Archive for Learning Center

Siemon intros Cisco-optimized SFP+ direct-attach copper cable assemblies for 10-GbE

Siemon has introduced a line of SFP+ copper twinax direct-attach cables (DACs) especially designed for compatibility with Cisco equipment. While Siemon’s industry-standard passive SFP+ DAC assemblies have been tested and proven for interoperability through independent testing by the UNH Interoperability Lab, the new cables are programmed specifically to work with all Cisco network equipment having 10GBASE-CX1 ports, including the company’s Catalyst and Nexus switches.

As 10 gigabit per second (Gb/s) SFP+ DACs and transceivers become common for top of rack (ToR) applications in the data center where small access switches or port extenders connect directly to servers, Siemon says its Cisco Compatible SFP+ DACs were developed specifically as a cost-effective and lower-power alternative to optical modules for these short-reach, high-speed interconnects. Ideal for high-performance computing (HPC) in networking and storage environments, the new standard-compliant assemblies easily support transfer rates up to 10+ Gb/s per lane with ultra-low crosstalk for enhanced performance.

Like all Siemon SFP+ DACs, the Cisco Compatible SFP+ DACs combine a twinaxial shielded cable construction with robust die-cast housing, superior strain relief and gold-plated contacts for enhanced support at higher frequencies with minimized EMI leakage. Siemon notes that, when the new cables are plugged into Cisco equipment, they will not trigger the warning message that a non-Cisco or third party DAC has been detected. The cables do not violate Cisco’s warranty.

“To avoid having to troubleshoot substandard cables, some switch vendors incorporate encryption or ‘vendor lock’ into their equipment to issue a warning message if a non-vendor approved cable assembly is plugged into a port,” explains John Sawdy, Senior Signal Integrity Engineer for Siemon. “While Siemon SFP+ DACs have always been compliant with IEEE and SFF industry standards with proven interoperability, we are excited to now employ encryption that prevents the warning message and offers a greater peace of mind to data center managers.”

Offered in the same lengths and wire gauges as Cisco DAC assemblies but at a significant cost reduction, Siemon’s Cisco compatible SFP+ cable assemblies are available in lengths from 1 to 5 meters. The assemblies support data transfer rates up to 10+ Gb/s per lane, meeting or exceeding current industry standard specifications.

PFOC-1200 Precision Fiber Optic Cleaning Cube/Fiber Optic End-face Cleaner

PFOC-1200 Precision Fiber Optic Cleaning Cube is a convenient, fast, portable platform for cleaning fiber optic end-faces.


Features
– Compact size: convenient, fast to work in the field or store in the tool case 
– Fiber-safe foam platform: provide ideal surface for fiber optic cleaning 
– Heavy Duty Lint-Free Wiping Material: won’t shred or tear, ideal for cleaning fiber optic  end-face 
– Low cost per clean: clean up to 1200 fiber optic end-faces 

Applications 
– Fiber Optic end-face cleaning 
– Splice preparation 
– Buffer gel removal 

Contains: 1200 cleans/Box, (200 Perforated sheets – each sheet up to 6 cleans)

Germany's Rosenberger OSI engineers longer fiber reach for data center cables

German manufacturer Rosenberger-OSI GmbH & Co. OHG has launched its PreConnect Pure, a new system for fiber-optic cabling in data centers that the company says exceeds current accepted quality standards. The new end-to-end system comprises trunk cables, patch cords, SMAP-G2 panels, and racks. The fiber-optic cables are available in multimode fiber and singlemode fiber versions.

Rosenberger-OSI says the values the system allows for insertion loss in the cables and for the quality of the fiber endfaces are more demanding than such relevant standards as IEC 61300-3-34 und IEC 61755-5 Ed. 1.0 CD. This performance enables the fiber cables to include more fiber-optic connector couplings and reach longer distances. For example, the PreConnect Pure 50 µm multimode in a 16G FibreChannel OM4 channel supports twice as many connections and for channels that are up to 15 m longer, according to the company.

Further, the new system’s interface design prevents damage or contamination of the fiber end faces during customization and installation of the cables, the company continues. This ensures that faulty installation doesn’t compromise the product quality guaranteed by the manufacturer. Compared to conventional systems, this enables savings in terms of time and cost of up to 15%, as there is no need for any on-site acceptance tests or cleaning, Rosenberger asserts.

