Monthly Archives: April 2015

What’s the Difference: Single Mode vs Multimode Fiber

An optical fiber is a flexible, transparent fiber made of extruded glass or plastic, slightly thicker than a human hair. Optical fibers are used most often as a means to transmit light between the two ends of the fiber and find wide usage in fiber-optic communications, where they permit transmission over longer distances and at higher bandwidths than wire cables. Optical fibers typically include a transparent core surrounded by a transparent cladding material with a lower index of refraction. Light is kept in the core by the phenomenon of total internal reflection which causes the fiber to act as a waveguide. In general, there are two kinds of optical fiber: fibers that support many propagation paths or transverse modes are called multimode fibers (MMF), while those that support a single mode are called single mode fibers (SMF). Single mode vs multimode fiber: what’s difference between them? Reading this text will help you get the answer.

Single Mode vs Multimode Fiber: What’s single mode optical fiber?

In fiber-optic communication, a single mode optical fiber (SMF) is an optical fiber designed to carry light only directly down the fibre – the transverse mode. For single mode optical fiber, no matter it operates at 100 Mbit/s or 1 Gbit/s date rates , the transmission distance can reach to at least 5 km. Typically, it is used for long-distance signal transmission.

Single Mode vs Multimode Fiber: What’s multimode optical fiber?

Multimode optical fiber (MMF) is a type of optical fiber mostly used for communication over short distances, such as within a building or on a campus. Typical transmission speed and distance limits are 100 Mbit/s for distances up to 2 km (100BASE-FX), 1 Gbit/s up to 1000m, and 10 Gbit/s up to 550 m. There are two kinds of multimode indexes: step index and graded index.

What’s difference between single mode optical fiber and multimode?

Core diameter

The main difference between multimode and single mode fiber is that the former has much larger core diameter, typically has a core diameter of 50 or 62.5 µm and a cladding diameter of 125 µm. While a typical single mode fiber has a core diameter between 8 and 10 µm and a cladding diameter of 125 µm.

Optical source
Both lasers and LEDs are used as light sources. Laser light sources are significantly more expensive than LED light sources however they produce a light that can be precisely controlled and which has a high power. Because the LED light sources produce a more dispersed light source (many modes of light) these light sources are used with multimode
cable. While a laser source is used (which produces close to a single mode of light) with single mode cable.

Bandwidth
Since multimode fiber has a larger core-size than single mode fiber, it supports more than one propagation mode. Besides, like multimode fibers, single-mode fibers do exhibit modal dispersion resulting from multiple spatial modes, but the modal dispersion of single mode fiber is less than multi-mode fiber. For these reasons, single mode fibers can have a higher bandwidth than multi-mode fibers.

Jacket color
Jacket color is sometimes used to distinguish multimode cables from single mode ones. The standard TIA-598C recommends, for non-military applications, the use of a yellow jacket for single mode fiber, and orange or aqua for multimode fiber, depending on type. Some vendors use violet to distinguish higher performance OM4 communications fiber from other types.

Modal dispersion
The LED light sources sometimes used with multimode fiber produce a range of wavelengths and these each propagate at different speeds. This will lead to much modal dispersion, which is a limit to the useful length for multimode fiber optic cable. In contrast, the lasers used to drive single mode fibers produce coherent light of a single wavelength. Hence its modal dispersion is much less than multimode fiber. Due to the modal dispersion, multimode fiber has higher pulse spreading rates than single mode fiber, limiting multimode fiber’s information transmission capacity.

Price
For multimode fiber can support multiple light mode, the price of it is higher than single-mode fiber. But in terms of the equipment, because single mode fiber normally uses solid-state laser diodes, therefore, the equipment for single mode fiber is more expensive than equipment for multimode fiber. And for this reason , the cost of using multimode fiber is much less than using single-mode fiber instead.

Single Mode vs Multimode Fiber: What kind of optical fiber should I choose?

