Author: Fiber-MART.COM

eShop of Fiber Optic Network, Fiber Cables & Tools

Introduction to Passive Optical Network (PON)

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

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).

What is PON 2.jpg.png

 

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 www.fiber-mart.com or contact us.E-mail: service@fiber-mart.com

Fiber Patch Cords vs Fiber Pigtails

by http://www.fiber-mart.com

Fiber optic patch cord and fiber optic pigtail are two commonly used components in fiber optic network. They have many things in common and they also differ in distinct ways. Knowing both the similarities and the differences between them will help you make the best selection for your project. The passage mainly talks about their similarities and differences in both structures and applications.
Structures of Fiber Patch Cords and Pigtails
Fiber patch cord, also known as fiber optic patch cable or fiber jumper cable, is a short length of optical fiber cable with a connector on each end. Connector types on each side of the fiber patch cable can be different and they can also be the same. Fiber optic pigtail is a piece of cable terminated with a fiber optic connector at only one end of the cable and leaves a length of exposed fiber at the other end, so that the connector side can link to the equipment and the other side can be melted with optical cable fibers or stripped and fusion spliced to a single fiber of a multi-fiber trunk. The following picture shows a fiber patch cord and a fiber pigtail.
Fiber optic patch cords and pigtails structurally have much in common. They are both available in single mode and multi-mode, and they can be made into simplex and duplex. Besides, both fiber patch cord and pigtail can terminate with many kinds of fiber optic connectors, including FC, SC, ST, LC, MTRJ, MPO, MU, SMA, FDDI, E2000, DIN4, and D4.
The major physical difference between fiber patch cord and pigtail is that fiber patch cord is a fixed length piece of cable with fiber connectors on each end while fiber pigtail has fiber connectors on only one end of the cable. Fiber optic patch cords can be cut into shorter lengths to make two pigtails.
Applications of Fiber Patch Cords and Pigtails
Fiber optic patch cords and pigtails provide interconnect and cross-connect of applications over installations in entrance facilities, telecommunications rooms, and data centers. They are available in OM4, OM3, OM2, OM1, or OS1/OS2 fiber types to meet the demands of Gigabit Ethernet, 10 Gigabit Ethernet and high speed Fibre Channel. However, they have their respective application areas, too.
Fiber patch cords are commonly used to connect ports on fiber distribution frames. They support network applications in main, horizontal and equipment distribution areas and are available in optical fiber riser cable (OFNR), and low smoke zero halogen (LSZH) rated jacket materials to comply with local cabling ordinances. They also support high speed (10/40 Gbs) telecommunications. Fiber optic patch cords can be used in many areas, such as integrated optics, laser detection and display, and materials processing.
Fiber optic pigtails support fusion splice field termination applications. They should be installed where they will be protected and spliced, so they are usually used with fiber optic management equipment like optical distribution frame (ODF), splice closures and cross cabinets. Pigtails are found anywhere, but most commonly in optical assemblages or optical components. There are waterproof fiber optic pigtails used for outdoor applications, which is with thick poly ethylene (PE) jacket and big diameter.
fiber-mart.com produces high quality fiber optic patch cords and pigtails using a variety of commercially available connectors and fibers. We provide various single mode and multi-mode fiber patch cords and fiber pigtails. These patch cords and pigtails offer low insertion losses, and excellent repeatability. And they can be manufactured to custom length.

News for Tuesday 10 July, 2018

View all news for Tuesday 10 July, 2018 on one page

Recent News

News Archive – See All News from Fiber-Mart.COM
Newsletter

Enter your email for new arrivals, brands and special offers!