Rosenberger specifies its PreConnect Pure system using the application limit value, which quantifies the level of insertion loss that the connections will not exceed (assuming that connectors and couplers are from a single manufacturer are used and that the connectors are free of damage, clean, and professionally installed.) The measuring procedure for the application limit value is standardized according to IEC 61300-3-34.

The highest grade of application limit values for 50 µm multimode connections specified by the IEC 61755-5 Ed. 1.0 CD standard is called Cm. To reach this grade, insertion loss (IL) may not exceed 0.6 dB for at least 97% of the channels, with a permissible mean insertion loss of 0.35 dB. The PreConnect Pure system is specified by Rosenberger OSI with a maximum insertion loss of 0.4 dB for 100% of the channels and a mean insertion loss of 0.15 dB. IEC 61755-5 Ed. 1.0 CD also sets a standard for the return loss (RL), which must reach at least 20 dB. For  the PreConnect Pure system, Rosenberger OSI guarantees a return loss of at least 40 dB.

Limit values for the optical quality of the polished endfaces of connectors are defined in the IEC 61300-3-35 standard. According to this standard, the core of a multimode cable may have up to four defects, none of which may be bigger than 5 µm. In the PreConnect Pure system, no defects are allowed, Rosenberger says. The permissible maximum size of scratches is defined by the standard as 3 µm while the manufacturers’ own standard allows scratches of up to 2 µm in size. For other zones of the cable, the PreConnect Pure standard is also more stringent than the international standards, the company says.

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Fiber Optics and Cable Television

Cable television is one network system today that is making a drastic step forward by spreading out from its long established role as an entertainment service industry which includes on-demand video and broadcast television to a high-speed data service industry.

The original design of cable television systems was the one-way, analog transmission system using coaxial cable. Today, cable television companies have found that fiber is the perfect choice for transmitting signals to multiple customer locations.

In this distribution system, each location is connected to an isolated terminal by a dedicated optical fiber and the tuner connected with each individual customer TV set is stationed in the remote terminal. Channel-selection signals are sent over the fiber from the customer location to the remote terminal. The single selected channel is the only channel transmitted over the fiber from the remote terminal to the associated TV set.

This application helps to prevent an outage for a large number of customers during a period of time and this in turn gives the cable companies a better customer relationship. It also helps to increase the company’s revenue by giving them a return path in which they can use for telephone connections and Internet.

Because of the growth in demand for communication signal transmission, cable television is in the midst of advancing their existing systems with fiber optic technology.

Benefits to End Cable Users

With fiber optic technology, cable companies can offer their customers a much better quality picture while at the same time reduce their operating costs because fiber optics cost much less to maintain.

One of the main uses of fiber optics to cable companies is the large information carrying capacity, which is hundreds of times greater than copper wire. Fiber optics also offer essential protection from electrical interference and lightning.

Fiber optics are highly reliable because they do not corrode in moisture, do not short out in water, and still perform at high speeds in any type of harsh weather. Optic cables are very lightweight because of their small size, and their long lengths make them easier to install. With fiber optic cables, there is no danger of fire hazards because they do not transfer any electricity.

Signal Improvement

Without losing power, fiber optic cables can carry television signals for a very long distance because of the technology of using very thin strands of glass. In different areas of the network, both single mode and multimode signals will be used. Signals will be sent from the central office to optical nodes using single mode fiber and then it will be converted to multimode.

Optical cables use light signals instead of electricity and this makes the signals much clearer and offers a very low signal loss over a wide range frequency with no interference to other signals.

Within the next few years, most cable television companies will have fiber optics installation, making it an advanced and versatile communications network solution.

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Best Practices for Terminating Fiber Optic Cabling

With fiber optic cabling becoming an increasingly important aspect of Local Area Network communications infrastructures, LAN installers have to be well schooled in the fundamentals of terminating fiber and installing fiber connectors. In fiber network installations, workmanship is absolutely critical to achieve acceptable results. Even a small imperfection or microscopic dirt on the face of the fiber can create significant problems with optical propagation that lead to failure of the link.

While having the proper tools is a critical factor for success, using the proper techniques is also paramount. As many LAN installers migrate from a focus on copper to handling fiber installations, it is all too easy to pick up bad habits that can lead to inefficiency, result in substandard quality and may also create safety risks.