This is based on transmission distance to be covered as well as the overall budget allowed. If the distance is less than a couple of miles, multimode fiber will work well and transmission system costs (transmitter and receiver) will be in the $500 to $800 range. If the distance to be covered is more than 3-5 miles, single mode fiber is the choice. Transmission systems designed for use with this fiber will typically cost more than $1000 due to the increased cost of the laser diode. Single mode vs multimode fiber: Do you know the differences now?

Comparison Between OS1 and OS2 SMF Cables

Fiberstore Supply Compatible Cisco 10G SFP+ Direct Attach Cables

What are Compatible Network Products?

Compatible products can include transceivers, direct-attach cables (DAC), active optical cables (AOC), and media converters, among others. Compatibles are designed to work with all manufacturers’ equipment and can be used in virtually any industry, from telecommunications and education to healtchcare and financial services.

Compatible Cisco 10G SFP+ Direct Attach Cables on Fiberstore

The compatible Cisco 10GBASE SFP modules also enable to give you 10 Gigabit Ethernet connectivity for your data center, enterprise wiring closet or service provider transport applications. 10GBASE-CU SFP+ cables, also known as SFP+ copper Twinax direct attach cables, are suitable for very short distances and offer a cost-effective way to connect within racks and across adjacent racks. Fiberstore offers passive Twinax cables in lengths of 1,1.5, 2, 2.5, 3 and 5 meters, and active Twinax cables in lengths of 7 and 10 meters. For more details about relevant products, we can see the table below:

Compatible Cisco Direct Attach Twinax Copper Cable Assemblies with SFP+ Connectors

Products	Cable Type	Cable Distance
Cisco SFP-H10GB-CU1M	Twinax cable, passive, 30AWG cable assembly	1m
Cisco SFP-H10GB-CU1-5M	Twinax cable, passive, 30AWG cable assembly	1.5m
Cisco SFP-H10GB-CU2M	Twinax cable, passive, 30AWG cable assembly	2m
Cisco SFP-H10GB-CU2-5M	Twinax cable, passive, 30AWG cable assembly	2.5m
Cisco SFP-H10GB-CU3M	Twinax cable, passive, 30AWG cable assembly	3m
Cisco SFP-H10GB-CU5M	Twinax cable, passive, 24AWG cable assembly	5m
Cisco SFP-H10GB-ACU7M	Twinax cable, active, 30 AWG cable assembly	7m
Cisco SFP-H10GB-ACU10M	Twinax cable, active, 28AWG cable assembly	10m

Advantages of Compatible Cisco 10G SFP+ Direct Attach Cables

Cable Compatible With Cisco SFP-H10GB-CU1M Compatible Cisco 10G SFP+ direct attach cables are cables that offer the same function with Cisco 10G SFP+ cable (SFP-H10GB-CU/ACU) and they are fully compatible with Cisco devices. They provide a low power and low latency interconnect solution for 10-Gigabit Ethernet, Fiber Channel and other industry standards, and are direct attached compliant and fully conform to the SFP+ MSA specifications. Above all, with this compatible cables, the cost savings are undeniable, which is supposed to achieve potential savings of 50–70% over comparable products from original equipment manufacturers (OEM).

Three Types Physical Media Systems For 10 Gigabit Ethernet

Overview

Dramatic growth in data center throughput has led to the increasing usage and demand for higher-performance servers, storage and interconnects. As a result, we are seeing the expansion of higher speed Ethernet solutions, specifically 10 and 40 gigabit Ethernet. This text will take an overview of 10 gigabit ethernet as well as introducing some common 10-gigabit physical media systems: fiber optic media systems, DAC cable media systems and twisted-pair media systems.

Introduction of 10 Gigabit Ethernet

10 Gigabit Ethernet is a group of computer networking technologies for transmitting Ethernet frames at a rate of 10 gigabits per second. It was first defined by the IEEE 802.3ae-2002 standard. Unlike previous Ethernet standards, 10 Gigabit Ethernet defines only full duplex point-to-point links which are generally connected by network switches. Like previous versions of Ethernet, 10GbE can use either copper or fiber cabling. However, the 10 Gigabit Ethernet standard encompasses a number of different physical layer (PHY) standards. A networking device may have different PHY types through pluggable PHY modules, such as those based on XENPAK, XFP and SFP+.

