Category: Fiber Optic Cables

How The NSA Taps Undersea Fiber Optic Cables

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The old saying goes that there’s more than one way to skin a cat, and that holds true for the NSA and the way it eavesdrops on global communications. In the latest round of leaks from Ed Snowden, the world’s most wanted ex-contractor reveals that it’s not just tech companies like Google and Microsoft that are willingly collaborating with the spooks – they’re also quite capable of helping themselves, tapping into the “internet’s backbone,” and siphoning off vast amounts of data from the undersea cables that make the web go round.
A report in The Atlantic details how British spies are running two rather blatant-sounding programs going by the names of “Global Telecoms Exploitation” and “Mastering the Internet”. The programs are said to be similar to PRISM, and fall under a larger operation called “Project Tempora”. According to documents leaked by Snowden, Tempora gathers up a seemingly ridiculous 21 million gigabytes of data every single day, which is then retained and analyzed for one month.
The Atlantic describes how this data is then shared between Britain’s GCHQ and the NSA, with more than 550 analysts working full time to sift through it all. In this case though, the risk towards our privacy is even greater than anything the NSA collects via PRISM, because tapping into undersea cables means that the agencies can gather the entire contents of communications, rather than just the metadata.
Speaking to security analyst Jacob Appelbaum, Ed Snowden relates how the GCHS is even “worse than” the NSA, because its system vacuums up all data indiscriminately, regardless of who it belongs too or what the content of that data is.
“If you had the choice, you should never send information over British lines or British servers,” stated Snowden.
The actual method through which GCHQ captures this data is still a matter of debate, although The Atlantic suggests that it probably involves some kind of “intercept probes” that are installed at various landing stations in the UK. These ‘intercept probes’ are said to be small devices capable of capturing the light sent down a fiber optic cable, bouncing that light around a ‘prism’, copying it, before allowing it to continue on its merry way.
A US government contractor called Glimmerglass is likely to have provided at least some of the technology that allows GCHQ to do this. Aviation Week reported that the company was carrying out similar interceptions on behalf of the US government back in 2010. Further, Glimmerglass has previously
This is all thought to be fairly recent technology however. Previously, the only way that undersea cables could be accessed was by tapping into them directly. To fulfil this purposes, the USS Jimmy Carter submarine was apparently repurposed for the job. The sub apparently accesses the cables at “regeneration points”, where their signal is amplified and where the cables are no longer bundled, but can be accessed individually.

Types of Outoodr Fiber Optic Cable

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As non-professionals, we may not be familiar with fiber optic cable, but when we need to use it, you must understand it. This article would put emphasis on introducing the following 4 Types of Outdoor Fiber Optic Cable (that from fiber-mart.com).
Aerial Bundle Cable Standards:
1. B-230 Aluminum Wire, 1350-H19 for Electrical Purposes.
2. B-231 Aluminum Conductors, Concentric-Lay-Stranded.
3. B-232 Aluminum Conductors, Concentric-Lay-Stranded, Coated Steel Reinforced (ACSR).
4. B-399 Concentric-Lay_Stranded 6201-T81 Aluminum Alloy Conductors.
5. B498 Zinc-Coated Steel Core Wire for Aluminum Conductors, Steel Reinforced (ACSR).
6. Duplex Service Drop cable meets or exceeds all applicable requirements of ANSI/ICEA S-76-474
Dry water-blocking outdoor cables: Being exploited by a dry water-blocking technology, dry water-blocking outdoor cables are designed to withstand harsh outdoor conditions. This kind of fiber optic cable is suitable for use within buildings, for outdoor installations or transitional aerial and duct applications, and for entrance facilities that require riser- or plenum-rated cable. An all-dielectric construction requires no grounding or bonding, while an armored cable construction has interlocking aluminum armor that eliminates the need for innerduct or conduit. The RoHS-compliant cable is available in singlemode (meets OS1 and proposed OS2 standards) and multimode (OM1, OM2, and10-Gbits/sec laser optimized OM3) types, and in fiber counts up to 144. This kind of fiber optic patch cord is an optimal choice under harsh environment.
Plenum outdoor cables: Plenum outdoor cables are flame-retardant and suitable for aerial, duct, riser and plenum installations. No transition splice is required when entering the building from a dedicated outside plant cable. Part of the company’s LANs solutions, these cables feature 250-µm color-coded fibers for simplified identification during installation. The loose tube design provides mechanical and environment durability, and the cable’s all-dielectric construction requires no grounding or bonding. This kind of fiber optic cable is available with 12 to 60 fibers and in 62.5- and 50-µm (including laser-optimized) and singlemode fiber outdoor versions, along with a flexible, flame-retardant, UV-resistant jacket.
Outdoor cable for factory: Featuring a proprietary pressure-extruded (core-locked) tightly bound outer jacket that firmly binds all fibers together so that the cable moves as a solid, rope-like unit, these tight-buffered cables are suited for industrial applications. This kind of fiber optic patch cable is designed with flex resistance of thousands of cycles, crush resistance of 2200 N/cm, the ability to withstand 1,000 impacts, and tensile load rating exceeding a ton. They are also constructed to withstand caustic and volatile chemicals, excessive moisture and fungus, UV exposure, and operating temperatures ranging from -55℃to 124℃. They are perfect options for factory environment.

