The Top 5 structured fiber optic cabling faults

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1. Cause: Intermittent faults – Unidentified intermittent faults are amongst the most common and damaging issues that affect structured cabling networks. Faulty patch leads and broken or malfunctioning outlets are typical causes of this frustrating and puzzling problem, but identifying the lead or outlet that’s misfiring can be a headache in itself.

Effect: Valuable resources are wasted.

2. Cause: Wi-Fi problems – Wi-Fi can present a host of challenges when installed incorrectly – from poor coverage to intermittent connectivity. Connecting multiple devices that use conflicting Wi-Fi standards is a common cause of many problems. Equally, the Wi-Fi devices themselves may be faulty or installed in the wrong position. If neither of these factors are the cause of your issues, check if you’ve connected new Wi-Fi devices with outdated cabling.

Effect: Workforce efficiency and productivity plummet.

3. Cause: Disorganization and disorder – Structured cabling networks often become disorderly over time as multiple firms are called in to install, maintain and repair them, resulting in a confused and jumbled system. A disorganized structured cabling network can also be the result of sloppy workmanship, where engineers haven’t taken enough care during the implementation process. Untidy patching, inaccurate labelling and poor record keeping are all warning signs that shouldn’t be ignored.

Effect: Unnecessary expenditure.

4. Cause: Mismatched cabling – Even if your infrastructure is built on one category of cable, if two different manufacturers have supplied different elements of your network, you may encounter problems. A structured cabling network that isn’t consistent end-to-end can cause electrical mismatching between components and although this can be difficult to spot, the effects are plain to see.

Effect: Costly network challenges.

5. Cause: A lack of network redundancy – Organizations need a backup cabling network and an uninterruptable power supply (UPS) to ensure connectivity and power remain consistent when the lights go out unexpectedly. This is especially true of critical links and services that underpin crucial business operations, for example the structured cabling network that supports a bank’s trading floor. Despite the importance of these systems, we find that many organizations don’t consider installing them until after an incident has taken place.

Effect: A catastrophic loss of service.

Introduction of Fiber Optic Cleaving

As we know, in most cases, when a fiber is used or spliced, it is essential to prepare clean ends. Stripping, cleaving, polishing are the basic steps to ensure fiber ends clean and smooth. Cleaving, an essential step of making fiber ends clean, though it’s a simple mean, but it works surprisingly well, at least for standard glass fibers. Thus, I want to share something about the cleaving in this paper today.

As we know, in most cases, when a fiber is used or spliced, it is essential to prepare clean ends. Stripping, cleaving, polishing are the basic steps to ensure fiber ends clean and smooth. Cleaving, an essential step of making fiber ends clean, though it’s a simple mean, but it works surprisingly well, at least for standard glass fibers. Thus, I want to share something about the cleaving in this paper today.

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Basics of Fiber Optic Cleaving

Fiber optic cleaving is one of the several processes in the preparation for a fiber splice operation. The purpose of cleaving is to prepare the end of the fiber so that it makes a very nearly perfect right angle with the body of the fiber and that this end face is nearly perfectly smooth. With a well-performed cleaving operation, a clean and flat endface was created perpendicular to the length of the fiber, with no protruding glass on either end. Besides it can also help to achieve a successful low loss splice of an optical fiber.

 

The technique of Fiber Optic Cleaving

A general strategy involved in the technique of fiber optic cleaving is known as the scribe-and-tension or scribe-and-break strategy. With the use of cutting tool made from materials such as diamond, sapphire or tungsten carbide, this process involves the introduction of a crack in the fiber, then followed by the application of tensile stress in the vicinity of the crack.

However, the specific implementations of the cleaving can be various thus lead to cleaves of different qualities. Some implementations may apply the tensile force uniformly across the cross section of the fiber while others might bend the fiber around a curved surface, causing excessive tensile stress on the outside of the bend. Besides, the crack in the fiber may also be generated in different ways: the crack may be introduced at a single point on the circumference or it may be generated all along the circumference of the fiber prior to the application of the tensile force. The circumferential introduction of the crack often allows fibers of considerably large diameters to be cleaved while maintaining high quality of the cleave.

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Two Types of Fiber Optic Cleavers

As mentioned before, fiber optic cleavers can be classified into precision cleavers and cheap or scribe cleavers.

Scribe Cleavers—The scribe or manual cleaver, which is cheaper than the precision cleaver, is the most original type of fiber optic cleaver. Scribe cleavers are usually shaped like ballpoint pens with diamond tipped wedges or come in the form of tile squares. The scribe has a hard and sharp tip, generally made of carbide or diamond, to scratch the fiber manually. Then the operator pulls the fiber to break it. Since the breaking process is under manual control, it is hard to control the force, which makes the cleaving less accurate and precise. That’s why most technicians shy away from these cheap cleavers.