Classification of 10 Gigabit Ethernet

When comes to 10 gigabit Ethernet (10GbE), IT managers are now faced with the challenge of selecting the appropriate 10-gigabit physical media. Broadly, this media is usually offered in the following three categories:

10 Gigabit Ethernet Fiber Optic Media Systems Solution

There are two classifications for optical fiber: single-mode (SMF) and multimode (MMF). SMF is used for long distance communication and MMF is used for distances of less than 300 m. There are also active optical cables (AOC). These have the optical electronics already connected eliminating the connectors between the cable and the optical module. They plug into standard optical module sockets. They are lower cost than other optical solutions because the manufacturer can match the electronics to the required length and type of cable. AOC Cable provides very short distance (same shelf) inexpensive connectivity at 10G rates between two 10G data ports. The following picture shows the SFP+ active optical cables (AOC):

NOTE: Dramatically reducing 10G interconnectivity costs, the 10G cables can provide inexpensive and reliable 10G speed connections using either copper cables with distances reaching up to 15 meters or active optical cables reaching even 100 meters.

10 Gigabit Ethernet Copper Direct Attach Cable Media Systems (10GSFP+Cu) Solution

SFP+ direct attach cable (DAC), also known as 10GSFP+Cu, is a copper 10GBASE Twinax Cable which comes in either an active or passive twinax cable assembly and connects directly into an SFP+ housing. SFP+ direct attach cable has a fixed-length cable, typically 1 to 7 m (passive cables) or up to 15 m (active cables) in length. And like 10GBASE-CX4, is low-power, low-cost and low-latency with the added advantages of using less bulky cables and of having the small form factor of SFP+. Besides, SFP+ direct attached Twinax copper today is tremendously popular, with more ports installed than 10GBASE-SR. The following picture shows the SFP+ passive direct attach cable(DAC):

10 Gigabit Ethernet Twisted-Pair Media Systems (10GBASE-T) Solution

10GBASE-T is a standard released in 2006 to provide 10 Gbit/s connections over unshielded or shielded twisted pair cables, over distances up to 100 metres. 10GBASE-T cable solution can also be used for 1000BASE-T allowing a gradual upgrade from 1000BASE-T using auto negotiation to select which speed to use. 10GBASE-T uses the IEC 60603-7 8P8C (commonly known as RJ45) connectors already widely used with Ethernet. Transmission characteristics are now specified to 500 MHz. To reach this frequency Category 6A or better balanced twisted pair cables are needed to carry 10GBASE-T up to distances of 100m. The following picture shows the Category 6A cable:

Cisco SFP Transceiver Modules for Opitcal Network

Cisco Systems, Inc. is an American multinational corporation headquartered in San Jose, California, that designs, manufactures, and sells networking equipment. With the rapid development of optical communication, Cisco’s products of optical networking are being used more and more widely all around the world. Among them, the SFP transceiver module is a critical component. In this article, Cisco SFP will be introduced.

Cisco Products Refer To Optical Communication

In fact, Cisco produces many optical networking equipment, such as optical services modules, optical transponders, optical transceiver modules and a comprehensive portfolio of WDM transmission modules, which includes optical terminal filters, optical amplifiers, optical service channel, and others, to support the network applications of enterprise and service provider customers.