Tags: UPC 9/125 Duplex | UPC Female Connector | UPC TO UPC | UPC Optic Connector | UPC Plastic Adapter | UPC Simplex 2.0mm Connector | UTP Cables | UPC Simplex | UPC Low Reflection Connector | Variable AttenuatorUnderground Cable Locator | UPC Duplex Cable | UPC 62.5/125 Optic Connector | Ultrasonic Cleaner | Unmanaged PoE Switch | UPC Multimode Connector | Unidirectional Transmitter | UPC swing shutter | UPC ConnectorUPC Dupex Cable |
Product Tags: A | B | C | D | E | F | G | H | I | J | K | L | M | N | O | P | Q | R | S | T | U | V | W | X | Y | Z | 0-9

MTP Fiber Patch Cables Overview

by http://www.fiber-mart.com

MTP stands for multi-fiber termination push-on connector and is designed by US Conec and built around the MT ferrule. MTP fiber patch cable takes its name from the MTP connector, which allows high-density connections between network equipment in telecommunication rooms. The following text will thoroughly cover types, advantages and applications of MTP fiber patch cords, and solution provided by fiber-mart.com.
Types of MTP Fiber Patch Cords
There are different types of MTP fiber patch cords based on various criteria. According to the core of the fiber, MTP fiber patch cords are categorized into MTP single mode fiber patch cords and MTP multi-mode fiber patch cords. According to the connectors on both ends, there are mainly two configurations for MTP fiber patch cables. One is the MTP connector to MTP connector, which is often called MTP trunk cable. The other is MTP connector to standard LC/FC/SC/ST/MTRJ connectors (generally MTP to LC), which is often called the MTP harness cable, or MTP fan-out cable. The picture shows a MTP trunk cable and a MTP harness cable.
Advantages of MTP Fiber Patch Cords
The MTP fiber system is a truly innovative group of products which moves fiber optic networks into the new millennium. MTP connector, as a kind of multi-fiber connector, is most commonly used for 12 or 24 fibers. It has about the same size of a SC connector and provides up to 12 or 24 times the density, thereby offering savings in circuit card and rack space. Using MTP trunk cables, a complete fiber optic backbone can be installed without any field termination being required. Moreover, MTP connector is designed as a high-performance version of the multi-fiber push on (MPO) and will interconnect with MPO connectors, so it is compatible with VZ TPR.9431, IEC-61754-7 and EIA/TIA-604-5. It uses a simple push-pull latching mechanism for easy and intuitive insertion and removal.
MTP jumpers utilizes precision ferrules, precise housing dimension and metal guide pins to ensure fiber positioning when mating and give excellent performance. And the easy installation of them saves time and money. They can optimize network performance and maximize lifespan. MTP multi-fiber jumpers deliver the performance and reliability needed in today’s demanding high-speed broadband and data networks. They are designed to cater for up-scaling needs and future technologies growth.
Applications of MTP Fiber Patch Cords
The MTP fiber patch cord is the choice for a wide variety of applications. MTP fiber patch cords can be used for backbones, disaster recovery, building fiber optic distribution, quick setup of new wiring hubs, warehouses, direct termination of ribbon cables, repair of plug and play universal system solutions, and parallel optical interconnects between servers.
Besides these general applications above, MTP trunk cable and MTP harness cable, two commonly used MTP fiber patch cords, have their respective special uses. MTP trunk cables are available in 12-144 count. These high count MTP assemblies are ideal for backbone and data center applications that require a high fiber count in a limited space. MTP fan-out assemblies provide connection to equipment or panels that are terminated with ST, SC, FDDI, or ESCON connectors and meet a variety of fiber cabling requirements. Such assemblies are pre-wired available for patch panels and wall enclosures.
fiber-mart.com MTP Fiber Patch Cables Solution
fiber-mart.com offers single mode and multi-mode MTP assemblies, such as MTP-LC, MTP-ST, MTP-FC, MTP-MU, MTP-MT-RJ, MTP-E2000, simplex and duplex. Also we provide UPC MTP assemblies and APC MTP cables. All fiber counts are available in plenum, riser, or outdoor ratings to suit different kinds of environment. Our high quality factory pre-termination eliminates the need for costly field termination and testing.