Considerations for an Effective Fiber Optic Cable Installation

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It’s safe to say that the advent of fiber optic cable solutions has been one of the best things to happen to technology in recent years. As fiber optic cables carry signals via light rather than electricity, they can travel much greater distances (up to 5,000 miles) and at quicker speeds (up to 10 GB a second) than their coaxial counterparts. Less vulnerable to electrical interference as well, fiber optic cables are able to deliver these signals much more smoothly, often without having to boost or clean a signal that has traveled even a great distance. So with the demand on technology ever-increasing, fiber optic cables are becoming the preferred method of transmission over traditional coaxial solutions.
But how to integrate the demands which the new physical topology of fiber places on cabling installation and maintenance processes?
For starters, the National Electric Contractors Association (NECA), along with the Fiber Optic Association (FOA) jointly developed the “NECA/FOA 301-2009 Standard for Installing and Testing Fiber Optics,” which addresses the emergent demands that fiber optic cables present in the technology environment. The Safety and Installation sections of the NECA/FOA 301-2009 use Occupational Safety and Health Administration (OSHA) and National Electric Code (NEC) regulations to address the proper handling of fiber optic cables during installation and maintenance.
If you are considering using fiber optic cables in your installation, take a moment to review a selection of these procedures, and see how fiber-mart.com Products provides you with the products and tools that allow you to adhere to the below guidelines.
Before Installation:
Allow for future growth in the quantity and size of cables when determining the size of the pathway bend radius requirements.
Try to complete the installation in one pull. Prior to any installation, assess the route carefully to determine the methods of installation and obstacles likely to be encountered.
Deploying Effective Vertical Cable Runs:
Check the cable length to make sure the cable being pulled is long enough for the run.
Try to complete the installation in one pull. Prior to installation, asses the route carefully to determine the methods of installation and obstacles likely to be encountered.
When laying loops of fiber on a surface during a pull, use “figure-8” loops to prevent twisting the cable.
All hardware and support structures should follow the recommendations of TIA-569 and NECA/BICSI 568 Standards documents.
Do not exceed the cable bend radius. Fiber optic cables can be broken when kinked or bent too tightly, especially during pulling.
Drop vertical cables down rather than pulling them up.
Support cables at frequent intervals to prevent excess stress on the cable jackets.
Use cable management straps or cable ties to support cable bundles. Make sure these implements are fastened snugly, but not tightly around cable bundles.
Protecting Cables and Equipment from Fiber Residue
Small scraps of bare fiber produced as part of the termination and splicing process must be properly disposed in a safe container. Follow your local regulations – in some areas this material may be considered hazardous waste.
Thoroughly clean the work area when finished, do not use compressed air to clean off the work area.
The small size of optical fibers makes them very sensitive to dust and dirt. Maintain the highest standards of cleanliness when working with fiber optic cables to optimize its performance.
Fiber Optics, Electrical Safety and Proper Grounding and Bonding
Though fiber optic cables are generally all-dielectric, power should be disconnected for the duration of the installation process when working in areas that have installed electrical hardware and power cables.
Fusion splicers create an electric arc. Ensure that there are no flammable vapors and/or liquids present. Do not use in confined spaces as defined by OSHA.
Although most fiber optic cables are non-conductive, any metallic hardware used in fiber optic cabling systems (such as wall-mounted termination boxes, racks and patch panels) must be grounded.

