Tag Archives: Optical fiber

FS Polarity Switchable LC Uniboot Cable: Leading Trend in Fiber Optics

The data center is moving towards high speed and high density. How to build more optical fiber cables in limited space is becoming increasingly severe. In this case, FS.COM introduced a new-type product suitable for high density cabling requirement—polarity switchable LC uniboot cable. It’s the preferred option for high density data center connection today. Its largest feature is switchable polarity, designed to eliminate the need for dual zip cords and reduce overall bulk cabling by 50%. But do you know about polarity switchable LC uniboot cable? What are the features of it and how to reverse the polarity? You may find answer in this post.

Introduction to LC Uniboot Fiber Patch Cable

LC uniboot fiber patch cables are designed for high density applications in data center environment. Generally, the LC uniboot patch cord is designed with a polarization method that can help users easily reverse the fiber polarity. In addition, the LC uniboot fiber patch cable can reduce cable management space comparing to standard patch cord as it places both simplex fibers into one jacket while still terminating into a duplex LC connector. Similar to the standard patch cord, single-mode and multimode versions are available in LC uniboot patch cables.

FS Polarity Switchable LC Uniboot Cable

Features & Advantages

FS polarity switchable LC uniboot cables feature high density. They are used to connect switches or network devices in fiber networks directly or interconnect structured cabling systems in a fiber network. Besides, FS uniboot fiber patch cable has the following highlights.

  • Easy polarity reversal: Polarity changes can be made in the field quickly, without the use of tools, to the correct fiber mapping polarity.
  • “All in One” international quality cable assemblies: FS uniboot fiber patch cable has passed IEC61300-3-35 end-face standard, EIA/TIA-455-171A attenuation standard and CE, etc. providing customers with the outstanding, standards-compliant products and services.

All in One International Quality Cable Assemblies_

  • LC licence compliant & 0.2dB IL: The worldwide licence and low insertion loss keep your network running fast and smooth.

LC Licence Compliant & 0.2dB IL

  • 2.0mm round cable design: 2.0mm thin diameter allows the polarity to be switched from A-B to A-A without any tools.
  • More fiber options: OM3, OM4, and OS2.
  • Space saving: It can save the space of cassettes and cable management by 68%.
How to Achieve Polarity Reversal of LC Uniboot Cable

As we know, for traditional cabling systems using single fiber connectors, maintaining polarity requires that the “A” transmits signal and at the same time the “B” receives signal. But duplex patch cords used to complete serial duplex pair connections available in two types, depending on which polarity technique is used— “A-to-B” patch cord for “straight-through” wiring and “A-to-A” patch cord for “crossover”wiring. Thus, polarity reversal is usually required during fiber optic cabling.

polarity of LC Uniboot Cable

However, polarity reversal of traditional LC patch cable is very inconvenient and annoying since some minor mistakes could lead to various troubles. Therefore, FS.COM developed the LC uniboot cable that is easier for polarity reversal, without having to re-terminate the connectors. Here two methods of polarity reversal are introduced as follows.


From the above picture, we can see that we can use just 3 steps to reverse polarity. Type one (the left one):

1. Open connector top.

2. Switch the polarity from A-B to A-A.

3. Close connector top.

Type two (the right one):

1. Open connector top.

2. Rotate connector 180 degree to exchange the position.

3. Close connector top.


To address the increasing demand for high density applications and smaller fiber cable, the LC uniboot fiber patch cable is designed to help cut down cabling space and provide more effective polarity reversal solution. I hope this article could help you choose the proper product for high density cabling. FS.COM not only provides polarity switchable LC fiber patch cable, but also provides bend insensitive fiber patch cable which is also a high density cabling application. Welcome to consult with customer service for more details.

Optical Fiber Benefits the Green Data Center Building

Green DataCenterWith the amount of energy now required to power the world’s data centers, one of the greatest challenges in today’s data centers is minimizing costs associated with power consumption and cooling, which is also the requirement of building the green data center. Higher power consumption means increased energy costs and greater need for heat dissipation. This requires more cooling, which adds even more cost. Under these circumstances, high-speed optical fiber offers a big advantage over copper to reduce the network operational and cooling energy.

What Is Green Data Center?
The word “green” invokes natural images of deep forests, sprawling oak trees and financial images of dollar bills. The topic of green has been gaining momentum across international, commercial and industrial segments as global warming and greenhouse gas effects hit headlines. In terms of different fields, the word “green” has different definitions. Specific to the data center segment of the telecommunications industry, green data center is a repository for the storage, management, and dissemination of data in which the mechanical, lighting, electrical and computer systems are designed for maximum energy efficiency and minimum environmental impact.

green data enter

How to Build Green Data Center?
Green data center address two issues which plague the average data center. One is the power required to run the actual equipment, the other is the power required to cool the equipment. Reduced the power required will effectively lessen not only the energy consumption but also the impact on environment. Green solutions include:

  • More efficient hardware components and software systems
  • Innovative cooling systems
  • Using natural ways to cool equipment
  • Building near advantageous natural resources or environments
  • Effective server and rack management for better air-flow

How Does Optical Fiber Benefit the Green Data Center Building?
Compared to copper cable, optical fiber may offer many advantages in contribution to building green data center. Usually, optical fiber connectivity can enhance green data center installations by utilizing high-port-density electronics with very low power and cooling requirements. Additionally, an optical network provides premier pathway and space performance in racks, cabinets and trays to support high cooling efficiency when compared to copper connectivity. All these advantages can be summarized as the following three points.