Introduction to Mode Conditioning Patch Cable

by http://www.fiber-mart.com

What Is Mode Conditioning Patch Cable?
A mode conditioning patch cord is a duplex multi-mode patch cord that has a small length of single mode fiber at the start of the transmission leg, and also a single mode to multi-mode offset fiber connection part in this leg. There are two multi-mode fibers on one end and one multi-mode and one single mode fiber on the other end. It is fully compliant with IEEE 802.3z application standards. Mode conditioning patch cord causes the single mode transceiver to create a launch similar to a typical multi-mode launch. It is designed for long wavelength Gigabit Ethernet applications. The following picture shows the construction of a mode conditioning patch cable.
Mode conditioning patch cord (MCP) was developed as a solution for network applications where Gigabit Ethernet hubs with laser based transmitters are deployed. It is a special fiber optic patch cord and allows customer upgrading their hardware technology without the cost of upgrading fiber plant. In addition, MCP significantly improves data signal quality while increasing the transmission distance. The text will give some detailed information about mode conditioning patch cable.
How Does Mode Conditioning Patch Cable Work?
The basic principle behind the cord is that you launch your laser into the small section of single mode fiber. The launch of the light coming out of the equipment begins on a single mode fiber. The other end of the single mode fiber is coupled to multi-mode section of the cable with the core offset from the center of the multi-mode fiber. The light is launched on to the multi-mode fiber at a precise angle, giving the cable its mode conditioning properties. When we use such mode conditioning fiber optic patch cords, we need to connect the yellow leg which is the color of single mode to connect the transmit side of the equipment (single mode Gigabit transceiver) while we connect the orange leg which is the color of multi-mode to the receive side. The picture below shows how the single mode fiber is coupled to multi-mode section of the cable.
How to Install Mode Conditioning Patch Cable?
To install a mode conditioning patch cable, you need to follow these steps:
Step1: Connect the yellow leg (single mode connector) of the MCP cable into the transmit bore of the transceiver.
Step2: Connect the rest orange legs (multi-mode connectors) of the MCP cable into the receive bore of the transceiver.
Step3: At the other end of the patch cord, put all the orange legs (multi-mode connectors) into the patch panel.
Step4: Repeat the above three steps for the second transceiver located at the other end of the network link.
After you have finished all the connection steps above, all the swap of transmit and receiver can only be done at the cable plant side.
Why Do We Need Mode Conditioning Patch Cable?
Transceiver modules used in Gigabit Ethernet (1000 Base-LX) launch only single mode (1300nm) long wave signals, which poses a problem if an existing fiber network utilizes multi-mode cable. When a single mode signal is launched into a multi-mode fiber a phenomenon known as differential mode delay (DMD) can create multiple signals within the multi-mode fiber. This effect can confuse the receiver and produce errors. By allowing the single mode laser launch to be offset away from the center of the multi-mode fiber, mode conditioning patch cord reduces the effect of such differential mode delay and provides a much higher operational bandwidth by precisely aligning a single mode termination at the laser transmitter. This is essential for networks using 62.5/125 and 50/125 multi-mode optical fiber and may be specified for current multi-mode networks depending upon the system requirements.
Mode conditioning patch cables are with various options, from all types of connectors to different jackets and different lengths. A variety of fiber optic connectors are available for your convenience, including: LC/UPC, SC/UPC, FC/UPC, ST/UPC, LC/APC, SC/APC, FC/APC, and MTRJ. Mode conditioning patch cables are built in the form of a simple duplex patch cable, so they can easily be installed in a system without the need for additional components or hardware. Their length can range from one meter and up to support virtually any network topography.

40G QSFP+ Direct Attach Copper Cabling

by http://www.fiber-mart.com

In today’s network building, requiring higher speeds, greater scalability and cost-effective cabling solution is preferable. Direct Attach Cable(DAC) is a kind of optical transceiver assembly widely applied in storage area network, data center, and high-performance computing connectivity etc and high density cabling interconnect system capable of delivering an aggregate data bandwidth of 40Gb/s,therefore, It is the cost-effective way to upgrade from 10G to 40G or 40G to 40G interconnect connection.