This article will provide a hands-on tutorial regarding the best practices for quickly, safely and correctly creating fiber optic connections that meet accepted standards of quality workmanship and assure optimal coupling efficiency. The following sections are intended to help field installers avoid problems by providing a solid base of information that can act as a learning tool and a reference source for both new and experienced field technicians handling fiber-cabling termination.

Creating and Maintaining a Safe Work Environment for Handling Fiber

The first and foremost consideration that all installers must keep in mind is the need for adequate safety measures when handling and terminating fiber. Not only should technicians protect themselves during the installation process, they also need to leave the completed installation area in a safe condition for other people who follow behind them.

Fundamental safety tools include a dark work surface, such as a black work mat, and a proper trash receptacle for fiber scraps that is clearly marked as to its contents (not just a piece of black tape to stick them on). Unfortunately, too many technicians have been incorrectly trained in the field to just flick off the cleaved fiber scraps with their fingers; a practice that is grossly unsafe in buildings or schools where the subsequent occupants could be harmed by coming into contact with the nearly unnoticeable sharp fiber scraps.

The technician should always have a pair of Teflon-tipped tweezers close at hand for removal of fiber splinters. Safety glasses are an absolute requirement. Good safety practices also include washing of hands as soon as they are done handling the fiber and avoiding all food and drink during the fiber handling process.

Later on, when checking fibers with a microscope, technicians should always make sure that the other end is not connected to a power source. Installers must remember that laser light is not visible so they may not have any warning of the danger and therefore should make no assumptions without double-checking on the power status of the link. As an extra precaution, it is also a good idea to select field microscopes with built-in IR eye protection to guard against inadvertently looking into a “hot” laser.

Cutting and Stripping Fiber Cabling

The first steps in terminating fiber are to cut, strip and prep the cable. Technicians should use cutting/stripping tools that match the specific size of cable being terminated and which can perform multiple operations without having to switch tools. For example, the MiniLite-Strip is essentially two tools in one, with a small stripping v-notch to remove the buffer and coating material from 125um fiber and a large stripping v-notch to strip a wide range of outer cable jacket insulation. The blade area is heat-treated for durability and laser marked for easy identification of the stripping options. Or the Fiber Optic Stripper can handle 900/250µm fiber with replaceable precision-ground blades that cleanly cut and strip a wide range of insulations and coatings.

Even with the best-adjusted and calibrated stripper, installers still need to learn the proper technique. Continuing to keep the pressure on after the buffer has been cut can place lateral pressure on the fragile glass core. Experienced technicians learn to “feel” for the slight loss of resistance when the tool cuts through the buffer, allowing them to ease up and avoid breaking the glass fiber. Veteran fiber installers also know the importance of keeping the stripper cutting face clean because even a small particle of dirt or debris can lead to broken or scored glass core. Therefore most experienced installers keep an old toothbrush handy in order to give the blades a precautionary cleaning before each round of stripping operations. (Safety note: never use canned air for cleaning tools in a fiber installation environment.)

Another important technique when stripping fiber is to avoid “pushing from the cut” in the manner technicians typically use to strip insulation from an electrical conductor. The tendency to bend the arm and wrist in a sweeping motion can twist the fiber cabling and create excess friction between the buffer and glass fiber, causing the fiber to curl and/or break. A better method is to “draw the glass fiber out of the buffer” in a nice linear pulling motion. Also, for some beginning installers, it may make sense to simply cut the buffer in smaller segments (¼ to ⅜ inch at a time) and pull it off a piece at time—creating less friction and minimizing the tendency to curl.

The installer also needs to be sure all of the coating has also been removed from the glass fiber. With some tools this can require multiple passes, however newer tools such as the MiniLite-Stripper are designed to effectively remove both the buffer and the coating in a single pass.

Cleaning and Preparing the Fiber

The next step is cleaning and preparing the fiber cabling for mating with the connector ferrule. Fiber Optic Cleaning is critical because there is only a 1 to 2 micron clearance in between the fiber and the connector ferrule. Even a very minute amount of debris on the fiber will interfere with fitting the fiber into the ferrule. The trimmed jacket at the base of the exposed fiber should be cleaned as well, in order to make sure that the epoxy will also adhere to the jacket for added strain relief.

