The History of fiber-optic communication

In 1880 Alexander Graham Bell and his assistant Charles Sumner Tainter created a very early precursor to fiber-optic communications, the Photophone, at Bell’s newly established Volta Laboratory in Washington, D.C. Bell considered it his most important invention. The device allowed for the transmission of sound on a beam of light. On June 3, 1880, Bell conducted the world’s first wireless telephone transmission between two buildings, some 213 meters apart. Due to its use of an atmospheric transmission medium, the Photophone would not prove practical until advances in laser and optical fiber technologies permitted the secure transport of light. The Photophone’s first practical use came in military communication systems many decades later.

In 1966 Charles K. Kao and George Hockham proposed optical fibers at STC Laboratories (STL) at Harlow, England, when they showed that the losses of 1000 dB/km in existing glass (compared to 5-10 dB/km in coaxial cable) was due to contaminants, which could potentially be removed.

Optical fiber was successfully developed in 1970 by Corning Glass Works, with attenuation low enough for communication purposes (about 20dB/km), and at the same time GaAs semiconductor lasers were developed that were compact and therefore suitable for transmitting light through fiber optic cables for long distances.

After a period of research starting from 1975, the first commercial fiber-optic communications system was developed, which operated at a wavelength around 0.8 mm and used GaAs semiconductor lasers. This first-generation system operated at a bit rate of 45 Mbps with repeater spacing of up to 10 km. Soon on 22 April 1977, General Telephone and Electronics sent the first live telephone traffic through fiber optics at a 6 Mbit/s throughput in Long Beach, California.

The second generation of fiber-optic communication was developed for commercial use in the early 1980s, operated at 1.3 mm, and used InGaAsP semiconductor lasers. These early systems were initially limited by multi mode fiber dispersion, and in 1981 the single-mode fiber was revealed to greatly improve system performance, however practical connectors capable of working with single mode fiber proved difficult to develop. By 1987, these systems were operating at bit rates of up to 1.7 Gb/s with repeater spacing up to 50 km.

The first transatlantic telephone cable to use optical fiber was TAT-8, based on Desurvire optimized laser amplification technology. It went into operation in 1988.

Third-generation fiber-optic systems operated at 1.55 mm and had losses of about 0.2 dB/km. They achieved this despite earlier difficulties with pulse-spreading at that wavelength using conventional InGaAsP semiconductor lasers. Scientists overcame this difficulty by using dispersion-shifted fibers designed to have minimal dispersion at 1.55 mm or by limiting the laser spectrum to a single longitudinal mode. These developments eventually allowed third-generation systems to operate commercially at 2.5 Gbit/s with repeater spacing in excess of 100 km.

The fourth generation of fiber-optic communication systems used optical amplification to reduce the need for repeaters and wavelength-division multiplexing to increase data capacity. These two improvements caused a revolution that resulted in the doubling of system capacity every 6 months starting in 1992 until a bit rate of 10 Tb/s was reached by 2001. In 2006 a bit-rate of 14 Tbit/s was reached over a single 160 km line using optical amplifiers.

The focus of development for the fifth generation of fiber-optic communications is on extending the wavelength range over which a WDM system can operate. The conventional wavelength window, known as the C band, covers the wavelength range 1.53-1.57 mm, and dry fiber has a low-loss window promising an extension of that range to 1.30-1.65 mm. Other developments include the concept of optical solitons, pulses that preserve their shape by counteracting the effects of dispersion with the nonlinear effects of the fiber by using pulses of a specific shape.

In the late 1990s through 2000, industry promoters, and research companies such as KMI, and RHK predicted massive increases in demand for communications bandwidth due to increased use of the Internet, and commercialization of various bandwidth-intensive consumer services, such as video on demand. Internet protocol data traffic was increasing exponentially, at a faster rate than integrated circuit complexity had increased under Moore’s Law. From the bust of the dot-com bubble through 2006, however, the main trend in the industry has been consolidation of firms and offshoring of manufacturing to reduce costs. Companies such as Verizon and AT&T have taken advantage of fiber-optic communications to deliver a variety of high-throughput data and broadband services to consumers’ homes.