5 FACTS ABOUT YOUR FIBER OPTIC CABLE CONNECTION CLEANLINESS

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Maintaining clean fiber optic cable connections is a vital part of any network installation, but proper cleaning is often overlooked. Check out the 5 facts below, and then make sure you think twice before making a connection without ensuring that your connector’s end faces are clean:

#1 – IMPROPER CLEANING OF FIBER OPTIC CABLE CONNECTIONS

Improper cleaning of fiber optic cable connections is the number one cause for network failures and contractor call-backs. USCONEC, a leader in providing passive components for high density optical interconnects, indicates that 80% of network owners and 98% of fiber optic cable installers cite contamination as the root cause of network failures. The use of dry cleaning tapes is recommended for single and multi-fiber ferrule connectors. Dry cleaning tape sticks and swabs, used with non volatile optical cleaning fluids, are acceptable for cleaning optical ports. Note that this recommendation does not include expanded beam lens (EBL) connectors or other connectors that may have anti-reflection coatings that require other special cleaning techniques.
#2 – YOU CAN’T JUDGE FIBER OPTIC CLEANLINESS WITH THE NAKED EYE
Your fiber optics cable isn’t clean, even if it appears to be with a naked eye. A dust particle, as small as one micrometer, can block up to one percent of the transmitted light through the fiber optics cable connector. A speck of dust as small as nine micrometers is still too small to see without a microscope, but it can completely block the fiber optic cable’s core. Use a fiber optic microscope with a good connector optical stage capable of 200X magnification for multi-mode connectors and 400X for single mode connectors. Digitally record your photos for future reference.
#3 – FIBER OPTIC CONTAMINATION WILL (PROBABLY) OCCUR
It’s nearly impossible to prevent contamination of fiber optic cable connections, even with the dust caps that come installed on your fiber optic cords and connectors. Common sources of fiber optic contamination include oils and dust, packaging material, and other work site debris. Wet reagent-grade isopropyl alcohol can be used for more stubborn contaminates on the ferrule surfaces if necessary (see the table below). With Legrand’s strict manufacturing processes, fiber optic cable assemblies may be clean right out of the bag, but we still recommend that you always clean and inspect the ferrules before plugging in.
#4 – PROPER PHYSICAL CONTACT OF FIBER OPTIC COMPONENTS IS CRITICAL
Fiber optic contamination prevents proper physical contact which can cause scratches and pitting defects that lead to permanent damage of your fiber optic cable. Physical Contact(PC), Ultra Physical Contact (UPC) and Angled Physical Contact (APC) connectors rely on proper physical contact to achieve a low loss, low reflection optical connection. If there is a film or debris that causes an air gap on the ferrule surface, the insertion loss of the connector increases, and so do the reflections.
#5 – DUST ATTRACTS DUST
Charged dust particles attract more particles. Because glass fibers are insulators, contaminated connector end faces will also continue to attract and accumulate more and more dust and debris. A clean fiber optic connector will appear pristine under the microscope and there will be no contaminants on the fiber’s surface, or damage to the core.