Cisco SFP Transceiver Modules

Cisco SFP transceiver modules support Ethernet, Sonet/SDH and Fibre Channel applications across all Cisco switching and routing platforms. The Cisco portfolio of hot pluggable interfaces offers a rich set of choices in terms of speeds, protocols, reaches and supported transmission media. Generally, these SFP transceiver modules are divided into three types as following three sorts:

Cisco Fast Ethernet SFP Modules:

Cisco 100M Ethernet SFP	Part Number	Description
Cisco 100BASE-FX SFP	GLC-FE-100FX	Operates on ordinary multimode fiber-optic (MMF) link spans up to 2 kilometers long. For 100Mbps Ethernet ports.
Cisco 100BASE-FX SFP	GLC-GE-100FX	Operates on ordinary multimode fiber-optic (MMF) link spans up to 2 kilometers long. For Gigabit Ethernet ports.
Cisco 100BASE-LX10 SFP	GLC-FE-100LX	Operates on ordinary single-mode fiber-optic (SMF) link spans up to 10 kilometers long.
Cisco 100BASE-ZX SFP	GLC-FE-100LX-RGD	Operates on ordinary single-mode fiber-optic (SMF) link spans up to 10 kilometers long.
Cisco 100BASE-BX10 SFP	GLC-FE-100BX-D GLC-FE-100BX-U	Operates on ordinary SMF single-strand link spans up to 10 kilometers long.
Cisco 100BASE-EX SFP	GLC-FE-100EX	Operates on ordinary single-mode fiber-optic (SMF) link spans up to 40 kilometers long.
Cisco 100BASE-ZX SFP	GLC-FE-100ZX	Operates on ordinary single-mode fiber-optic (SMF) link spans up to 80 kilometers long.

Cisco Gigabit Ethernet SFP Modules

Gigabit Ethernet SFP	Part Number	Description
Cisco 1000BASE-SX SFP	GLC-SX- MM	Operates on 50m multimode fiber links up to 550m and on 62.5 m FDDI-grade multimode fibers up to 220m.
Cisco 1000BASE-LX/LH SFP	GLC-LH-SM	Operates on standard single-mode fiber-optic link spans of up to 10 km and up to 550 m on any multimode fibers.
Cisco 1000BASE-ZX SFP	GLC-ZX-SM	Operates on standard single-mode fiber-optic link spans of up to approximately 70 km in length.
Cisco 1000BASE-BX10-D & 1000BASE-BX10-U SFP	GLC-BX-D GLC-BX-U	Operates on a single strand of standard single-mode fiber. A 1000BASE-BX10-D device is always connected to a 1000BASE-BX10-U device with a single strand of standard single-mode fiber with an operating transmission range up to 10 km.
Cisco 1000BASE-T SFP	GLC-T SFP-GE-T	1000BASE-T SFP Transceiver Module for Category 5 copper wire.

Cisco CWDM Transceiver Modules

Part Number	Description	Color Code
CWDM-SFP-1470	Cisco CWDM 1470-nm SFP; Gigabit Ethernet and 1 and 2 Gb Fibre Channel	Gray
CWDM-SFP-1490	Cisco CWDM 1490-nm SFP; Gigabit Ethernet and 1 and 2 Gb Fibre Channel	Violet
CWDM-SFP-1510	Cisco CWDM 1510-nm SFP; Gigabit Ethernet and 1 and 2 Gb Fibre Channel	Blue
CWDM-SFP-1530	Cisco CWDM 1530-nm SFP; Gigabit Ethernet and 1 and 2 Gb Fibre Channel	Green
CWDM-SFP-1550	Cisco CWDM 1550-nm SFP; Gigabit Ethernet and 1 and 2 Gb Fibre Channel	Yellow
CWDM-SFP-1570	Cisco CWDM 1570-nm SFP; Gigabit Ethernet and 1 and 2 Gb Fibre Channel	Orange
CWDM-SFP-1590	Cisco CWDM 1590-nm SFP; Gigabit Ethernet and 1 and 2 Gb Fibre Channel	Red
CWDM-SFP-1610	Cisco CWDM 1610-nm SFP; Gigabit Ethernet and 1 and 2 Gb Fibre Channel	Brown

This picture shows the Third Party 1000BASE-T SFP Transceiver from Fiberstore

The Fiberstore industry-standard 1000BASE-T Small Form-factor Pluggable (GLC-T SFP) gigabit interface converter (GBIC) is a hot-swappable input/output device that plugs into a Gigabit Ethernet port or slot, linking the port with the network. The SFP modules from Fiberstore provide full-duplex Gigabit Ethernet connectivity to high-end workstations and between wiring closets over existing copper network infrastructure.