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New Submarine Cables Put to Revolutionize West African Internet

Slow downloads and faulty Internet connections could soon become distant memories in West Africa. Two underwater fiber-optic cables stretching from Europe down the western coast of Africa are set to go online in mid-2012. The cables will bring faster, and likely cheaper, broadband Internet to nearly every country in the region.

Patricia Oben runs an international trade and consultancy firm in Douala, Cameroon. She pays nearly $100 each month for the best Internet connection available, which she describes as one step up from snail speed.

I try to send sometimes 60 pages. That might take you anything up to 18, 20 hours, which means that sometimes at night you set it up and you keep your fingers crossed that sometime in the middle of the night it will not just stop working. Sometimes it takes more time to use the Internet than to use DHL. I sent a CD to India. The CD got there before we could finish uploading. Three days. It’s incredibly frustrating. A lot of time wasting and money wasting, she said.

Oben says her firm has lost sales because she could not access catalogues or information in time.

But that could all change in just a few months as two extensive submarine fiber-optic cables are to set to bring faster and more reliable broadband Internet to Cameroon and 18 other countries along the Atlantic coast of Africa.

Seven of those countries, including Liberia, Guinea and Sierra Leone, will get broadband access for the first time after years of relying on slower and more expensive satellite links.

Paul Brodsky is a senior analyst at the Washington-based market research firm, Telegeography. Broadband Internet, he says, is actually a vast global plumbing of fiber-optic cables. It is quite literally strands of glass that are no thicker than a human hair through which pulses of light, laser light, get shot through. These very high frequencies of laser light carry the information, the data, between computers in West Africa and Europe, North America and the rest of the world, he said.

The strands of glass are twisted in pairs, encased in protective layers of steel and rubber and then run along the ocean floor from global network hubs in Europe.

Eight West African countries, including Cameroon, are already connected via the older and slower SAT-3 cable and the Nigeria-based MainOne cable, which came online in mid-2010.

Brodsky says the two new cables will each have potential capacities of 5.12 terabits a second – more than the region may likely ever need. Those benefits should translate to lower pricing for consumers and businesses who need access to the Internet, as well as improved bandwidth, he said.

However, he said telecom monopolies in some countries could keep consumer prices high, at least in the short term, though overlaps in coverage could also foster competition.

National governments and private telecoms, like MTN and France Telecom, are footing the more than $600-million bills for each cable.

The Africa Coast to Europe, or ACE, cable will stretch 17,000 kilometers and land in 20 countries on its way from France to South Africa. The West Africa Cable system, or WACS, will measure 14,000 kilometers and hit 13 countries between London and South Africa.

Hundreds of millions of dollars of terrestrial cables must also be built to connect rural areas and landlocked countries, like Mali and Niger, to the submarine network.

The economic impact could be huge. The World Bank says every 10-percent increase in broadband connection boosts economic growth by 1.38 percent. The WACS cable alone is expected to increase connectivity by more than 20 percent.

Eastern and Southern Africa are a few years ahead of West Africa. A second underwater cable, SEACOM, went online on that side of the continent in July 2009.

Harvard University professor and telecommunications expert, Calestous Juma, says he has already seen the results in his native Kenya. We are starting to see the emergence of small enterprises that rely on high-speed Internet or broadband access. For example, small start-up companies in Kenya that are working on animation for Hollywood. Animators can get contracts from Hollywood, do the work in Kenya and ship the product back to Hollywood, he said.

High speed Internet, he says, creates jobs, increases productivity and levels the playing field between businesses in developed countries and those in emerging economies.

Think of it as the equivalent of roads. When you build a road somewhere, you open up not just new possibilities, but it is a signal of hope to the people that there is actually a future. For the first time, they can think about being able to reach the rest of the world, he said.