Introduction of Armored fiber cable

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Armored Fiber Cable Structure
As shown in the below picture, the optical fibers of the armored fiber cable are in the center of the cable covered by metal armor. The metal armor is covered by Kevlar firstly, then by the outer jacket. This is usually the most basic structure of armored fiber cables. For different applications, the structure will change accordingly. Kindly visit “Armored Fiber Cable Structures” for more details about different structure of the armored fiber cable.
Types of Armored Fiber Cable
Armored fiber optic cable can be divided into two types according to the metal tube: interlock armored fiber cable and corrugated armored cable. Interlocking armor is an aluminum armor that is helically wrapped around the cable and found in indoor and indoor/outdoor cables. It offers ruggedness and superior crush resistance. Corrugated armor is a coated steel tape folded around the cable longitudinally. It is found in outdoor cables and offers extra mechanical and rodent protection. Both types of these armored fiber cables enable installation in the most hazardous areas, including environments with excessive dust, oil, gas, moisture, or even damage-causing rodents.
Armored Fiber Cable for Indoor and Outdoor Use
Armored fiber cable can be used for indoor, indoor/outdoor and outside plant (OSP) applications. According to different installation environments, tight-buffered armored cable and loose-buffered armored cable are generally adopted: loose-buffer armored fiber cables are usually applied in outdoor applications, while both loose-buffered and tight-buffered armored fiber cable can fit indoor and indoor/outdoor applications.
Indoor Armored Fiber Cable
Armored cable used for indoor applications often consists of tight-buffered or loose-buffered optical fibers, strengths members and an inner jacket. The inner jacket is commonly surrounded by a spirally wrapped interlocking metal tap armor. As the fiber optic communication technology develops rapidly with FTTX, there is a fast growing demand for installing indoor fiber optic cables between and inside buildings. Indoor armored fiber cable experiences less temperature and mechanical stress and it can retard fire effectively.
Indoor/Outdoor Armored Fiber Cable
This armored fiber optic cable shares much popularity in today’s telecommunication network, which allows links from building to building eliminating the transition from indoor cable to outside plant cable. The following picture shows the structure of commonly used multi-fiber I/O armored fiber cable.
Outdoor Armored Fiber Cable
Armored cable for outdoor is made to ensure operation safety in complicated outdoor environment, and most of them are loose buffer design: with the strengthen member in the middle of the whole cable, loose tubes surround the central strength member. Inside the loose tube there is waterproof gel filled to make the cable water resistance. The combination of the outer jacket and the armor protects the fibers from gnawing animals and damages that occur during direct burial installations.
How to Select Armored Fiber Cable?
The selecting of armored fiber cable is like the selection of standard fiber cables. Fiber type (OS2, OM1, OM2, OM3, or OM4), fiber count and cable riser should all be considered. However, there is many special properties of armored fiber cable, the armored fiber cable selection should also consider many other factors.
Armor Type of Armored Fiber Cables
The market can provide armored fiber cables with different types of armor tubes which are with different structures and materials. The most commonly used armor tubes are with interlock design and corrugated design as shown in the above picture. For now, the interlock armored fiber cable is very popular and being used in a lot of indoor and indoor/outdoor applications. Corrugated armored fiber cable is often used in outdoor applications. As for the materiel for armor tube, steel and aluminum are the most commonly used. Now light steel armored fiber cables are being widely used in a lot of indoor applications, because of its lower weight and flexible properties.
Pre-Terminated or Field-Terminated Armored Fiber Cables
As there is a strong metal armored tube inside the armored fiber cable, the termination of armored fiber cable is difficult than that of standard fiber optic cables. In some applications, field-terminated armored fiber cable is better in outdoor applications. While, to save time and ensure transmission quality, many installers will choose pre-terminated armored fiber cables for indoor applications. The pre-terminated armored fiber cables provided by the market are mainly armored fiber patch cable and armored fiber trunk cable. The former looks like the standard fiber patch cable, but it is stronger than the traditional fiber patch cable and is more flexible during cable for it can provide larger bend radius. Pre-terminated armored fiber trunk cable is a length of armored fiber cable with several legs on each ends terminated with fiber optic connectors. Kindly visit “Armored Fiber Cable” page for more specific details about pre-terminated armored fiber cables.
Conclusion
Armored fiber cable presents a premium solution to secure your network by protecting fiber links, which is specified as the primary backbone due to its distinct advantages for space efficiency, lower cost of materials and installation, as well as less risk of downtime and damage.Fiber-Mart offers a great variety of armored cable.  and tested rigorously to ensure product reliability and durability, and all the fiber cables are ready in stock for delivery in volume.welcome to contact with us: product@fiber-mart.com.

Introduction to Passive Optical Network (PON)

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Seen from the entire network structures,the Passive Optical Network (PON) market is in a high-growth period due to the ongoing deployments of Fiber to the Home (FTTH) networks.today, we mainly Introduce Passive Optical Network (PON).

 

What does Passive Optical Network (PON)mean?