Main Featurs

Hot-swappable when deployed, the switch or router does not have to reboot
Interchangeable with other 1000BASE-X SFPs on the same linecard
Supports Cisco quality ID feature that enables the switch or router to identify whether the SFP is a Cisco SFP

Technical Specifications

Platform Support
The Cisco 1000BASE-T SFP is supported across a variety Cisco switches, routers, and optical transport devices.
Connectors and Cabling
RJ-45 connector
Cable: Category 5 unshielded twisted pair (UTP)
Cabling distance (maximum): 328 ft (100 m)
Dimensions
Maximum Dimensions (H x W x D): 0.55 x 0.54 x 2.8 in. (14.0 x 13.7 x 71.1 mm)

Environmental Conditions and Power Requirements

Operating temperature range: 0 to 70° C (32 to 158° F)
Storage temperature range: -40 to 85° C (-40 to 185° F)
Predicted mean time between failure (MTBF): 1 million hours

Armored Fiber Optic Cable

Definition of armored fiber optic cable
Armored Fiber Optic Cable, just as the name implies, is that there is a layer of additional protective metal armoring of the fiber optic cable.
Function
Armored fiber cable plays a very important role in long-distance line of fiber optic cable. A layer of metal armoring in the scarf-skin of fiber optic cable protects the fiber core from rodent, moist and erosion.

Classification
According to the place of use, there are indoor armored fiber optic cables and outdoor armored fiber optic cables.

Indoor armored fiber optic cable
Indoor armored fiber optic cable is mainly used in interior, so it must be flexible and can be installed in the corner and some narrow places. Besides, indoor armored fiber optic cable experiences less temperature and mechanical stress, but they have to be fire retardant, emit a low level of smoke in case of burning. And indoor armored fiber cables must allow a small bend radius to make them be amendable to vertical installation and handle easily.

Indoor armored fiber optic cable can be divided into simplex armored fiber optic cable and duplex armored fiber optic cable. The main difference is that simplex armored fiber optic cable is the cable that not contains stainless steel wire woven layer, and duplex armored fiber optic cable is the cable that contains stainless steel hose and stainless steel wire woven which are of compressive property, resistance to deflection, rodent resistance, anti-torque and so on.

Outdoor armored fiber optic cable
Outdoor armored fiber optic cables are made to protect the optical fiber to operate safely in complicated outdoor environment. Most armored outdoor fiber cables are loose buffer design, with the strengthen member in the middle of the whole cable, the loose tubes surround the central strength member.

Outdoor armored fiber optic cable can be divided into light armored fiber optic cable and heavy armored fiber optic cable. Light armored fiber optic cable is with steel tape and aluminium tape which can strengthen rodent protection. Heavy armored fiber optic cable is equipped with a circle of steel wire, and usually used in riverbed and seabed.

Installation
There are two installation methods of armored fiber optic cable. One is buried directly in the ground, and the other is aerial optical cable.

For direct burial fiber cable, armored fiber optic cable is in the position to resist external mechanical damage, prevent erosion and resist rodent. In addition, because of different soil and environment, the depth of burying under the ground is about between 0.8m-1.2m.

On the other hand, aerial optical cable is the optical cable that hanging on the pole. This kind of installation way of armored fiber optic cable can prevent fiber core from any kind of severe environment, such as typhoon, ice, and people or animals. Aerial armored optical cable mostly uses central loose tube armored fiber optic cable (GYXTW) and stranded loose tube armored fiber optic cable (GYTA). The features of GYXTW are that can contain up to 12 fiber cores, the loose tube is centrally situated with good excess length and minimizes the influence of lateral crush, and double wire as strength member provides excellent strain performance. GYTA is suitable for installation for long haul communication and LANs, especially suitable for the situation of high requirements of moisture resistance. GYTA is with compact structure; the cable jacket is made of strong Polyethylene. This armored fiber optic cable features the good mechanical and temperature performance. GYTA is also with high strength loose tube that is hydrolysis resistant and the optical cable filling materials ensure high reliability, its APL makes the cable crush resistant and moisture proof. The GYTA fiber optic cable is available from 2 cores to 144 cores.