Analysts also expect better broadband connectivity to boost the already booming market for wireless 3G devices in Africa.

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Verizon Starts Its First Tri-Lingual FiOS Store

When it comes to communications and entertainment services, Providence-area consumers want theirs to be fast, reliable and easy to use. And in offering those services, Verizon is speaking consumers’ languages. Literally.

Verizon on Tuesday (April 3) officially opened its first tri-lingual FiOS retail store, where employees are ready to serve customers in English, Spanish, and Portuguese. The store is located at 579 Atwells Ave.

Mayor Angel Tavaras and members of the Providence City Council, along with New England Patriots legend Joe Andruzzi, joined leaders from Verizon at a grand-opening ceremony at the store.

As part of the ceremony, Verizon executives presented a $2,500 donation to Children’s Friend, a Rhode Island nonprofit dedicated to helping underprivileged children.

Also at the event, Verizon announced that it is bringing FiOS voice, Internet and TV service to the 40 units of Eagle Square.

I commend Verizon for its role as a terrific corporate citizen in our city, said Mayor Tavaras. Time and again Verizon has demonstrated that it understands our community, and is making it easier for our residents and businesses to do business with them.

Susan Retta, vice president of marketing for Verizon, said: Verizon has a long, proud history of citizenship in Providence, and the opening of our new FiOS store is another example of that. Providing excellent customer service is a priority for Verizon. Having employees in our store who speak Spanish and Portuguese will enhance the experience for our customers.

Employees at the new Verizon FiOS store will be able to help FiOS customers with questions about their FiOS Internet, TV and voice service, as well as demonstrate some of its exciting new features, including Home Monitoring and Control Service,* which enables customers to check on their home, or the kids and pets, from anywhere, anytime, right from their computer, smartphone or tablet.

Visitors to the new Verizon FiOS store also will be able to upgrade their set top boxes and pay their bills.

FiOS TV customers receive many added benefits that are included in their service at no additional cost. For example, FiOS TV includes 35,000 monthly video-on-demand titles (more than 15,000 of which are free), including 8,000 in HD, and next-generation interactive services including an advanced interactive media guide; news, traffic, weather, sports, entertainment and social networking apps that include Twitter and Facebook; DVR management via broadband or cell phone; and more.

In addition, FiOS TV customers have online access to thousands of movie titles and TV shows through Verizon’s Flex View and FiOS TV Online services. Flex View allows FiOS TV customers to rent or purchase more than 10,000 movie titles and watch them on their TV, online and on a growing number of mobile devices including smartphones and tablets. FiOS TV Online offers online access to a variety of programming from HBO, Showtime, Cinemax, EPIX, TBS, TNT, truTV, Cartoon Network, Adult Swim, Nickelodeon, Comedy Central and MTV as well as live streaming from CNN, ESPN, NBA League Pass and the Longhorn Network.

FiOS TV also offers a multi-room DVR that allows customers to view, record, pause and rewind programming on up to three TVs in the home at the same time.

Customers can access their FiOS TV DVRs remotely from a PC or select mobile devices with the MY FiOS app, which also provides access to movies, TV shows and personal content; home and energy monitoring; and billing, account management and customer service tools. All FiOS TV customers also have access to Media Manager, which lets them access personal videos, photos and music from their home computer on their TV.

FiOS TV is delivered over Verizon’s all-fiber-optic network, which brings the power and capacity of fiber optics directly into homes and businesses and has industry-leading quality and reliability. Fiber delivers amazingly sharp pictures and sound, and has the capacity to transmit a wide array of high-definition programming that is so clear and intense it seems to leap from the TV screen.

The network also offers FiOS Internet Service, America’s fastest, most reliable, most consistent Internet service. It delivers downstream speeds of up to 150 Mbps (megabits per second) and upstream speeds of up to 35 Mbps.