 

A passive optical network (PON) is a cabling system that uses optical fibers and optical splitters to deliver services to multiple access points. A PON system can be fiber-to-the-curb (FTTC), fiber-to-the-building (FTTB) or fiber-to-the-home (FTTH). A PON system consists of optical line termination (OLT) at the communication provider’s end and a number of optical network units (ONUs) at the user’s end. The term “passive” simply means that there are no power requirements while the network is up and running.

 

A PON consists of an optical line terminal (OLT) at the service provider’s central office (hub) and a number of optical network units (ONUs) or optical network terminals (ONTs), near end users. A PON reduces the amount of fiber and central office equipment required compared with point-to-point architectures. A passive optical network is a form of fiber-optic access network.In most cases, downstream signals are broadcast to all premises sharing multiple fibers. Encryption can prevent eavesdropping.upstream signals are combined using a multiple access protocol, usually time division multiple access (TDMA).

 

Feature

 

A PON takes advantage of wavelength division multiplexing (WDM), using one wavelength for downstream traffic and another for upstream traffic on a single mode fiber (ITU-T G.652). BPON, EPON, GEPON, and GPON have the same basic wavelength plan and use the 1490 nanometer (nm) wavelength for downstream traffic and 1310 nm wavelength for upstream traffic. most common is 28 dB of loss budget for both BPON and GPON, but products have been announced using less expensive optics as well. 28 dB corresponds to about 20 km with a 32-way split. Forward error correction (FEC) may provide for another 2–3 dB of loss budget on GPON systems. As optics improve, the 28 dB budget will likely increase. Although both the GPON and EPON protocols permit large split ratios (up to 128 subscribers for GPON, up to 32,768 for EPON), in practice most PONs are deployed with a split ratio of 1:32 or smaller.

 

A PON consists of a central office node, called an optical line terminal (OLT), one or more user nodes, called optical network units (ONUs) or optical network terminals (ONTs), and the fibers and splitters between them, called the optical distribution network (ODN). “ONT” is an ITU-T term to describe a single-tenant ONU. In multiple-tenant units, the ONU may be bridged to a customer premises device within the individual dwelling unit using technologies such as Ethernet over twisted pair, G.hn (a high-speed ITU-T standard that can operate over any existing home wiring – power lines, phone lines and coaxial cables) or DSL. An ONU is a device that terminates the PON and presents customer service interfaces to the user. Some ONUs implement a separate subscriber unit to provide services such as telephony, Ethernet data, or video.

An OLT provides the interface between a PON and a service provider′s core network. These typically include:

  • IP traffic over Fast Ethernet, gigabit Ethernet, or 10 Gigabit Ethernet;
  • Standard TDM interfaces such as SDH/SONET;
  • ATM UNI at 155–622 Mbit/s.

functions are separated into two parts:

  • The ONU, which terminates the PON and presents a converged interface—such as DSL, coaxial cable, or multiservice Ethernet—toward the user;
  • Network termination equipment (NTE), which inputs the converged interface and outputs native service interfaces to the user, such as Ethernet and POTS.

 

The Benefits of PON

 

As early as before, PONs began appearing in corporate networks. Users were adopting these networks because they were cheaper, faster, lower in power consumption, easier to provision for voice, data and video, and easier to manage, since they were originally designed to connect millions of homes for telephone, Internet and TV services.Passive Optical Networks (PON) provide high-speed, high-bandwidth and secure voice, video and data service delivery over a combined fiber network.

 

The main benefits of PON as below:

  • Lower network operational costs
  • Elimination of Ethernet switches in the network
  • Elimination of recurring costs associated with a fabric of Ethernet switches in the network
  • Lower installation (CapEx) costs for a new or upgraded network (min 200 users)
  • Lower network energy (OpEx) costs
  • Less network infrastructure
  • You can reclaim wiring closet (IDF) real estate
  • Large bundles of copper cable are replaced with small single mode optical fiber cable
  • PON provides increased distance between data center and desktop (>20 kilometers)
  • Network maintenance is easier and less expensive

 

Conclusion

 

According to the above article, you may have a understanding of the passive optical network.A PON network eliminates the need for switches and a wiring closet, which means fewer points of failure. Fiber-Mart manufactures and offers customized services. any question pls welcome to visit http://www.fiber-mart.com or contact us.E-mail: service@fiber-mart.com