Fiber Optic Connectors ― an Essential Part of Fiber Patch Cords

by www.fiber-mart.com

Fiber optic patch cord is a fiber optic cable capped at both ends with fiber optic connectors to allow it to be rapidly and conveniently connected to telecommunication equipment and to achieve accurate and precise connections. Fiber optic connector is a very important part of the fiber patch cords. This article mainly talks about what fiber optic connector is, four common types of fiber optic connectors and its relationship with fiber patch cords.

 

What Is Fiber Optic Connector

This question can be answered in two ways. Functionally, a fiber optic connector terminates the end of an optical fiber, and provides a separable connection between two elements of an electronic system without unacceptable signal distortion or power loss. Structurally, every connector includes several parts, two permanent interfaces, the contact springs in each half of the connector, the separable interface and the connector housing which maintains the location of the contacts and isolates them from one another electrically. The connectors mechanically couple and align the cores of fibers so light can pass. To achieve less light loss, more and more better connectors are made to provide more accurate misalignment of the fibers.

 

Four Common Types of Fiber Optic Connectors

Connector types of the patch cable must match the patch panels and equipment so that the patch cable can function well. There are many different connectors in use for fiber optic patch cords. The text below is a brief overview of four common connector types. The following picture shows some common fiber optic connectors.

 

Fiber Optic Connector

 

LC connector is a small form factor plastic push/pull connector with a 1.25mm ferrule. LC was first developed by Lucent. LC connector has a locking tab and a plastic housing and provides accurate alignment via its ceramic ferrule. LC has been referred to as a miniature SC connector.

 

SC connector is a plastic push/pull connector with a 2.5mm ferrule. It requires less space in patch panels than screw on connectors. For its low cost, simplicity and durability, SC connector is the second most commonly used type for polarization maintaining (PM) connections. Like LC connector, SC connector also has a locking tab and provides accurate alignment via its ceramic ferrule.

 

FC connector is a metal screw on connector with a 2.5mm ferrule. It is extensively used at the interfaces of test equipment due to its ruggedness. FC connector is the most common connector used for PM connections. And it features a metal housing, a position locatable notch and a threaded receptacle. FC connectors are nickel-plated.

 

ST connector is a metal bayonet coupled connector with a 2.5mm ferrule. It can be inserted into and removed from a fiber optic cable both quickly and easily. ST connectors are nickel-plated, keyed, spring-loaded and constructed with a metal housing. It has push-in and twist types.

 

All these four types of fiber optic connectors have different constructions and their respective applications. And there are many other kinds of fiber optic connectors, such as MU, MTRJ, E2000, SMA, etc. One important criterion for choosing fiber patch cord is to choose one with the most appropriate connector type that meets your needs.

 

Fiber Optic Connectors and Fiber Patch Cords

Fiber optic connector is an essential part of fiber patch cords. Generally, many fiber optic connectors can be manufactured for both single mode and multi-mode, simplex and duplex fiber patch cables. And fiber patch cord can have the same or different connectors at its both ends. For example, LC-LC single mode simplex fiber patch cord is a single mode simplex fiber patch cable with a simplex LC connector on each end, or SC-LC multi-mode duplex fiber patch cord is a multi-mode duplex fiber patch cable with a duplex LC connector on one end and a duplex SC connector on the other end.

Single Fiber CWDM MUX and DEMUX Tutorial

by Fiber-MART.COM

In CWDM networks, bidirectional CWDM MUX DEMUX (also called dual fiber CWDM MUX DEMUX) uses the same wavelengths for transmitting and receiving. It is often used in dual way transmission applications. The working principle is easy to understand. A duplex fiber cable links two dual-fiber CWDM MUX DEMUXs supporting the same wavelengths installed on each end of the fiber optic network. The wavelengths of the two fibers are the same, but they are running on the different directions for duplex transmission. However, in some cases, there is only one fiber available for network capacity expansion. Then, single fiber CWDM MUX and DEMUX is being used, which is very different from the dual-fiber one.

 

Understand Single Fiber CWDM MUX and DEMUX

The single fiber CWDM MUX DEMUX has a simplex line port (shown in the above picture), which is the biggest difference from the bidirectional CWDM MUX DEMUX on the appearance. There are also some single fiber CWDM MUX and DEMUX are made with a duplex port. But only one port of this duplex port is in use, the other is usually marked with N/A. For instance, our FMU single fiber CWDM MUX DEMUX also uses this design.