Precision Cleavers—As the name implies, precision cleavers can do a preciser cleaving job compared to the scribe cleavers. A precision cleaver uses a diamond or tungsten wheel/blade to provide the nick in the fiber. Tension is then applied to the fiber to create the cleaved end face. The advantage of the precision cleavers is that they can produce repeatable results through thousands of cleaves by simply just rotating the wheel/blade accordingly. Although they are more costly than scribe cleavers, precision cleavers can cut multiple fibers with increasing speed, efficiency, and accuracy. As the fusion splicers became popular, precision cleavers were developed to support various splicing works. Precision cleavers are deal for fusion splicing standard 125/250um & 125/900um fibers and preparing fiber for various pre-polished connectors.

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Operation Procedure for Fiber Cleavers

A fiber cleaver utilizes an automatic anvil drop for fewer required steps and better cleaving consistency. The automated anvil design can save time and significantly improve the quality of the cleave by eliminating human error and subpar cleaves associated with scribes and manual cleavers. To perfectly cleave optical fibers, perform the following steps:

Step 1: Open the body cover and put the stripped fiber on the v-groove.

Step 2: Close the holder cover.

Step 3: Close the cover and move the slider forward to cleave the fiber.

Step 4: Open the cover and check the cleaved fiber.

Step 5: Open the holder cover and take out the cleaved fiber.

Step 6: Remove the chip of cleaved fiber with a pair of tweezers.

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Tips on Choosing Fiber Cleavers

1.Select fiber cleavers according to your application requirements. Fiber cleavers, designed for fusion splicing, need a low average angle that is one degree or less, whereas cleavers appropriate for mechanical connectors require angles below three degrees. So determine whether you require a single-fiber or multi-fiber cleaver before you cleave the fibers at one time.

2.Think twice before purchasing a cleaver built into a splicer. If you intend to purchase the built-in cleavers, you must check whether the cleaver or splicer requires maintenance. It may cause inconvenience to technician if they loses valuable tools, which can hold up the job at hand.

3.Purchase a cleaver with the latest automation features that can save a lot of labour and time. Fiber cleavers are always continuing to evolve with new and improved features, such as automated fiber scrap collection, automated scoring mechanisms, and the latest automatic blade rotation technology.

 

Conclusion

To get good fiber optic splices or terminations, especially when using the pre-polished connectors with internal splices, it is extremely important to cleave the fiber properly. As we know, fiber splicing requires mating two fiber ends. Any defect of the ends would impact the performance of fiber splicing.To buy reliable and high precision fiber cleavers, please visit www.fiber-mart.com or contact us product@fiber-mart.com.

 

What does an Optical Attenuator do ?

With the advancement of DWDM technology, as well as the potential to flexibly upgrade the reconfigurable optical add-drop multiplexer (ROADM), the demand for optical attenuator is sure to soar, especially for optical variable attenuator.

With the advancement of DWDM technology, as well as the potential to flexibly upgrade the reconfigurable optical add-drop multiplexer (ROADM), the demand for optical attenuator is sure to soar, especially for optical variable attenuator.

 

Optical Attenuators, or fiber optic attenuators, are used in optical communications to reduce optical fiber power at a certain level. Generally, the attenuator types are classified by connector types and attenuation levels. A common version is the female to male plug type bulkhead attenuator which has a connector at one side and a adapter at the other side.in fiber optics, attenuation can also be called transmission loss. It’s the reduction in light signal intensity with regards to the distance traveled by the signal inside a transmission medium. Attenuation is an important element to limit the transmission of the digital signal driving considerable distances. Optical attenuator reduces this optical signal because it travels along a totally unoccupied space or perhaps an optical fiber.

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Optical fiber attenuators may employ several principles when utilized in fiber optic communications. One common principle may be the gap loss principle. Attenuators by using this principle are responsive to the modal distribution ahead of the attenuator. Thus, they should be utilized at or close to the transmitting end. Otherwise, the attenuators could establish less loss than intended. This problem is avoided by attenuators which use absorptive or reflective principles

Types of Fiber Optic Attenuators:

Optical attenuator takes a number of different forms. They are typically grouped as fixed optical attenuator and optical variable attenuator

The fixed attenuator, as the name implies, has a fixed attenuation level. Fixed attenuator can theoretically be designed to provide any amount of attenuation that is desired and be set to deliver a precise power output. Fixed attenuators are typically used for single-mode applications. They mate to regular connectors of the identical type for example FC, ST, SC and LC.

variable optical attenuators (VOA) resistors are replaced with solid state devices like the metal semiconductor field effect transistor (MESFETs) and PIN diodes. VOA attenuates light signal or beam inside a guarded manner. Thus producing an output optical beam with various attenuated intensity. The attenuator adjusts the ability ratio between your bright beam from the tool and the light beam entering the device over a changeable rate. VOA is usually used in fiber optic communication systems to manage optical power levels in order to prevent damages in optical receivers which may be due to irregular or fluctuating power levels. Price of commercial VOA varies depending on the manufacturing technology used.

