The recent state of Optical Fiber Connectors

We have already covered the fundamentals of the optics connectors in a previous post. We explained the differences in polishing, RL and IL and choosing the right one. Nonetheless, technology keeps moving forward, and we need to be aware of the latest advancements so we can properly take advantage of the resources at our disposal.

 

In this post, we’ll take a look at the most recent developments in the field of connectors. So feel free to join the ride, and explore what the next generation of connectors is all about!

 

Nowadays, physical space has become an important issue. With the advent of more connection needs, size has gotten increasingly valuable when it comes to adopting new connections for the future. This is where splice-on connectors come in handy since they have expanded the catalog of resources for companies that need to establish new connections in their plants.

 

New connectors, ranging from fiber-to-the-x (FTTx) to no-epoxy/no-polish (NENP), for example, are now being used to augment speed and diminishes expenses. These new modules allow to decrease the size required for a “splice tray” and diminish the cost of space needed. This shall be the trend followed by the new developments in optic fiber connectors. 

 

The increasing demand for access networks and the increased value of rack space has originated the inclusion of small form connectors or multi-fiber connectors with high-bandwidth features. This need is represented by repair, need to improve fiber routing, fiber system upgrades and installation of space to temporary connections.

 

The current needs of the optic fiber scene have aimed towards a technology and equipment-cost perspective. The demand and the technology and have made a notorious impact on the cost and performance of the next generation of connectors. 

 

The other area that has been dramatically changed in field termination, is represented by the need for an angled polished connector (APC) end face as the interface. APC interface has become the industry standard for FTTx and other outside plant equipment. That being said, the cost of material per termination has been reduced considerably as the new generation of connectors has become commonly utilized.

 

Anaerobic (epoxy/polish):

 

These connectors have been made by taking the existing field fiber and adhering it inside the ferrule. These anaerobic terminations are low-cost connectors that offer a robust performance over time and throughout changes in temperature. Anaerobic connectors have now been justifiably accepted in the optic fiber industry. Perhaps the only limitation of these terminations it that their efficiency is highly determined by the expertise of the technicians who install them and handle them.

 

No-epoxy no-polish (NENP):

These connectors posses a physical way of retaining the field fiber by compression and meet the fiber retention qualities while offering/providing a factory-polished end face for mating in the adapter. The only conditions for a proper performance of this type of terminations are represented by location and stability. The retention technology that these terminations offer is established by its manufacturers. The only foreseeable limitation is the impact of temperature in these terminations, which can cause unwanted margins of loss.

NENP angled polished connectors: The introduction of consistent APC terminations has filled the necessity of field-installed APC connectors in FTTx-type projects. However, the incorporation and alignment of these connectors are both time-consuming and extremely craft-sensitive. The consequence is a considerable need for a higher maintenance, which may add cost to the termination.

The variables of field deployment range from temperature change, performance variation due to factory fiber characteristics, quality of field fiber with regards to quality of fiber, tools and termination process. Taking into consideration all of these variables when defining a mechanical connector, the manufacturers have been able to consistently meet the insertion of loss requirements. The individual optical performance requirements have to be addressed with the specific mechanical connector manufacturer to guarantee a flawless optical plant is being put together.

Fusion splice-on connectors:

 

These connectors remove some variables and add strength. The vast majority of splice-on connectors are now available for use in the field and they are able to retain a consistent splice loss and return loss over temperature and time. These connectors can keep the performance of a splice-on pigtail without having to store a splice sleeve and they stand for being the most robust and consistent option for field-installable fiber connectors.

 

MPO/MTP® connector:

 

These terminations provide offers strength in numbers. Holding the strength from the fusion splice type connector and expanding its flexibility for field deployment generates a field-installable multi-fiber connector known as the MPO (multi-fiber push on). This connector offers the same benefits as a single fiber fusion splice-on connector but terminates up to 12 fibers per connection. This type of connector helps with restoration, repair and upgrade projects of existing MPO networks. The factory end face and fusion spliced optical path produce a solid alternative for field termination. The MPO termination has been growing and will continue to grow with fiber consolidation and high-speed bandwidth connections.

 

Self-contained patch and splice modules:

 

This is a variation of field-installable termination that goes into a self-contained field-installable patch and splice module. Field-installable modules employ a traditional pigtail splice to an adapter; fortunately, the need for factory pre-termination is removed. This is very convenient to those cases where space is limited or when you need a small footprint fiber termination. Because this module is self-contained, patch and splice, this option constitutes a cost-effective solution when adding a circuit to an existing fiber rack system or colocation type deployment. 