 

The reason why single fiber CWDM MUX and DEMUX can achieve dual way transmission is because it uses the CWDM wavelengths in a different way compared with the bidirectional CWDM MUX DEMUX. In bidirectional CWDM network, each wavelength runs on two opposite directions. However, in single fiber CWDM network, each wavelength just runs on one direction. In other works, if you want to build a dual way transmission link between two sites, you can use one wavelength over duplex fiber with dual-fiber CWDM MUX DEMUX, or use two wavelengths (one for TX and the other for RX) over simplex fiber with single fiber CWDM MUX DEMUX.

 

The above picture shows how CWDM wavelengths are used in a single fiber CWDM network. In this network, 16 wavelengths are used to support 8 pairs of dual-way transmission. On site A, there deployed an 8-channel single fiber CWDM MUX DEMUX using 8 wavelengths for transmitting and the other 8 wavelengths for received. On the opposite site B, also a single fiber CWDM MUX and DEMUX is deployed. However, the wavelengths for TX and RX are reversed. For instance, a pair of dual-way signal uses 1270nm for TX and 1290nm for RX on site A, while use 1290nm for TX and 1270nm for RX on site B. This is how the single-fiber CWDM MUX and DEMUX achieving dual-way transmission.

 

How to Select Fiber Optic Transceiver for Single Fiber CWDM MUX and DEMUX

Some might get confused about how to select the CWDM transceivers for single fiber CWDM network as there are two different wavelengths on a duplex channel port. The selection for single fiber CWDM MUX DEMUX is mainly based on the wavelength for TX. Still take the above mentioned example, on site A 1270nm is used for TX, thus, a 1270nm CWDM transceiver should be used. On site B, a 1290nm CWDM transceiver should be used. The fiber optic transceivers used for single fiber CWDM MUX and DEMUX are different on the two sites.

 

Single Fiber CWDM MUX DEMUX Case Study

Here offers a case of how to use single fiber CWDM MUX and DEMUX to build CWDM network which supports four pairs of dual-way signals. To build such a single fiber CWDM network, eight different wavelengths should be used. Here we use two of our FMU 4 channel CWDM MUX DEMUX to show the details. These two single fiber CWDM MUX DEMUX can be used together. The following shows their channel port details.

 

The following picture shows how to build a 10G single fiber CWDM network. As clearly showed, all the wavelengths just go in one direction. CWDM SFP transceivers working on 1470nm, 1510nm, 1550nm and 1590nm are linked with the CWDM MUX and DEMUX on one side of the network. The other CWDM MUX DEMUX deployed on the other end of the network is connected with CWDM SFP transceiver working on wavelengths of 1490nm, 1530nm, 1570nm, 1610nm. Thus, eight wavelengths are used for 4 pair dual-way transmission in this single fiber CWDM network.

 

fiber-mart.COM Single Fiber CWDM MUX DEMUX Solution

The above mentioned products for CWDM network are all available in fiber-mart.COM. Various CWDM MUX DEMUX and CWDM transceivers including CWDM SFP/SFP+/XFP are available and can be customized. Please note the special ports like expansion port and monitor can also be added and they are all simplex. Kindly contact sales@fiber-mart.com for more details if you are interested.

Cable Management for Fiber Patch Cords

The principles of best cable management for fiber patch cords are similar to those for copper patch cords. However, there are special considerations with optical fiber, and extra care is needed in some areas.

1. Planning
Administration activities are initiated with a change request. The change request must contain all necessary information to begin the planning process.

Searching the Records
Once a request form is received, search the records to be sure of the circuit path. The floor plans provided by the system designer should show backbone/riser cables, TRs/FDs and lOs. Any changes or additions made since your cabling infrastructure was installed should also have been documented. If the records are stored in a database, a different screen can be displayed for each user. This screen should supply you with the information you need, including the riser and horizontal fiber pairs serving the particular WAO and the locations of available fiber.

Check Design Guidelines and Match Cords
Make sure you know the specifications and design of your fiber cabling. Ensure you have patch cords matched to the installed cabling, since optical fiber cords of different types should not be mixed.

Efficient Routing
The first step in choosing a cord of the correct length is to determine the best route between its points of connection. This is usually the shortest route through horizontal and vertical cable pathways that does not obstruct or interfere with other cords and connectors on the panel. 

Note: Avoid running cords through cable pathways that are already congested.

Vertical and Horizontal Sizing
Having established the best route for the cord, find the required length by adding the horizontal and vertical distances.

Minimizing Slack
When selecting a cord to make a cross connection, avoid excessive slack and provide a neat appearance. Tight cords will pull on connectors and too much slack complicates cord management, making the panel more difficult to work on.