Cleaning should only be done with an approved solution designed specifically for fiber such as “tech-grade” Isopropyl alcohol (99 percent pure). Never use standard isopropyl alcohol (70 percent pure) because the other 30 percent may consist of water, lanolin or other substances that can contaminate the fiber and keep the epoxy from adhering properly to the glass. To support fast and efficient cleaning, many installers have turned to using specially designed split-tip swabs that are pre-loaded with 99 percent isopropyl alcohol. The split-tip fits snugly around the fiber to thoroughly clean it and a single swab can be used for many cleanings or until the alcohol is gone.

Mating the Fiber into the Connector Ferrule & Curing the Epoxy

The next step is to apply the epoxy into the connector and insert the fiber. It is also a good idea to apply a small amount of epoxy to the base at the trimmed jacket for strain relief. There are a variety of approaches that can be used for curing the epoxy. Some experienced installers have developed special methods that can significantly accelerate the curing time and therefore increase overall fiber installation productivity. Traditionally, field-curing ovens use a relatively low temperature in the range of 150-200°F, which can require from 5 to 15 minutes of curing time. Some veteran installers carry a 3M Hot-Melt oven, with a temperature of up to 400°F, which can cut the cure time down to as little as 90 seconds.

Ultimately, the choice of which method to use for attaching fiber connectors comes down to a number of tradeoffs, which involve balancing the curing time against the pot life and factoring in the ability to leverage standard tools and methods. For example, crimp on connectors can eliminate the need for using epoxy but drive up the cost of the connector itself as well as requiring proprietary tools. Room cure epoxy can eliminate the need to have a field-heating oven but can take as much as 60-90 minutes to cure, with the added complication of only a short (5-8 minute) pot life, meaning that the mixture sometimes can set up faster than it can be applied. Heat cure epoxies are no different from room cure except that they are formulated to have a long pot life but cure quickly in high temperatures. This typically gives the installer the best balance when terminating many fiber connections by providing flexibility for applying the epoxy many times before it starts to set up, along with the ability to cure each connection in a matter of a few minutes with a high-heat field oven. Experienced installers also can take advantage of this flexibility by interleaving a number of different operations (epoxy, curing, cooling, etc.) in parallel to further boost overall throughput and efficiency.

Scribing the Connection and Removing Excess Fiber

Once the epoxy has cured and the connection has cooled, the next step is to scribe the glass and remove the excess fiber. The objective of scribing is to assure a clean break across the entire face, without shattering. This involves scoring the glass close to the connector end and then running the fingers up the connector and pulling away the excess glass along the linear axis to create a clean break near the connector face.

Depending upon the specific requirements and personal preferences, different installers may choose between ruby, sapphire or carbide scribing tools. Ruby and the sapphire are industrial gemstones polished to a super-sharp edge. There is essentially no difference between the two as far as cutting properties are concerned. From a personal preference standpoint, some people like to use a lighter scribe such as the sapphire and others prefer the ruby scribe’s darker line that provides contrast against the glass. Advanced carbide scribes, such as the IDEAL 45-359, deliver a smooth superfine cutting edge that is equal to either the ruby or the sapphire gemstones.

The basic tradeoff is that gemstone scribes are slightly less expensive than carbide however they are more fragile. Dropping ruby or sapphire scribes on a hard surface can chip the cutting surface but a carbide blade is much more rugged and durable. All of IDEAL’s ruby, sapphire and carbide scribes have a unique dual-edge feature that allows each blade to be reversed to obtain a second cutting edge whenever the first one has become worn or damaged.

Polishing Processes

After the fiber has been scribed and removed, the face is polished through a series of steps to achieve a smooth surface. The first step involves an “air polish” using a 12 micron grit lapping film, in which the film is held up by one corner and the face of the connector is gently rubbed back and forth against the suspended lapping film. The objective of the air polishing step is simply to bring the level of the glass down to the level of the glue bead at the connector opening. This step only takes about 20-30 seconds and can be checked by gently rubbing a finger over the surface to assure that any jagged edge left from the scribe break has been smoothed down flush with the bead.

The next step is to use a polishing puck on a rubber or neoprene pad, along with progressively finer lapping film to smooth the fiber face down to the required level. The lapping film is placed face up on the pad and the puck is placed on the film. Then the connector is inserted into the polishing puck and is moved in “figure 8 motions” across the surface of the film to polish down both the glue bead and the glass. It is important to check the surface regularly to avoid over-polishing. Most epoxy is infused with a blue dye so it is readily apparent when the glue bead has been eliminated. The inherent give in the polishing pad allows the polishing process to produce a slightly dome-shaped result that eliminates the glue around edges and creates a smooth face for propagation of the light through the fiber.