Verizon Communications Inc., headquartered in New York, is a global leader in delivering broadband and other wireless and wireline communications services to consumer, business, government and wholesale customers. Verizon Wireless operates America’s most reliable wireless network, with nearly 108 million total connections nationwide. Verizon also provides converged communications, information and entertainment services over America’s most advanced fiber-optic network, and delivers integrated business solutions to customers in more than 150 countries, including all of the Fortune 500. A Dow 30 company with $111 billion in 2011 revenues, Verizon employs a diverse workforce of nearly 194,000.

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Application of Fiber Converters Technology

Fiber optic networks already enjoy popular support, a synonym for high-speed and effective in the communication system also has the realization of the large-scale deployment and application. To achieve a transparent, high survivability of AON System is the development of broadband communication network. Optical switching technology as an important basis in AON technologies, the development and application of fiber converters largely determines the direction of future fiber optic networks.

Fiber optic network has the advantages of large information capacity and strong anti-interference ability, its superior performance has been confirmed, and gradually take the place of electronic circuit as the main communication network, become an important way of modern communication.

In fiber optic networks systems, only scientific and reasonable communications architecture can express the advantages of optical fiber system, to make up the ideal of high speed, large capacity, high quality fiber optic network, and the original electronic circuit communication in all optical network is a huge obstacle, to get rid of the influence of the electronic circuit is need to improve optical fiber communication system technology. So optical switching technology, is considered to be one of the most important and new generation of broadband technology.

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Types of fiber optic attenuators

1. Female to male plug style optical attenuator (MU, SC, FC, ST, LC) PC& APC polish available;
2. Flange style fiber optical attenuator;
3. Adjustable fiber optical attenuator (FC style) Attenuation scale:0~30dB;
4. IN-Line style fiber optical attenuator.

Wide range variable & inline fiber optic attenuator
The inline fiber optic attenuators are with more accurate attenuation compared with traditional connector type fiber optic attenuators. What is more, the fiber optic attenuator is with a precision screw set, by turing it, the attenuation range can be varied. And this fiber optical attenuator can be with various terminations on the each side of the cable.

Variable Fiber Optic Attenuators
Fixed value fiber optic attenuators can reduce the power of fiber light at a fixed value loss, for example, a 10dB SC fiber optic attenuator will reduce the optical power 10dB and utilize a SC male to female attenuator. Variable fiber optic attenuators (or adjustable fiber optic attenuator) are with adjustable attenuation range. It usually is inline type, the appearance like fiber optic patch cord; it is with an adjustable component in the middle of the device to change the attenuation level to a certain figure. There are also handheld variable fiber optic attenuators; they are used as test equipment, and we have the inline fiber optic attenuators.

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FTTH Solutions for Multi-Stories Building

According to the characteristics of China’s building based on multilayer foreign mature in the FTTH network operators/high-rise building fiber-to-the-home wiring deployment experience, TE telecom network department specifically for the Chinese market developed multi-layer and high-rise building (MDU) rapid installation. In the process of the FTTx solutions, the protection of operator, on the basis of reasonable assets investment, promote the rapid response ability of the customer service, and reduce the overall network operation and maintenance costs, the bandwidth of the user help operators to cope with rising demand effectively. TE can provide industry leading end-to-end FTTH network overall current solutions, both in terms of room/data center or outside the facility and multi-stories building, TE connection/cable and protection of all kinds of products.

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Optical Module/ Fiber Module Product Overview

