesn’t without some help because the light will escape from the sides of the fibers. Look back at our propylene stream.

Here’s how the light attenuates as it travels. You can see here a narrow beam in the bucket that broadens a bit when it enters the stream and then after the first bounce, the beam leaves even broader than it entered. That’s because the interface with the air is uneven and the rays that make up the beam strike at slightly different angles.

When that beam makes its second reflection, those individual rays diverge even more. Until by the time it reaches the third bounce, many of the rays are no longer at the critical angle and can exit from the sides of the stream. Here it happens in a few inches but in fiber optic cables like TAT-8, the signal travels a stunning 50 kilometers before it needs to be amplified. Absolutely amazing.

7 Advantages of Fiber Optic Cables Over Copper Cables

by http://www.fiber-mart.com

When you’re planning a new network cable installation or considering upgrades to an existing network, you might want to consider using fiber optic cables.
Network fiber cables have some definite advantages over copper cables.
N35409M-FRONT-M1. Greater Bandwidth
Copper cables were originally designed for voice transmission and have a limited bandwidth. Fiber optic cables provide more bandwidth for carrying more data than copper cables of the same diameter. Within the fiber cable family, singlemode fiber delivers up to twice the throughput of multimode fiber.
2. Faster Speeds
Fiber optic cables have a core that carries light to transmit data. This allows fiber optic cables to carry signals at speeds that are only about 31 percent slower than the speed of light—faster than Cat5 or Cat6 copper cables. There is also less signal degradation with fiber cables.
3. Longer Distances
Fiber optic cables can carry signals much farther than the typical 328-foot limitation for copper cables. For example, some 10 Gbps singlemode fiber cables can carry signals almost 25 miles. The actual distance depends on the type of cable, the wavelength and the network.
4. Better Reliability
Fiber is immune to temperature changes, severe weather and moisture, all of which can hamper the connectivity of copper cable. Plus, fiber does not carry electric current, so it’s not bothered by electromagnetic interference (EMI) that can interrupt data transmission. It also does not present a fire hazard like old or worn copper cables can.
N81801M-FRONT-M5. Thinner and Sturdier
Compared to copper cables, fiber optic cables are thinner and lighter in weight. Fiber can withstand more pull pressure than copper and is less prone to damage and breakage.
6. More Flexibility for the Future
Media converters make it possible to incorporate fiber into existing networks. The converters extend UTP Ethernet connections over fiber optic cable. Modular patch panel solutions integrate equipment with 10 Gb, 40 Gb and 100/120 Gb speeds to meet current needs and provide flexibility for future needs. The panels in these solutions accommodate a variety of cassettes for different types of fiber patch cables.
7. Lower Total Cost of Ownership
Although some fiber optic cables may have a higher initial cost than copper, the durability and reliability of fiber can make the total cost of ownership (TCO) lower. And, costs continue to decrease for fiber optic cables and related components as technology advances.

The True Value Behind Fiber Optic Communications

by http://www.fiber-mart.com

When it comes to choosing network cables for your business, you want to make sure you choose the right kind. With several different ones available on the market, the last thing you want to do is choose the wrong type and then end up having to replace them all in a few years or even a few months. Fiber optic cables are a preference over copper cables for many IT professionals for a variety of reasons. These are just a few of the reasons fiber optic communications and cables are the better choice and the better overall value:
Why Fiber Optic Communications is a Smart Choice
The transmission of data is faster. Fiber optic cables are by far the fastest available cables on the market. While they may not be as fast as the speed of light, they are pretty close and nothing else in the market can even compare.
They maintain more of the signal. Copper wires are notorious for losing some of the signal of the transmission the further the data has to travel. With fiber optic cables, there is a lot less signal loss, or low attenuation, in other words. With fiber cables, data can travel anywhere from 984.2 feet to 24.8 miles but copper cables only allow for 9,328 feet because of their tendency to lose data.
They are less likely to break. Fiber optic cables are much more durable than copper cables. Fiber cables are made of glass but the copper cable is still more likely to break which means you would have to replace them much more often.
They do not conduct electricity. This is a huge benefit that many people do not consider. If copper wires and cables are not installed correctly, they can produce electromagnetic currents. These currents can cause a lot of problems with your network and other types of wires. With fiber optic cables, there is no chance of this happening.
They are not a fire hazard. Because they do not produce electricity and there is no electric current running through them, the light cannot catch fire and your business, as a result, will not be at risk for a loss.