Taking a decision towards which one of these options are the best for your needs is certainly not easy, but that doesn’t mean that you won’t be able to make a proper decision. You just need to gather a good amount of solid information based on what your system really needs. 

 

It is mandatory then to have a good sense of the space available for potential adjustments. That being said, you then need to take a close look at the available options offered by trustworthy manufacturers. If you do a thorough research, rest assured that you will find the resources that will accommodate your needs. 

 

So don’t despair if you suspect that you’re not able to find a perfect solution to your problem because more often than not, that seems to be the case. Just make sure to focus on having a solid understanding on the demands, study proficiently the resources at your disposal and then get prepared to make the ultimate decision that will help you satisfy what you most urgently need for.

 

We really hope you can find all of this information very useful for your projects. 

The recent state of Optical Fiber Connectors

We have already covered the fundamentals of the optics connectors in a previous post. We explained the differences in polishing, RL and IL and choosing the right one. Nonetheless, technology keeps moving forward, and we need to be aware of the latest advancements so we can properly take advantage of the resources at our disposal.

 

In this post, we’ll take a look at the most recent developments in the field of connectors. So feel free to join the ride, and explore what the next generation of connectors is all about!

 

Nowadays, physical space has become an important issue. With the advent of more connection needs, size has gotten increasingly valuable when it comes to adopting new connections for the future. This is where splice-on connectors come in handy since they have expanded the catalog of resources for companies that need to establish new connections in their plants.

 

New connectors, ranging from fiber-to-the-x (FTTx) to no-epoxy/no-polish (NENP), for example, are now being used to augment speed and diminishes expenses. These new modules allow to decrease the size required for a “splice tray” and diminish the cost of space needed. This shall be the trend followed by the new developments in optic fiber connectors. 

 

The increasing demand for access networks and the increased value of rack space has originated the inclusion of small form connectors or multi-fiber connectors with high-bandwidth features. This need is represented by repair, need to improve fiber routing, fiber system upgrades and installation of space to temporary connections.

 

The current needs of the optic fiber scene have aimed towards a technology and equipment-cost perspective. The demand and the technology and have made a notorious impact on the cost and performance of the next generation of connectors. 

 

The other area that has been dramatically changed in field termination, is represented by the need for an angled polished connector (APC) end face as the interface. APC interface has become the industry standard for FTTx and other outside plant equipment. That being said, the cost of material per termination has been reduced considerably as the new generation of connectors has become commonly utilized.

 

Anaerobic (epoxy/polish):

 

These connectors have been made by taking the existing field fiber and adhering it inside the ferrule. These anaerobic terminations are low-cost connectors that offer a robust performance over time and throughout changes in temperature. Anaerobic connectors have now been justifiably accepted in the optic fiber industry. Perhaps the only limitation of these terminations it that their efficiency is highly determined by the expertise of the technicians who install them and handle them.

 

No-epoxy no-polish (NENP):

These connectors posses a physical way of retaining the field fiber by compression and meet the fiber retention qualities while offering/providing a factory-polished end face for mating in the adapter. The only conditions for a proper performance of this type of terminations are represented by location and stability. The retention technology that these terminations offer is established by its manufacturers. The only foreseeable limitation is the impact of temperature in these terminations, which can cause unwanted margins of loss.

NENP angled polished connectors: The introduction of consistent APC terminations has filled the necessity of field-installed APC connectors in FTTx-type projects. However, the incorporation and alignment of these connectors are both time-consuming and extremely craft-sensitive. The consequence is a considerable need for a higher maintenance, which may add cost to the termination.

The variables of field deployment range from temperature change, performance variation due to factory fiber characteristics, quality of field fiber with regards to quality of fiber, tools and termination process. Taking into consideration all of these variables when defining a mechanical connector, the manufacturers have been able to consistently meet the insertion of loss requirements. The individual optical performance requirements have to be addressed with the specific mechanical connector manufacturer to guarantee a flawless optical plant is being put together.

Fusion splice-on connectors:

 

These connectors remove some variables and add strength. The vast majority of splice-on connectors are now available for use in the field and they are able to retain a consistent splice loss and return loss over temperature and time. These connectors can keep the performance of a splice-on pigtail without having to store a splice sleeve and they stand for being the most robust and consistent option for field-installable fiber connectors.

 

MPO/MTP® connector:

 

These terminations provide offers strength in numbers. Holding the strength from the fusion splice type connector and expanding its flexibility for field deployment generates a field-installable multi-fiber connector known as the MPO (multi-fiber push on). This connector offers the same benefits as a single fiber fusion splice-on connector but terminates up to 12 fibers per connection. This type of connector helps with restoration, repair and upgrade projects of existing MPO networks. The factory end face and fusion spliced optical path produce a solid alternative for field termination. The MPO termination has been growing and will continue to grow with fiber consolidation and high-speed bandwidth connections.