For multimode fiber, the polishing process should progress at least down to 3 micron lapping film, with 0.5 micron being optional (always check the recommendations of the connector and fiber manufacturers). For singlemode fiber, a final polishing step with 0.5 micron film should be mandatory to minimize coupling loss and assure adequate light propagation. Some installers also finish the process with a final “wet polish” by applying a small amount of 99 percent pure isopropyl alcohol to the 0.5 micron lapping film.

The lapping films should always be cleaned between before each use. The underlying neoprene pad also should always be clean in order to avoid any grit or debris that can cause bumps in the polishing action. After polishing, the entire connection should then be cleaned with 99 percent pure isopropyl alcohol or similar solution—including both the fiber face and connector ferrule. Here again, do not use canned air and never blow on the connector face in an attempt to clean it!

Inspecting with Field Microscopes

Each connection should then be inspected using a good field fiber microscope (with built-in eye protection). For multimode fiber, the minimum magnification should be 100x. For singlemode, the magnification should be at least 200x. The installer should look for a well-defined “bulls-eye” where the center of the bulls-eye is the core of the fiber and the next ring is the cladding and the final outer ring is the connector itself. The inspection also should assure that there are no scratches, pits, chips, nicks or glue residue. The examples below show a comparison of plucked, dirty and clean fiber faces.

When selecting a field microscope, installers should look for those that include multiple adapters to handle a variety of different standard connector types. In addition, some of the newer field inspection microscopes use LEDs instead of incandescent sources for backlighting because white LEDs provide a more pure light source and make it easier on the technicians’ eyes—especially after repeated usage in the field.

As soon as the connector has been inspected, it should be immediately covered with a clean dust cap in order to protect it from dirt or damage.

Testing for Basic Continuity

Field installers also should be responsible for conducting a continuity check of the fiber link, using a basic Fiber Optic Continuity Tester—typically with a powerful Krypton light source to provide long range testing. The continuity tester should include a soft ferrule gripping membrane to protect the finished ferrules while firmly securing the connector in the tester body. In addition, visible laser-light source testers can be valuable for checking the integrity of the jacket and detecting breaks in the cladding along the whole length of the link.

Ultimately, field installers are fundamentally responsible for delivering high-quality consistent workmanship and a functioning network infrastructure, while maintaining a safe and productive work environment. By obtaining the right tools, learning the right techniques and seeking out in-depth training on proper procedures, field technicians responsible for installing fiber networks can meet all of these objectives while simultaneously achieving a well-deserved high degree of pride in their work.

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Cellular signal boosters raise stakes for wireless system integrators, custom installers

Wilson Electronics, LLC, a noted North American manufacturer of cellular signal boosters, is introducing two new boosters for its Custom Installer (WCI) product line at InfoComm 2014, in the company’s booth #C4726.

The Pro 70 and the Pro 70X are high performance cellular signal boosters designed specifically for custom integration applications in larger venues where weak cell reception is a problem indoors. Both cellular signal boosters detect and amplify weak outside cellular signals which are then redistributed inside structures, resulting in reliable voice and data coverage (including 4G) inside today’s energy efficient – but cellular challenged – buildings.

The Pro 70 booster is designed for installations where one inside antenna is sufficient for improved indoor signal coverage and ships as a complete kit including outdoor and indoor antennas, lightning surge protector and RG-11 cable. neoclean The Pro 70X booster is designed for wider indoor distribution of the cell signals in applications where four or more inside antennas are required.

“The Pro 70 and Pro 70X are optimized to provide solid coverage in larger venues,” fiber optic cleaning kit comments Joe Banos, managing director, strategic market development. “Signal boosters like the Pro 70 and Pro 70X represent a tangible new revenue opportunity for contractors and custom installers. They are a perfect opportunity to circle back to an existing customer with a new product that can demonstrably improve their cellular communications, while boosting integrators’ bottom line.”

Like the Pro 70, the Pro 70X ships as a complete kit except it includes four indoor antennas and splitters. Expansion kits consisting of additional splitters and indoor antennas are available for even wider indoor signal distribution. Like all Wilson Electronics signal boosters, these units are designed to work with all U.S. carrier networks and technologies, Ideal 45-163 feature numerous network protection techniques, and are FCC certified to the most up-to-date technical specifications.