Why Are Businesses Switching to Fiber Optic Cables?

by http://www.fiber-mart.com

Many businesses, especially those which depend on high data usage and transmission, have been switching their cabling over to fiber optic cables as they realize all the benefits provided by fiber optic technology. Apart from the nature of business and its built-in appetite for data, another reason for this trend is due to the increasing demands placed on companies undergoing growth – which naturally elevates the demand for data usage as well. Here are some of the benefits offered by fiber optic cables which make them so appealing.
5 Reasons Why Businesses are Making the Switch to Fiber Optic Cables
Overall cost
There might be a slightly higher initial cost associated with installing fiber optic cables, but in the long run, the investment pays off in spades. Because it is more durable, more functional, and requires less ongoing maintenance, fiber optics can end up being the most cost-effective approach for many companies.
Physical size
Performance of fiber optic cables has nothing to do with their size, unlike the case with copper-based cables. To increase speed and bandwidth on a copper line, more copper must be included, which means the physical size of the cable grows, leading to increased costs for transportation and installation.
Dependability
Copper wiring is subject to degraded performance or damage when exposed to wet weather or other wet conditions. Since there is no electricity being transmitted through fiber optic cables, there is no hazard created if they should be exposed to severe weather conditions.
Security
It is much more difficult and costly for hackers to attempt a breach of fiber optic cabling, which is why it has been subjected to far fewer attacks than other forms of cabling. With the number and the severity of cyber attacks constantly on the rise, it makes sense to consider every aspect of security for your data center.
Performance
Voice communication has always been the primary usage for copper wiring, and even though it has been adapted for data usage as well, it is limited in terms of its capabilities for speed and bandwidth. Fiber optics have no such constraints, and have already provided unprecedented rates in both categories.
Where to Find Fiber Optic Cabling and Fiber Optic Tool Box
Ease of use can be a big appeal when it’s time to install fiber optic cabling. A fiber optic tool box has all the tools needed for fiber optic cable installation, making it an easy process. Your single source provider for all fiber optic technology should be 4Fiber, an industry leader in research and production of high-quality fiber optic technology.

Why Fiber Optic Patch Cable Is Helpful

by http://www.fiber-mart.com

In the present era of technology, fiber optics has started to get a huge role in network and telecommunication. The data transfer that happens over these cables derive from we have got we’ve got the technology of optical systems. Light surf is encoded and modulated to deliver and receive data. And optical patch cord play a crucial role in finishing the conclusion-to-finish connection of systems applying this technology.
Firstly, let’s figure out what makes the fiber optic communication important. The fiber optics make sure that certain desired properties of any communication are satisfied. And the quality that they maintain with respect to these properties makes using these network cables desirable.
Interestingly, the fiber optic patch cord require being compatible with all these properties to keep up with the network quality. So the attributes desirable of the fiber cables are also good for the patches. Some of the important properties are listed below.
Rate of data transfer: Data of high volume can easily be transferred using the optic cables. In fact, with the mainline network cables, one can transfer terabytes of data every second as done in case of the worldwide Internet exchange data. The same can be said about the fiber optic patch cables. The bandwidth of these cables are extremely high.
Speed of communication: The physical communication happens over modulated waves of light. As a result, the speed of communication is extremely fast with the fiber optic networks. One can use these networks to access real time data across the globe. The patch cables are compatible with the speed and they can transfer data at the same speed as the main network cable.
Absence of attenuation: Attenuation of signal is a critical factor in most of the networks. However, for an optical network, this is practically absent. The data can traverse along the network with no amplifier installed in route. The patch cables also do not attenuate the data.
Accuracy of transferred data: The transfer of data takes place with a high degree of accuracy. The data suffers from practically no external hindrance. No signal coming form outside really changes anything about the data. As a reault, the data transfer preserves the accuracy of information exchange. The fiber optic patch cables maintain high levels of accuracy when it comes to data transfer.
Security factors: Fiber optic patch cables are as secure as the overall optical fiber network. They are extremely difficult to break into and hence the possibility of data leaking out of the network is practically minimal.
All of the above makes using fiber optic patch cables helpful when it comes to real life application. Make sure that you have got the right patch with the right length and aperture, and you are all set to enjoy the benefits of a secure and high speed communication.
fiber-mart.com provides various types of fiber optic patch cords including single mode fiber patch cables, OM1 62.5/125, OM2 50/125, 10G OM3/OM4 patch cables,armored patch cables, fiber optic pigtails, multi core patch cables, MPO/MTP patch cables and other special patch cables. And the optical patch cord connectors including LC fiber cable, ST fiber cable, SC to LC patch cable and more.