Lower Operational Power Consumption
Optical transceiver requires less power to operate compared to copper transceiver. Copper requires significant analog and digital signal processing for transmission that consumes significantly higher energy when compared to optical media. A 10G BASE-T transceiver in a copper system uses about 6 watts of power. A comparable 10G BASE-SR optical transceiver uses less than 1 watt to transmit the same signal. The result is that each optical connection saves about 5 watts of power. Data centers vary in size, but if we assume 10,000 connections at 5 watts each, that’s 50 kW less power—a significant savings opportunity thanks to less power-hungry optical technology.

Less Cooling Power Consumption
Optical system requires far fewer switches and line cards for equivalent bandwidth when compared to a copper card. Fewer switches and line cards translate into less energy consumption for electronics and cooling. One optical 48-port line card equals three copper 16-port line cards (as shown in the following picture). A typical eight-line card chassis switch would have 384 optical ports compared to 128 copper ports. This translates into a 3:1 port advantage for optical. It would take three copper chassis switches to have equivalent bandwidth to one optical chassis switch. The more copper chassis switches results in more network and cooling power consumption.

Line card port density in a 10G optical system vs. copper system

More Effective Management for Better Air-flow
Usually, a 0.7-inch diameter optical cable would contain 216 fibers to support 108 10G optical circuits, while 108 copper cables would have a 5.0-inch bundle diameter. The larger CAT 6A outer diameter impacts conduit size and fill ratio as well as cable management due to the increased bend radius. Copper cable congestion in pathways increases the potential for damage to electronics due to air cooling damming effects and interferes with the ability of ventilation systems to remove dust and dirt. Optical cable offers better system density and cable management and minimizes airflow obstructions in the rack and cabinet for better cooling efficiency. See the picture below: the left is a copper cabling system and the right is an optical cabling system.

copper cabling system vs optical cabling system

Data center electrical energy consumption is projected to significantly increase in the next five years. Solutions to mitigate energy requirements, to reduce power consumption and to support environmental initiatives are being widely adopted. Optical connectivity supports the growing focus on a green data center philosophy. Optical cable fibers provide bandwidth capabilities that support legacy and future-data-rate applications. Optical fiber connectivity provides the reduction in power consumption (electronic and cooling) and optimized pathway space utilization necessary to support the movement to greener data centers.

DWDM play an important role in submarine systems

Advantages of DWDM Multiplexer

DWDM is a very effective means of sharing transmission costs when fiber and other common components, such as optical amplifiers, dominate the overall system cost. The aggregate capacity of a single optical fiber can be increased by either increasing the bit rate or by increasing the number of wavelength channels using DWDM. The former requires development of new high-speed electronics, while DWDM allows fiber and fiber amplfier costs to be shared among all channels, driving down the total system cost per channel. Since information must still be coded onto the wavelength channels, today’s long-haul systems combine time-division multiplexing(TDM) with DWDM, taking advantage of high speed TDM advances to further reduce the system cost per bit per channel.

Both long-haul and undersea systems depend heavily on dense wavelength division multiplexed (DWDM) signals to achieve high-capacity transport.

Current long-haul system development efforts have focused on wide-band DWDM and ultra-long transport. These systems are enabled by new modulation formats, wideband amplification, wideband dispersion compensation and the use of forward error correction coding. Taken as a whole , these systems will deliver the lowest cost per transmitted bit over the longest distance . Optical fiber is an integral component of the entire system. T he fiber’s parameters have a significant impact on both cost and performance and influence the choice of most other components, such as amplifiers and compensators. In fact ,the use of wideband DWDM over ultra-long distances has elevated the fiber requirements in terms of dispersion management, nonlinear performance, distributed gain, spectral loss, and polarization mode dispersion (PMD).


The first applications of fiber optic communication were to carry aggregated voice traffic between major metropolitan areas, such as the trunk lines from Washington, DC to Boston. In the United States, typical distances between major switch centers are on the order of 1600 km, while in Europe, these distances are typically 400 km. However, with the advent of all-optical or photonic switching located at these centers, the transmission distances without electronic regeneration could reach well into the thousands of kilometers in both cases, with the application space for these systems spilling over into the metro and regional networks. Such ultra-long distances have historically been reserved for point-to-point undersea fiber systems where transoceanic distances are typically 10,000 km and 4000 km for Trans-Pacific and Trans- Atlantic routes, respectively. As these distances are approached in terrestrial applications, it is not unreasonable to think of using similar system solutions for land applications.