Working Principle of Optical Attenuator

Optical attenuator usually works by absorbing the light, like sunglasses absorb the extra light energy. It typically has a working wavelength range in which it can absorb the light energy equally. It should not reflect the light since that could cause unwanted back reflection in the fiber system. Another type of attenuator utilizes a length of high-loss optical fiber, that operates upon its input optical signal power level in such a way that its output signal power level is less than the input level. The power reduction is done by such means as absorption, reflection, diffusion, scattering, deflection, diffraction, and dispersion, etc.

 

Applications of Optical attenuators 

A set optical attenuator fixed amount of attenuation of the optical road to the sunshine energy is principally used for its excellent temperature characteristics. Within the commissioning from the system, widely used in analog optical signal through the corresponding period of optical fiber attenuation or reduce the margin from the optical power the relay station may also be used to prevent saturation from the optical receiver; optical test instrument calibration scaling. For different line interface, you can use different fixed attenuator; if the interface is really a pigtail type available pigtail type optical attenuator welded towards the optical path between the two sections of fiber; If you are debugging the machine connector interface converter or inverter-type fixed attenuator.

Fiber optic attenuator is an essential passive component in the optical communication system. In practical applications often require attenuation quantity of the optical attenuator could be changed using the user needs. Fiber-Mart provides optical attenuators with various connector types, such as FC/SC/ST/LC/E2000, available with APC or UPC polish. Our fixed attenuators can be with different attenuation levels from 1 dB to 30 dB (step by 1 dB), while the variable optical attenuators (generally used as in-line attenuators) can be with a range of 0 ~ 60 dB. Customers can buy these attenuators directly in this category or Make Customized Orders. Any question pls feel free to contact us. E-mail: service@fiber-mart.com

 

FAQ about 100G Ethernet Transmission

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What standard addresses 100G, and when will this standard be complete?
The IEEE 802.3ba technical requirements were ratified in the recent April 2010 sponsor ballot. The document has been forwarded for approval to RevCom and is expected to be released in June 2010.

When is customer implementation of 100G expected?
Early end-user adoption is expected in 2010. Industry adoption is anticipated in 2013.

Where will 100G be used (in what applications)?
Core networking applications will have a future need for bandwidth beyond existing capabilities. Switching, routing and aggregation in data centers, internet exchanges and service provider peering points, and high-bandwidth applications such as video-on-demand and high-performance computing environments will drive the need for 100 Gb/s Ethernet interfaces.

What parameters affect a product’s ability to support 100G? Which of these is the limiting factor?
Bandwidth and insertion loss each impact the ability to meet the standard’s transmission distance of at least 100 meters over OM3 fiber and 150 meters over OM4 fiber. The transceiver specifications impact distance, transceiver cost and the amount of loss allocated for the fiber and connectors in the system. For products that meet the bandwidth and the cable fiber skew performance criteria, system loss will be the limiting factor in transmission distance.

What are the distances and insertion loss budgets for 100 GbE?
For multimode systems, 40 and 100 Gigabit Ethernet specify a minimum distance of 100 meters over OM3 fiber and 150 meters over OM4 fiber. OM3 and OM4 are the only multimode fiber types included in the standard. The OM3 and OM4 channel loss budgets are 1.9 dB that includes a 1.5 dB total connector loss and 1.5 dB that includes a 1.0 dB total connector loss, respectively.

What transmission method will be used for 40G and 100G?
Parallel optics transmission has been adopted for 40 and 100 Gigabit Ethernet over OM3 and OM4 fibers. Parallel optics transmission, compared to traditional serial transmission, uses a parallel optical interface where data is simultaneously transmitted and received over multiple fibers. The 40 Gigabit interface utilizes 4 x 10 Gigabit Ethernet channels on four fibers per direction. The 100 Gigabit interface utilizes 10 x 10 Gigabit Ethernet channels on 10 fibers per direction.