Efficient Management
Ensure you have cords of the right length available and that panels are fitted with correct cable management accessories. In general, a horizontal patch cord management guide is needed for every two rack units, depending on the type of optical patch panel or lightguide interconnect unit (LIU). At the optical patch panel or LIU, route patch cords equally toward both sides of the vertical cable management channels to prevent overloading one side.

Maintaining Old with New
Take care not to mix up cords of different core diameters. Additionally, cords must be of the same or higher bandwidth as the behind-the-wall cabling. System performance regarding distances cannot be guaranteed if lower rated patch cords are used. Color-coding of connectors for different fiber standards make it easy to avoid confusion.

Core Diameter
Fiber patch cords must use the same core diameter as the trunk cable. A large attenuation penalty will occur when using a 62.5μm patch cord with a 50μm trunk cable fiber or vice versa. Single mode fiber patch cords should use fiber with the same Mode Field Diameter as the trunk cable fiber.

Factory-terminated vs. Field-polished
Factory-terminated cords guarantee fiber patches with optimum performance. Field polished cords are not covered by warranties and are likely to deliver lower performance and variable quality.

Fiber Safety Precautions and Responsibilities
The lasers that carry information through fiber cables may cause irreparable damage to the retina. Always avoid looking directly into an energized optical fiber, and never attach a microscope or other magnifying device to an energized optical fiber. Always wear appropriate eye protection and ensure that unused ports are covered.

2. Preparation
To minimize disconnect time, do as much preparation as possible before performing administration activities.

Study Administrative Records
Locate the ports that must be connected or reconnected. Ensure technicians have clear information on what they need to do, including labeling information for the ports involved.

Cord Inspection

It is essential to ensure cords are of the right type and quality, and that they are clean and in good condition. Fiber patch cords should be inspected for physical damage including:
stress marks from bending on the sheath pullout of fibers from the connector cracks or scratches on fiber end in connector using a fiber examination microscope.

Cleanliness is vital in fiber optic connections so special care is needed with:

connector ends on patch cords connector ends on panels connector ends on network equipment

Materials that will be needed include:

cassettes for connector ends lint-free wipes cleaning stick for MPOs behind the wall

3. Patching

Once work on a panel is started, it should be completed without delay using best practice at each stage.

Cord Handling
Kinks, snags, pinches and poor contacts can dramatically reduce the performance of a fiber patch cord. The following factors are important in avoiding these problems.

Bend Radius
The minimum bend radius for optical fiber patch cords varies with cord diameter. For 1.6 mm and 3.0 mm cords the minimum un-loaded bend radius is 1.4 in (3.5 cm), and for MPO Patch Cords, the minimum bend radius is ten times the cord diameter. Exceeding the bend radius can result in significant additional loss and adverse impact on channel performance.

Cord Pulling and Stress
Be careful not to use excessive force during the patching process. This can stress cords and connectors, reducing their performance. If you need to use force in pulling a cord, something is wrong. Find the problem and fix it before proceeding.

Bundling
Bundling and tying cords gives the panel a neat appearance but tight bundling increases the risk of pinching. Do not tighten ties beyond the point where individual cords can rotate freely. Use only products manufactured for this purpose, and consider the use of products that can be re-used without the use of tools such as "hook and loop" strapping.

Routing Cords Through Cable Pathways
If the existing cord is the right length, it may be possible to re-use it. If this is the case, remove the cord completely and re-run it in through the cable pathways. This is the only sure way to ensure there are no tangles, kinks or strains in the cord.

Steps in Removing and Adding Fiber Patch Cords

Removing a fiber patch cord:
1. locate the existing circuit on both fields of the TR/FD or equipment room. 2. unplug the fiber patch cord at one end and cover the connector endface(s) with a dust cap. 3. cover the open port with a dust cover—some adapter ports have spring-loaded covers that automatically cover the port. 4. gently lift the cord straight up, taking up slack until its movement is detected. 5. follow the cord routing, gently removing it along its length from the cable pathways. 6. find the other end and unplug it. 7. fully remove the cord.

Adding a fiber patch cord:
1. identify the location of the new circuit. 2. plug in one end of the fiber patch cord into the fiber coupling. 3. route the fiber patch cord. 4. at the field nearest to the switch and/or computer port field, locate the new connecting point. 5. plug in the other end of the fiber patch cord into the fiber coupling.

4. Validation

Final Visual Inspection and Panel Closure
Patching must be right first time since mistakes can cause costly disruption and re-work. The time taken to make a final visual check on connections is a good investment. When the fiber patch panels are mounted in enclosures, ensure these are securely closed and, where necessary, locked, making sure that cord slack is not snagged or pinched by the doors.

Update Documentation
The final step is to update the documentation to the as-built configuration and close the work order associated with the completed change request.