 

Self-contained patch and splice modules:

 

This is a variation of field-installable termination that goes into a self-contained field-installable patch and splice module. Field-installable modules employ a traditional pigtail splice to an adapter; fortunately, the need for factory pre-termination is removed. This is very convenient to those cases where space is limited or when you need a small footprint fiber termination. Because this module is self-contained, patch and splice, this option constitutes a cost-effective solution when adding a circuit to an existing fiber rack system or colocation type deployment. 

Taking a decision towards which one of these options are the best for your needs is certainly not easy, but that doesn’t mean that you won’t be able to make a proper decision. You just need to gather a good amount of solid information based on what your system really needs. 

 

It is mandatory then to have a good sense of the space available for potential adjustments. That being said, you then need to take a close look at the available options offered by trustworthy manufacturers. If you do a thorough research, rest assured that you will find the resources that will accommodate your needs. 

 

So don’t despair if you suspect that you’re not able to find a perfect solution to your problem because more often than not, that seems to be the case. Just make sure to focus on having a solid understanding on the demands, study proficiently the resources at your disposal and then get prepared to make the ultimate decision that will help you satisfy what you most urgently need for.

 

We really hope you can find all of this information very useful for your projects. 

How Many Choices Do You Still Have for Fiber Patch Cable?

by www.fiber-mart.com

Fiber patch cable, also known as fiber jumper, is a key component in today’s fiber optic network. They play the role of veins in the whole fiber optic network bringing fiber optic signals between devices.

 

How to Select Standard Fiber Patch Cable?

During the selection of standard fiber patch cables, several questions are usually take into consideration:

 

What’s the fiber type of the patch cable? The available selection are Multimode (OM1, OM2, OM3, OM4) and single-mode (OS1 and OS2).

 

What’s the connector type and connector polishing type on the two ends of fiber patch cable? Currently the most commonly used fiber patch cables are usually terminated with LC, SC and MPO connectors.

 

What’s the fiber count of the patch cable? Simplex (one fiber) and duplex (2 fibers) fiber patch cable are very common. For fiber patch cables terminated with MTP/MPO connector or breakout fiber patch cables. Their fiber count would be larger, sometime up to 24 fibers or more.

 

What’s the material of the fiber patch cable jacket? PVC, LSZH, Armored, and OFNP are the choice of most situations.

 

Not All Fiber Patch Cable Are Created Equal

Now with the fiber optic cable being widely used in a variety of industries and places, the requests for fiber patch are being refined. Fiber patch cable are being required to be improved and provide more possibilities to satisfy various application environments. Actually, many specially fiber patch cable have been created to answer the market call. Here will introduce several unique but useful fiber patch cable for your references.

 

Bend Insensitive Fiber Patch Cable for Lower Signal Loss

 

Bend loss issues are always a headache problem for most fiber optic network designers and installers. Why? Cause signal loss caused by bend loss issues are really hard to handle. In addition the bend loss issues are difficult to locate. That’s why bend insensitive fiber patch cables are created. Literally, it tells us that this type of fiber patch cable is not as sensitive as other fiber patch cables. The secrets is lays on the fibers which is made of bend insensitive glass. More and more data centers and FTTH systems are tend to use these bend insensitive fiber patch cables, because they do not provide lower signal loss, but also provide a much more durable and easy to maintain networking environment. Fiber optic installer is able to save installation cost with faster installation due to easier fiber optic cable handling.

 

bend insensitive fiber patch cable

Keyed LC Fiber Patch Cable for Data Security

 

Keyed LC fiber patch cable, is also called secured LC fiber patch cable. This is because, the fiber optic connectors on the two end of the patch cable are specially designed LC connectors, which can ensure the data security at the mechanic level. Keyed LC fiber patch cable is identifies by the connector color. Keyed LC fiber patch cable is just a part of the Keyed LC connectivity product family. It should be used with the same colored fiber adapters or fiber adapter panels. Each color of a set of keyed LC connectivity products represents a unique keying pattern that only allows matched color mating. This is how keyed LC fiber patch cable can provide data security for fiber optic network. A previous article (Secure Fiber Optic Link With Keyed LC Connectivity Products) of my has introduce keyed LC connectivity in details, kindly follow the link on the article title if you need more information about them.

 

keyed-lc-connector-and-adapter

Uniboot LC Fiber Patch Cable for Easier Cable Management

 

Uniboot LC fiber patch cable is a fiber patch cable with two fibers wrapped in the same strand of cable. A duplex LC fiber optic connector which can provide easy polarity reversal is terminated on each end of the uniboot LC fiber patch cable. The following picture show the polarity reversal of a typical uniboot LC fiber patch cable. With less cabling space are require, better cooling is available. With easier polarity reversal, no additional tools are required. And easier cable management can be enjoyed.