What is skew?
Skew is the difference in time of flight between light signals traveling on different fibers. This is relevant to the 100 Gigabit Ethernet standard that uses parallel optics. In parallel optic systems, one data stream is divided into multiple data streams and transmitted over different optical fibers to enable lower-cost transceivers to be used.

The IEEE 802.3ba standard has a cabling skew of 79 ns. Corning Cable Systems has done internal skew testing on 100G Ready Products that demonstrated compliance to a strict 0.75 ns skew requirement as defined in the InfiniBand Standard. Deployment of a connectivity solution with strict skew performance ensures compatibility of the cabling infrastructure across a variety of applications. When evaluating optical cabling infrastructure solutions for 40/100G applications, selecting one that meets the 0.75 ns skew requirement ensures performance not only for 40/100G, but for InfiniBand and future Fibre Channel data rates of 32G and beyond. Additionally, low-skew connectivity solutions validate the quality and consistency of cable designs and terminations to provide long-term reliable operation.

How will polarity work for 100G?
The CXP transceiver will be utilized for 100G transmission. The CXP transceiver has 10 transmit and 10 receive optical lane positions as depicted in Figure 1. The CXP transceiver contains 24 total positions arranged in two rows of 10 or 12 positions. One row is dedicated to transmit optical lanes and the other row to receive optical lanes. A 24-fiber MTP® Connector interfaces with the CXP transceiver. Plug & Play™ Universal Systems trunks are compatible with the CXP transceiver polarity requirements.

What about 40G transmission?
The IEEE standard addresses both 40G and 100G Ethernet transmission, so similar parameters apply. 100G Ready solutions are backwards-compatible with 40G.

Introduction to Active Optical Cable (AOC Cable)

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Data requirement is tremendous increase in year 2016 to year 2020, thus a high transmission media is required, Active Optical Cables (AOCs) could achieve high data transmission over distances, The AOC with electrical inputs as a traditional copper cable, and use optical fiber as transmission media, it is an ideal to streamlined installation for high-performance computing and storage applications with sacrificing compatibility of the existing standard electrical interfaces.
The AOC Cable generally composed  as follow:
The Active connectors are QSFP+, complied with SFF-8436 standard, could be hot-swappable in switch, router, etc.
The system with 4Tx and 4 Rx channels, could transmit data in parallel to reach duplex data transmission.
The AOC with O-E (Optical-Electronic) and E-O (Electronic – Optical) conversion module.
The ribbon optical fiber cable (generally yellow cable for SM (single mode) Cable, and Orange or Aqua for Multimode Cable).
Why Use Active Optical Cable (AOC)?
1. Compared to Copper Cables
Longer reach, using single mode fiber, could transmit over kilo meters
Lower weight and tighter bend radius, compared with traditional bulky  cooper cable, the cable is light weight and with small bending radius, easy for installation, as well as enable simpler cable management
Thinner cables, It allows better airflow for cooling
Lower power consumption
No need for power-hungry conditioning ICs on the host board
2. Compared to Optical Transceivers
Cost effective: Compatible with existing cooper interface, no need new investment
Data center/Consumer friendly: No need to worry about contamination on fiber connector
Disadvantage: Have to use extra cabinets for wiring, not able to use fiber optic patch panel

Introduction to OSFP Optical Transceiver

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OSFP is short for Octal Small Form Factor Pluggable. it is being designed to use eight electrical lanes and each lane for 50GBE to deliver 400GbE. compared with QSFP transceiver, It is slightly wider and deeper, but it still supports 36 OSFP ports per 1U front panel, enabling 14.4 Tbps per 1U.
OSFP is a conventional style of electrical interconnect, leveraging best practices that the industry has learned in the past from SFP and QSFP connectors. The electrical connector in OSFP has a single row of contacts on both top and bottom, and it provides robust electrical and signal-integrity performance. Because it’s faceplate pluggable and eld replaceable, it has a single-receptacle electrical connector.
One of the nontraditional aspects of OSFP is that it integrates thermal management (heat sinking) directly into the form factor to help cool the module, similar to the microQSFP form factor that predates it. An OSFP integrated heat sink is intended to enable modules with up to 15 W of power in a switch chassis with conventional front-to-back air ow. This accomplishes two things over a more conventional riding heat sink: It eliminates the high thermal resistance between the module and the heat sink, and, secondarily, once the air exits the back of the module form factor, it is available for cooling the silicon switch or compute chips that are downstream inside the equipment enclosure.
The OSFP receptacle does not offer backwards intermate-ability to existing modules since it favors optimizing the electrical, packaging, and thermal aspects over legacy application support.
There are multiple type of connectors supported by OSFP; Duplex LC, MPO/MTP, CS, and copper.