The Introduction of Optical Power Meter

What Is an Optical Power Meter?
An Optical Power Meter usually knows as Fiber optical power meter is a device that used to measure the absolute optical signal and relate fiber optic loss. The term usually refers to a device for testing average power in fiber optic systems. Fiber optical power meter is a tool for telecommunication and CATV network. Optical power meter consists of a calibrated sensor, measuring amplifier and display. The sensor primarily consists of a photodiode selected for the appropriate range of wavelengths and power levels. On the display unit, the measured optical power and set the wavelength are displayed. Power meters are calibrated using a traceable calibration standard such as a NIST standard.

When to Use Optical Power Meter?
When you install and terminate fiber optic cables, you need to test them. A test should be conducted for each fiber optic cable plant for three main areas: continuity, loss, and power. In order to do this, you’ll need a fiber optic power meter.

How to Use Optical Power Meter?
When you measure fiber optic power with a power meter, you should attach the meter to the cable. Turn on the source of power, and view the meter’s measurement. Compare the meter measurement with the specified correct power for that particular system to make sure it have proper power not too much or too little . Correct power measurement is so important to fiber optic cables because the system works similar to electric circuit voltage, and the power must be just the right amount to work properly.

Classification of Optical Power Meter
There are two types of Optical Power Meter: Ordinary Optical Power Meter and PON Optical Power Meter. Ordinary optical power meter measures the optical power in the fiber link, typically an absolute power value 850/1300/1310/1490/1550/1625nm optical wavelength. While PON Optical Power Meter is more suitable for measuring the fiber to the home (FTTH) networks. Specific measurement: PON Optical Power Meter can send three wavelengths from a single laser output port (1310 nm, 1490 nm, 1550 nm), of which 1310nm can measure upstream transmission direction, 1490 nm and 1550 nm measure downstream direction. Upstream associated with your upload data, downward is download data.

Tips for Selection and Operation

Choose the best probe type and interface type.
Evaluation of calibration accuracy and manufacturing calibration procedures, and your fiber and connectors to match the required range.
Make sure the type and the range of your measurement and display resolution is consistent.
With immediate effect db insertion loss measurements.
Wear eye protection when working with high-power cables. Even with low-power layouts, it’s wise to check the connectors with your power meter before looking.

Are There Any Differences Between LX, LH and LX/LH?

We usually see LX SFP, LH SFP and LX/LH SFP on many websites, and many people show their confusion about them. Whether they are the same or different? If they are dissimilar, what differences between them on earth?

The Commonly Used 1000BASE-X Standards about Ethernet
Ethernet was the result of the research done at Xerox PARC in the early 1970s. Ethernet later evolved into a widely implemented physical and link layer protocol. Fast Ethernet increased speed from 10 to 100 megabits per second (Mbit/s). Gigabit Ethernet was the next iteration, increasing the speed to 1000 Mbit/s. The initial standard for Gigabit Ethernet was produced by the IEEE in June 1998 as IEEE 802.3z, and required optical fiber. 802.3z is commonly referred to as 1000BASE-X, which is used in industry to refer to Gigabit Ethernet transmission over fiber, where options include 1000BASE-SX, 1000BASE-LX, 1000BASE-LX10, 1000BASE-BX10 or the non-standard -EX and -ZX implementation.

Gigabit Ethernet 1000BASE-LX Optical Interface Specifications

1000BASE-LX is a fiber optic Gigabit Ethernet standard specified in IEEE 802.3 Clause 38 which uses a long wavelength laser (1,270–1,355nm). The 1000BASE-LX SFP is specified to work over a distance of up to 10 km over single mode fiber and it can also run over all common types of multimode fiber with a maximum segment length of 550 m. For link distances greater than 300 m, you must install a mode-conditioning patch cord between the transceiver and the MMF cable on both ends of the link.