Additionally at Infocomm, fiber optic microscope the Wilson Electronics team is showing the company’s newly redesigned RF Signal Meter, a portable, multi carrier signal detector that measures signal strength of available cellular signals at any location, and displays actual signal levels on the device’s LCD screen.

The RF Signal Meter’s new features include an internal rechargeable battery that provides up to 30 days of stand-by power and up to three hours of continuous use, a new ergonomic case for easier handheld operation and a larger, more high definition screen. The meter is typically used to map the outdoor cellular signal strengths around a building for proper outside antenna placement as well as orientation. It can also be used to verify indoor signal improvement results. fiber optic tools Cellular signal booster systems are typically no more difficult to install than a satellite TV system, notes the company.

Fiber Optic Tutorial

Some Benefits of Fiber Optics vs. Copper

  • Low loss of signal (typically less than 0.3 dB/km), so repeater-less transmission over long distances is possible
  • Large data-carrying capacity (thousands of times greater, reaching speeds of up to 1.6 Tb/s in field deployed systems and up to 10 Tb/s in lab systems respectively)
  • Greater resistance to electromagnetic noise such as radios, motors or other nearby cables
  • No electromagnetic radiation; difficult to eavesdrop
  • High electrical resistance, so safe to use near high-voltage equipment or between areas with different earth potentials
  • Low weight
  • No crosstalk between cables

What is Fiber Optics?

Fiber-optics use light pulses to transmit information down fiber lines instead of using electronic pulses to transmit information down copper lines. Looking at the components in a fiber-optic chain will give a better understanding of how the system works in conjunction with wire based systems.

At one end of the system is a transmitter. This is the place of origin for information coming on to fiber-optic lines. The transmitter accepts coded electronic pulse information coming from copper wire. It then processes and translates that information into equivalently coded light pulses. A light-emitting diode (LED) or an injection-laser diode (ILD) can be used for generating the light pulses. Using a lens, the light pulses are funneled into the fiber-optic medium where they transmit themselves down the line.

Light pulses move easily down the fiber-optic line because of a principle known as total internal reflection. “This principle of total internal reflection states that when the angle of incidence exceeds a critical value, light cannot get out of the glass; instead, the light bounces back in. When this principle is applied to the construction of the fiber-optic strand, it is possible to transmit information down fiber lines in the form of light pulses.

Fiber Optic Diagram
Diagram showing how light is guided through an optical fibre

Incident rays which fall within the acceptance cone of the fiber are transmitted, whereas those which fall outside of the acceptance cone are lost in the cladding.
Types of Fiber Optics

There are three types of fiber optic cable commonly used: single mode, multimode and plastic optical fiber (POF).

The optical fiber can be used as a medium for telecommunication and networking because it is flexible and can be bundled as cables. Although fibers can be made out of either transparent plastic (POF = plastic optical fibers) or glass, the fibers used in long-distance telecommunications applications are always glass, because of the lower optical absorption. The light transmitted through the fiber is confined due to total internal reflection within the material. This is an important property that eliminates signal crosstalk between fibers within the cable and allows the routing of the cable with twists and turns. In telecommunications applications, the light used is typically infrared light, at wavelengths near to the minimum absorption wavelength of the fiber in use.

Fibers are generally used in pairs, with one fiber of the pair carrying a signal in each direction, however bidirectional communications is possible over one strand by using two different wavelengths (colors) and appropriate coupling/splitting devices.
Single Mode Fiber

Single Mode cable is a single stand of glass fiber with a diameter of 8.3 to 10 microns that has one mode of transmission. Single Mode Fiber with a relatively narrow diameter, through which only one mode will propagate typically 1310 or 1550nm. Carries higher bandwidth than multimode fiber, but requires a light source with a narrow spectral width. Synonyms mono-mode optical fiber, single-mode fiber, single-mode optical waveguide, uni-mode fiber.

Single-mode fiber gives you a higher transmission rate and up to 50 times more distance than multimode, but it also costs more. Single-mode fiber has a much smaller core than multimode. The small core and single light-wave virtually eliminate any distortion that could result from overlapping light pulses, providing the least signal attenuation and the highest transmission speeds of any fiber cable type.