 

40G QSFP+ Direct Attach Copper Cable (DAC) Basics

 

40G QSFP+ Direct Attach Copper Cable (DAC) is a high speed twinax cable with QSFP+ connector on either end of the cable. It is designed to meet emerging data center and high performance computing application needs for a short distance and high density cabling interconnect system capable of delivering an aggregate data bandwidth of 40Gb/s. The maximum transmission distance of QSFP+ direct attach copper cable is 10 meters, which makes the cable suitable for in-rack connections between servers and Top-of-Rack (ToR) switches because they often require shorter distances and not routed to the Main Distribution Frames.

 

 

How to Use 40G QSFP+ Direct Attach Copper Cable

 

According to the connector types on both ends. One is QSFP+ to 4 SFP+ direct attach breakout copper cable, and the other is QSFP+ to QSFP+ direct attach copper cable. In fact, it is not common for there is a third type QSFP+ direct attach copper cable called QSFP+ to 4 XFP breakout cable. For a QSFP+ to 4 SFP+ direct attach breakout copper cable, it has a QSFP+ connector on one end and four SFP+ connectors on the other end. In terms of a QSFP+ to QSFP+ direct attach copper cable, it has a QSFP+ connector on both ends of the cable. When we use a fiber optic transceiver and patch cable to establish a fiber link, we should firstly plug the transceiver to the switch and then plug the patch cable to the transceiver. But for a QSFP+ direct attach copper cable, either SFP+ connector or QSFP+ connector, before building the network, it is necessary to buy 40G DAC cables from reliable QSFP cables supplier and manufacturer.can be both directly inserted into the switch and don’t need a transceiver at all, which provides a really cost-effective solution for interconnecting high speed 40G switches to existing 10G equipment or 40G switches to 40G switches.

 

40G QSFP+ to 4 SFP+ Direct Attach Copper Cabling

 

The move from 10G to 40G Ethernet will be a gradual one. It is very likely that one may deploy switches that have 40G Ethernet ports while the servers still have 10G Ethernet ports. For that situation, we should use a QSFP+ to 4 SFP+ direct attach breakout copper cable.In 40G to 40G connection, QSFP+ to QSFP+ direct attach copper cables are suitable for very short distances and offer a highly cost-effective way to establish a 40G link between QSFP+ ports of QSFP+ switches within racks and across adjacent racks. These QSFP+ copper cables connect to a 40G QSFP port of a switch on one end and to another 40G QSFP port of a switch on the other end. It is noted that the distance between the two switches is within the cable length.  These cables connect to a 40G QSFP Port of a switch on one end and to four 10G SFP+ ports of a switch on the other end, which allows a 40G Ethernet port to be used as four independent 10G ports thus providing increased density while permitting backward compatibility and a phased upgrade of equipment. As a lower cost alternative to MTP/MPO breakouts for short reach applications up to 5 meters, it helps IT organizations achieve new levels of infrastructure consolidation while expanding application and service capabilities.

 

40G QSFP+ to QSFP+ Direct Attach Copper Cabling

 

QSFP+ to QSFP+ direct attach copper cable are suitable for very short distances and offer a highly cost-effective way to establish a 40G link between QSFP+ ports of QSFP+ switches within racks and across adjacent racks. These cables connect to a 40G QSFP port of a switch on one end and to another 40G QSFP port of a switch on the other end. Supporting similar applications to SFP+, these four-lane high speed interconnects were designed for high density applications at 10Gb/s transmission speeds per lane. One QSFP+ to QSFP+ direct attach copper cable link is equivalent to 4 SFP+ cable links, providing greater density and reduced system cost. Passive and active QSFP+ to QSFP+ direct attach copper cables are both available. With a active QSFP+ to QSFP+ direct attach copper cable assembly, the connection is capable of distances of up to 10 meters.

 

 

Why Use 40G QSFP+ Direct Attach Copper Cable (DAC)?

 

For 40G short reach applications, 40G QSFP+ direct attach copper cable provides simple and inexpensive cabling solution.

The main advantages in following.