1000BASE-LH and 1000BASE-LX/LH Optical Interface Specifications
LH refers to Long Haul. Many vendors use both of them for certain SFP modules, but they aren’t a Gigabit Ethernet standard at all. 1000BASE-LX/LH SFP can achieve a distance up to 20 km over single mode fiber. Unlike that, 1000BASE-LH SFP operates a distance up to 70 km over single mode fiber.

Conclusion
In a word, these three modules are all referred to Gigabit Ethernet transmission. Among them, the 1000BASE-LX is a standard, the other two just are terms widely used by vendors. Other long haul transmission standards include 1000BASE-LX10, 1000BASE-EX and 1000BASE-ZX. We can see their differences more clearly in the following chart:

Name	Medium	wavelength	Specified distance
1000BASE-LX/LH	9/125 Single mode fiber	1310nm	10km
1000BASE-LX	62.5/125, 50/125 Multi mode fiber	1310nm	550m
1000BASE-LX10	9/125 Single mode fiber	1310nm	10km
1000BASE-LH	9/125 Single mode fiber	1310nm	25~70km
1000BASE-EX	9/125 Single mode fiber	1310nm	40km
1000BASE-ZX	9/125 Single mode fiber	1550nm	70km

Some Common Types of Indoor Cables

Optical fiber cables for indoor cabling are used for the construction of horizontal subsystem and SCS building backbone cabling subsytems. They differ form cables used for outdoor cabling by two key parameters.

Indoor fiber optic cable is tight buffer design, usually they consist of the following components inside the cable, the FRP which is non-metallic strengthen member, the tight buffer optical fiber, the Kevlar which is used to further strength the cable structure, making it resist high tension, and the cable outer jacket. The trend is to use LSZH or other RoHS compliant PVC materials to make the cable jacket; this will help protect the environment and the health of the end users.

Indoor Cables

Cables for indoor applications include the following:

* Simplex cables
* Duplex cables
* Multifiber cables
* Heavy-, light-, and plenum-duty cables
* Breakout cables
* Ribbon cables

Although thes categories overlap, they represent the common ways of referring to fibers. Figure 7-5 shows cross sections of several typcial cables types.

Simplex Cables

A simplex fiber cable consists of a single strand of glass of plastic fiber. Simplex fiber is most often used where only a single transmit and/or receive line is required between devices or when a multiplex data signal is used (bi-directional communication over a single fiber).

Duplex Cables

A duplex fiber cable consists of two strands of glass or plastic fiber. Typically found in a “zipcord” construction format, this cable is most often used for duplex communication between devices where a separate transmit and receive are required.

Duplex cable is used instead of two simplex cables for aesthetics and convenience. It is easier to handle a single duplex cable, there is less chance of the two channels becoming confused, and the appearance is more pleasing. Remember, the power cord for your lamp is a duplex cable that could eaily be two separate wires. Does a single duplex cord in the lamp not make better sense? The same reasoning prevails with fiber optic cables.

Loose Tube Cables

The loose tube variety contains one or more hard buffer tubes, which house between 1 and 12 coated fibers. The hard buffer tubes are also filled with a gel to provide vibration and moisture protection for the fibers. The fibers lie loosely in the tubes, which are wound into the cable in a reversing helical fashion and are actually longer than the outer sheath of the cable. This arrangement allows for a small amount of stretch in the outer sheath when installing the cable. Loose tube cable is used most often in OSP construction because it is designed for a tough outdorr environment use. See Figure-1 for the physical make-up of a typical loose tube cable.