Single-mode optical fiber is an optical fiber in which only the lowest order bound mode can propagate at the wavelength of interest typically 1300 to 1320nm.

Single Mode Fiber Diagram
Multimode Fiber

Multimode cable is made of of glass fibers, with a common diameters in the 50-to-100 micron range for the light carry component (the most common size is 62.5). POF is a newer plastic-based cable which promises performance similar to glass cable on very short runs, but at a lower cost.

Multimode fiber gives you high bandwidth at high speeds over medium distances. Light waves are dispersed into numerous paths, or modes, as they travel through the cable’s core typically 850 or 1300nm. Typical multimode fiber core diameters are 50, 62.5, and 100 micrometers. However, in long cable runs (greater than 3000 feet [914.4 ml), multiple paths of light can cause signal distortion at the receiving end, resulting in an unclear and incomplete data transmission.

Multi Mode Fiber Diagram 

Construction

Fiber Optic Cable Construction 

Fiber Optic Connectors

ST Connector
ST – A slotted style bayonet type connector. This connector is one of the most popular styles.
SC Connector
SC – A push/pull type connector. This connector has emerged as one of the most popular styles.
FC Connector
FC – A slotted screw-on type connector. This connector is popular in single mode applications.
SMA Connector
SMA – A screw-on type connector. This connector is waning in popularity.
FDDI Connector
FDDI – A push/pull type dual connector. This connector is one the more popular styles.
MTRJ Connector
MTRJ – A new RJ style housing fiber connector with two fiber capability.
LC Connector
LC – A small form factor optic connector developed by Lucent Technologies.
SC Duplex
SC Duplex – Dual SC connectors.

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5-year enterprise wearables market seen reaching $18 billion

Growing at a CAGR value of 56.1% over the next five years, wearable device technologies will become an integral part of enterprise mobile enablement strategies, predicts ABI Research.

“There are cases being made for wearables in the enterprise despite the relative newness of the technology,” states Jason McNicol, senior enterprise analyst with ABI Research. “However, which wearables are primed for enterprise usage and adoption is a more important question. Wearable technology such as smart glasses and those used for healthcare are better suited for the enterprise as corporate-liable devices. Smart watches, on the other hand, will most likely follow the trend of BYOD into the enterprise.”

ABI Research has identified six kinds of wearable devices: smart glasses, cameras, smart watches, healthcare, sports and activity trackers, and 3D motion trackers. Healthcare wearables, smart glasses, and smart watches will be the dominant form-factors purchased by the enterprise and used by employees, projects the firm.

McNicol continues, “Companies like Vuzix, in partnership with SAP, and Google Glass Explorers are testing the boundaries and capabilities of smart glass technologies for the enterprise. Smart watch OEMs Samsung, LG, Sony, and Google are also trying to position their products for the enterprise. Lastly, healthcare OEMs FitLinxx, BodyMedia, and FitBit are getting involved through corporate wellness programs. Once these companies convince enterprise customers of the added value from wearables, the market will see incredible growth.”

The firm forecasts that, as expected, the North American region will be the largest and grow at a CAGR value of 39% over the next five years. More interestingly, ABI expects the Asia-Pacific region will become the second largest market for enterprise wearable technology, outpacing Europe by 2019 with a CAGR of 90%.

“Like any digital device supporting the enterprise, wearables will need to be secured and managed,” notes ABI practice director Dan Shey. “Wearable use cases in field services, maintenance, training, etc., highlight the need for enterprise mobility management providers, mobile operators, enterprise application and platform vendors, system integrators, device OEMs and other enterprise mobile suppliers to add services to support wearables. Enterprise connectivity continues at a rapid pace and its benefits are only achieved when end-to-end solutions — including security and management services — support the devices and connections.”

Fiber Optic Safety

Many people who install or maintain fiber optic cables do not take proper safety precautions to avoid the many hazards that can be caused by fiber optics. They assume that because optical fiber doesn’t carry electricity, it is not dangerous. Unfortunately, accidents occur because of this assumption.

There are three categories involved in safety protection issues when working with fiber optics. These are eye protection, fiber fragment control, and safe use of chemicals.

Hazards of Working with Fiber Optics

When working with fiber optics, a person’s eyes can be damaged by the transmitting of light. Anyone looking directly at the transmission of such frequencies can suffer loss of visual acuity or blind spots because the beam is focused on the retina.