 

uniboot LC fiber patch cable

HD TAB Fiber Patch Cable for Space Saving

 

HD (high density) TAB fiber patch cable is a fiber patch cable with its connectors attached with a push pull tab, which can provide easier finger access and cable locating. Today’s fiber optic network is increasing depended on high density which results in difficult finger access and difficult cable management. With a push-pull tab attached on the connector, problem are solved easily. The connecting and disconnection of fiber patch cables will be easier without affecting other surrounding links. Currently most HD TAB fiber patch cables available the market are terminated with LC and MTP/MPO connectors. For more information about this type of patch cable kindly visit my article: Cabling With High Density Push-Pull Tab Patch Cords.

 

HD TAB fiber patch cable

HD Uniboot LC Fiber Patch Cable—Space Saving to the Extreme

 

HD uniboot LC fiber patch cable combine the advantages of uniboot LC fiber patch cable and HD TAB fiber patch cable. Combining two optical fibers in a single cable strand and attaching a push-pull tab on the connectors, HD uniboot LC fiber patch cable can minimize the required cabling spaces to extreme. It is an ideal solution for high density cabling environment.push-pull tab patch cords connectors

 

Except the standard fiber patch cable, there are still a lot of choices which can meet the requirements of various networking environment. All the above mentioned fiber patch cable are all available in fiber-mart.COM. Kindly visit fiber-mart.COM or contact sales@fiber-mart.com for more details.

Optic Fiber Termination and Splicing

by www.fiber-mart.com

Optical fibers are connected to terminal equipment by optical fiber connectors. These connectors are usually of a standard type such as FC, SC, ST, LC, or MTRJ.

Optical fibers may be connected to each other by connectors or by splicing, that is, joining two fibers together to form a continuous optical waveguide. The generally accepted splicing method is arc fusion splicing, which melts the fiber ends together with an electric arc. For quicker fastening jobs, a "mechanical splice" is used.

Fusion splicing is done with a specialized instrument that typically operates as follows: The two cable ends are fastened inside a splice enclosure that will protect the splices, and the fiber ends are stripped of their protective polymer coating (as well as the more sturdy outer jacket, if present). The ends are cleaved (cut) with a precision cleaver to make them perpendicular, and are placed into special holders in the splicer. The splice is usually inspected via a magnified viewing screen to check the cleaves before and after the splice. The splicer uses small motors to align the end faces together, and emits a small spark between electrodes at the gap to burn off dust and moisture. Then the splicer generates a larger spark that raises the temperature above the melting point of the glass, fusing the ends together permanently. The location and energy of the spark is carefully controlled so that the molten core and cladding don't mix, and this minimizes optical loss. A splice loss estimate is measured by the splicer, by directing light through the cladding on one side and measuring the light leaking from the cladding on the other side. A splice loss under 0.1 dB is typical. The complexity of this process makes fiber splicing much more difficult than splicing copper wire.

Mechanical fiber splices are designed to be quicker and easier to install, but there is still the need for stripping, careful cleaning and precision cleaving. The fiber ends are aligned and held together by a precision-made sleeve, often using a clear index-matching gel that enhances the transmission of light across the joint. Such joints typically have higher optical loss and are less robust than fusion splices, especially if the gel is used. All splicing techniques involve the use of an enclosure into which the splice is placed for protection afterward.

Fibers are terminated in connectors so that the fiber end is held at the end face precisely and securely. A fiber-optic connector is basically a rigid cylindrical barrel surrounded by a sleeve that holds the barrel in its mating socket. The mating mechanism can be "push and click", "turn and latch" ("bayonet"), or screw-in (threaded). A typical connector is installed by preparing the fiber end and inserting it into the rear of the connector body. Quick-set adhesive is usually used so the fiber is held securely, and a strain relief is secured to the rear. Once the adhesive has set, the fiber's end is polished to a mirror finish. Various polish profiles are used, depending on the type of fiber and the application. For singlemode fiber, the fiber ends are typically polished with a slight curvature, such that when the connectors are mated the fibers touch only at their cores. This is known as a "physical contact" (PC) polish. The curved surface may be polished at an angle, to make an "angled physical contact" (APC) connection. Such connections have higher loss than PC connections, but greatly reduced back reflection, because light that reflects from the angled surface leaks out of the fiber core; the resulting loss in signal strength is known as gap loss. APC fiber ends have low back reflection even when disconnected.