Breakout Cables

Breakout cabke

Breakout cables have several individual simplex cables inside an outer jacket. The breakout cables shown in Figure 2 use two dielectric fillers to keep the cables positioned, while a Mylar wrap surrounds the cables/fillers. The outer jacket includes a ripcord to make its removal fast and easy. The point of the breakout cable is to allow the cable subunits inside to be exposed easily to whatever length is needed. Breakout cables are typically available with two or four fibers, although larger cables also find use.

Ribbon Cables

ribbon cable

Ribbon cable uses a number of fibers side by side in a single jacket. Originally, Ribbon fiber cable was used for outdoor cables (see Figure 3). Today they also find use in premises cabling and computer applications. The cables, typically with up to 12 fibers, offer a very small cross section. They are used to connect equipment within cabinets, in network applications, and for computer data centers. In addtion, they are comatible with multifiber array connectors. Ribbon cables are available in both multimode and single-mode versions.

The Application and Types of Armored Fiber Cable

What Is Armored Fiber Cable?
Armored fiber optic cable consists of a cable surrounded by a steel or aluminum jacket which is then covered with a polyethylence jacket to protect it from moisture and abrasion. It may be run aerially, installed in ducts, or placed in underground enclosures with special protection from dirt and clay intrusion.

armored fiber optic cable

Armored fiber optic cable is often installed in a network for added mechanical protection. Two armored fiber cable types exist: interlocking and corrugated. 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.

Types Of Armored Fiber Cable

Armored fiber cable can be divided into indoor armored fiber cable and outdoor armored fiber cable. With the fast development of fiber optic communication technology and the trend of FTTX, indoor fiber optic cables are more and more required to be installed between and inside buildings. Typical indoor armored fiber cable types include GJFJV, GJFJZY, GJFJBV, GJFJBZY, GJFDBV and GJFDBZY. Compared with outdoor use fiber cable, indoor fiber cable experiences less temperature and mechanical stress, but they have to be fire retardant, emit a low level of smoke in case of burning. And indoor armored fiber optic cable allows a small bend radius to make them be amendable to vertical installation and handle easily.

Features of Indoor Armored Fiber Cable

* Good mechanical property and environment property.
* Soft, agility, convenience for connect.
* Flexible and Easy to Handle
* Cables with Improved Attenuation Available
* Adapt to harsh environments and man-made damage.

Outdoor armored fiber cable is made to protect the optical fiber to operate safely in complicated outdoor environment. Most Outdoor Armored fiber cables are loose buffer design, with the strengthen member in the middle of the whole cable, the loose tubes surround the central strength member. Inside the loose tube there is waterproof gel filled, whole cable materials used and gels inside cable between the different components (not only inside loose tube) will help make the whole cable resist of water.

Features

* Excellent attenuation performance
* Dry water blocking for moisture protection
* Polyethylene jacket for weather and UV protection
* Breakout kits available
* Corrugated Steel Tape
* Rodent Resistant
* Waterblock gel available

Application of Armored Fiber Cable

Armored fiber cable is used in direct buried outside plant applications where a rugged cable is needed and/or for rodent resistance. Armored fiber optic cable withstands crush loads well, for example in rocky soil, often necessary for direct burial applications. Cable installed by direct burial in areas where rodents are a problem usually have metal armoring between two jackets to prevent rodent penetration. Another application for armored fiber cable is in data centers, where cables are installed under the floor and one worries about the fiber cable being crushed. Indoor armored fiber optic cables may have nonmetallic armor. Metallic armored fiber cable is conductive, so it must be grounded properly. As with other fiber optic components, there are different names or meanings used. “Armor” in some companies’ jargon denotes a twisted heavy wire rope type cable surrounding the entire poly cable sheath/jacket. Single or double armor (two opposite ply layers of the steel wire) is typically used underwater near shore and shoals. Inner metallic sheath members of aluminum and/or copper are used for strength and for buried cable locating with a tone set.

Fiber Optic Cabling Solutions

The largest solutions of pre-terminated fiber optics, including multimode and single-mode patch cords, MTP/MPO fiber trunks and harnesses, plug-n-play modules/cassettes and fiber enclosures.