The fibers themselves are a very serious hazard since they are small pieces of glass. If possible, use a dark mat that is chemical-resistant and as resilient as the work surface so when small fragments fall, they can be seen easily and picked up with tweezers.

When a worker is trimming, stripping, or cutting fibers, tiny fragments can penetrate the skin and become embedded, causing a serious irritation. Ingested fibers can cause internal damage since they are light enough to float in air. Because of this, workers should not eat or drink in a fiber optic work area since a fiber scrap could fall onto their food or in their drink.

There are also many chemicals and solvents used in cleaning and splicing fiber optics, which can be hazardous.

Fiber Optic Safety Rules

When working with fiber optics, all employees performing any splicing or termination activities should always wear safety glasses with side shields. Any other employees or site managers entering the work area should wear safety glasses with side shields also.

Unless an employee is absolutely sure there is not a light source at the other end, they should never look directly into the end of the cable. A power meter can be used to make certain the fiber is dark.

While working with fiber optics, the worker needs a well-ventilated and well-lit work area. Workers must avoid smoking while working with fiber optics.

Also, all food and beverages should be kept out of the work area.  Workers can wear disposable aprons to keep fiber particles off their clothing. Before leaving the work area, an employee should always check their clothing for pieces of stray fiber, and if any are found, they can remove it with double-sided tape.

A worker should wash their hands thoroughly before touching their eyes, and contact lens wearers should wash their hands before touching their lenses. Workers should also read all instructional material before handling chemicals.

A disposable container that can be tightly closed must be used for fiber scraps. When finished with a fiber optic job, all cut fiber pieces should be disposed of properly along with any used chemicals and containers. The work area should be thoroughly cleaned when job is completed.

Following these simple fiber optic safety rules can keep workers healthy and the work environment safe for all employees.

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Making Optical Fibers

The impact of the technology of optical fiber in our communication system is astounding. Many have wondered how these optical fibers are made. There are several steps involved in making an optical fiber, which include making a preform glass cylinder and drawing fibers from the preform.

Optical Glass

Optic fiberglass, a replacement for copper wires, is an ultra-high-purity silica glass that can be stretched into long, hair-thin fibers and used to transmit information over long distances. Fiber optic strands consist of an inner core of high purity glass with a high refractive index that transmits light, and an outer core of low refractive glass that keeps the light signal from seeping out the sides. The basic unit from which fibers are drawn is called a “preform.”

Preform Glass Cylinder

A preform is a glass cylinder that might be several inches long and several inches thick with a different refractive index to provide the core and cladding of the fiber. The fiber’s capability to reflect light is decided by the creation of the cladding glass relative to the core glass. The reflection usually occurs by creating a higher refractive index in the core of the glass than in the surrounding cladding glass.

Modified chemical vapor deposition, which is a chemical process used for producing high-performance solid materials, is used for making the glass for the preform. Vapor deposition, outside vapor deposition, and vapor axial deposition are the three methods usually used in this process.

The most common process used is the outside vapor deposition because it yields a low-loss fiber that is very well suited for long-distance cables. This process is highly automated and usually takes several hours for completion. Once the preform blank is cool, it is tested for quality control and then placed into a fiber drawing tower.

Drawing Fibers from Preform

The drawing tower has a temperature of 3,452 to 3.992 degrees Fahrenheit or 1,900 to 2,200 degrees Celsius. This tower consists of a furnace that heats the tip of the blank until a piece of molten glass falls from the blank, pulling a thin strand of glass, which is the beginning of an optical fiber. Then the fiber goes through a monitor to ensure a specified outside diameter. Next, ultraviolet lamps are used for applying and curing coatings. The fiber is wound on spools at the bottom of the draw and each fiber is assigned a unique identification number. The optic fiber cables are formed by being coated, colored and bundled in protective jackets.

Once the optical fibers are finished they are tested for bandwidth, tensile strength, fiber geometry, operating temperature and range of humidity, refractive index profile, attenuation, and temperature dependence of attenuation. Cables that are going to be used undersea must have the ability to conduct light under the water.

From Optical Fiber Production to Many Uses

The fibers, after they have passed quality control, are sold to many companies to improve capacity and speed, and to replace their old copper wire systems. Some types of companies that use fiber optics include network providers, telephone, power, and cable companies, industrial plants, and computer technicians.

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