  •  Robust
  •  Cheap
  •  Low-power Consumption
  •  Easy Operation

 

 

Conclusion

 

With the wide deployment of 40 Gigabit Ethernet, the 40G QSFP+ direct attach copper cables are becoming more and more popular due to the compact size, low power and cost-effectiveness.  Fiber-Mart supplies various kinds of high speed interconnect DAC cable assemblies including 10G SFP+ Cables, 40G QSFP+ Cables, and 120G CXP Cables. All of our direct attach cables can meet the ever growing need to cost-effectively deliver more bandwidth, and can be customized to meet different requirements. For more information, welcome to visit http://www.fiber-mart.com.or contact us .E-mail: service@fiber-mart.com

 

Introduction of Fiber Optic Attenuators

by http://www.fiber-mart.com

What is Fiber Attenuator?
Fiber optic attenuator is a passive device used to reduce the power level of an optical signal because too much light can overload a fiber optic receiver and degrade the bit error ratio (BER). To achieve the best BER, the light power must be reduced by using fiber optic attenuator. Generally, the optical attenuators are used in single-mode long-haul applications to prevent optical overload at the receiver.
Optical attenuator reduces signal power by absorbing the light, like sunglasses absorb the extra light energy. Or by scattering the light like an air gap. Fiber optic attenuators are commonly used in two scenarios:
1.Attenuators are permanently installed in a fiber optic links to properly match signal levels at transmitter and receiver.
2.In fiber optic power level testing. Attenuators are used to temporarily add a calibrated amount of signal loss in order to test the power level margins in a fiber optic system.
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.
What is Fixed Fiber Attenuator?
Fixed fiber optic attenuator, also called fixed plug type or fixed build-out fiber attenuator, is used in fiber optic communications to reduce the optical fiber power by a certain level. Typical attenuation values are between 1 and 30 dB. Usually, it has a male plug connector at one side to allow fiber attenuator to be plugged directly into receiver equipment or adapters in patch panel, and has female type fiber optic adapter at the other side to allow the patch cords to plug in. Fixed fiber optic attenuator name is based on the connector type and the attenuation level. LC attenuator 5dB means this attenuator uses LC fiber optic connector, and it can reduce the optical fiber power level by 5dB.
What is optical variable attenuator?
Optical variable attenuator can also be made as a plug-in card. It is a part of Fiber-Mart, all-in-one multi-service transport system. This hot-swappable plug-in variable optical attenuator is an online attenuation adjustment device, only occupying one slot in the 1U/2U/4U chassis. It is applied to applications that optical power required strict control, such as to balance signal strengths in a DWDM network system. Card optical variable attenuator adopts MEMS technology and could continually and variably reduce the light intensity in the optical network and help simulate distance or actual attenuation in the fiber optic testing work. With the card design, this optical variable attenuator is easy to install and remove without any tool. The online attenuation adjustment also contributes to safer business.
How to use Fiber Optic Attenuators in data link?
For a single-mode applications, especially analog CATV systems, the most important parameter, after the correct loss value, is return loss or reflectance. Many types of attenuators (especially gap loss types) suffer from high reflectance, so they can adversely affect transmitters just like highly reflective connectors.
Choose an attenuator with good reflectance specifications, and always install the attenuator ( X in the drawing) at the receiver end of the link as shown above. This is because it’s more convenient to test the receiver power before and after attenuation or while adjusting it with your power meter at the receiver, plus any reflectance will be attenuated on its path back to the source.
Test the system power with the transmitter turned on and the optical attenuator installed at the receiver, and using an optical power meter set to the system operating wavelength. Check to see whether the power is within the specified range for the receiver.
Conclusion
Fiber optic attenuator is an essential passive component in the optical communication system. 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. The innovation in fiber optic industry never ceases, and fiber optic attenuator will evolve to have lower cost, faster response time and enhanced integration of hybrid with other optical communication devices.Fiber-Mart provides a wide range of fiber optical attenuator.Welcome to contact with us:product@fiber-mart.com.