Integrated optical transceiver modules (Transceiver): often referred to as the optical module or fiber optic module, also it was called the optical transceiver module.
Optical module types:
1. Classified according to the package in the form of optical module: SFP、GBIC、XFP、Xenpak、X2、1X9、SFF、200/3000pin、XPAK、SFP+，RJ45。
2. Classified according to the transmission rate optical module: Unit Mb/s or Gb/s. Optical module product mainly has the following rate: low rate optical module, hundred trillion optical module (such as 155M), Gigabit optical module (2.5G, 25G and 4.9G, 6G, 8G), Gigabit optical modules (10G and 40G).
3. SDH transmission optical module: OC3,OC12,OC48
Fiber optic module common model: GLC-SX-MM，GLC-LH-SM/GLC-LX-SM，GLC-ZX-SM，GLC-T,DX，CWDM，FX
Fiber module common laser and wavelength:850nm/1310nm/1550nm/1470nm/1490nm/1510nm/
1530nm/1550nm/1570nm/1590nm/1610nmVCSEL/FP/DFB
Single-mode optical module or multimode optical module
Fiber optic module the mainstream interface type: Duplex LC interface, SC connector
Major optical module manufacturers brand: Cisco, Huawei, H3C, HP, Nortel, 3COM, EXTREME, Alcatel-Lucent, NeoPhotonics, SourcePhotonics,WTD ZTE. In these brand, the Cisco optical module is the most common brand.
At present, The number of optical module manufacturers has been increased, the various suppliers / sellers are numerous. With major brand manufacturers, after many developed optical module manufacturers, mainly mainly to production Compatibility (OEM) products. Compared with the big brand manufacturers, optical module manufacturers cheap.
Shenzhen optical module manufacturers in the development of the country should be the fastest, a large number of optical module products much lower than the prices of the major brand manufacturers are quick to sell to the various countries of the world’s regions. With the progress of the communications industry, the development of the optical module manufacturers in Shenzhen, I believe that can be driven by the rapid development of the national optical module products.
FiberStore is located in Shenzhen of China. FiberStore is an professional manufacturer & supplier of transceivers. All our fiber transceivers are 100% compatible with major brands and backed by a lifetime warranty. Meanwhile, we can customize transceivers to fit your specific requirements.

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Optical Fiber Cables

An optical fiber cable is a cable containing one or more optical fibers. Optical fiber cable is made of thin reflective tubing that sends light particles that can contain data from one end to the other. The tubing has a mirror-like interior which literally bumps the particle around the microscopic tube until it arrives at its destination. The optical fiber elements are typically individually coated with plastic layers and contained in a protective tube suitable for the environment where the cable will be deployed. Now I am grade to introduce the cable types of Cat5e network cable and outdoor Fiber Optic Cable.
Cat5e network cable
Cat5e network cable (Cat 5) is a twisted pair cable for carrying signals. CAT 5 is an Ethernet network cable standard defined by the Electronic Industries Association and Telecommunications Industry Association (commonly known as EIA/TIA). CAT5 cable contains four pairs of copper wire, which supports Fast Ethernet speeds (up to 100 Mbps). CAT5 is the fifth generation of twisted pair Ethernet technology and the most popular of all twisted pair cables in use today.
Twisted pair cable like CAT5 comes in two main varieties, solid and stranded. Solid CAT5 cable supports longer length runs and works best in fixed wiring configurations like office buildings. Stranded CAT5 cable, on the other hand, is more pliable and better suited for shorter-distance, movable cabling such as on-the-fly patch cabling.
Cat 5 is used in structured cabling for computer networks such as Ethernet. The cable standard provides performance of up to 100 MHz and is suitable for 10BASE-T, 100BASE-TX (Fast Ethernet), and 1000BASE-T (Gigabit Ethernet). Cat 5 is also used to carry other signals such as telephony and video. In some cases, multiple signals can be carried on a single cable; Cat 5 can carry two conventional telephone lines as well as a single 100BASE-TX channel in a single cable or two 100BASE-TX channels in a single cable.
Though newer cable technologies like CAT6 and CAT7 are in development, CAT5 / CAT5e Ethernet cable remains the popular choice for most wired local area networks (LANs), because Ethernet gear is both affordable and supports high speeds.
Outdoor Fiber Optic Cable
Outdoor fiber optic cable is made to protect the optical fiber to operate safely in complicated outdoor environment. Most 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. 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.
Bulk outdoor fiber optic cable enables pixel-perfect transmission of AV signals over extreme distances and is available as singlemode or laser-optimized multimode fiber optic cables. Singlemode fiber’s low-loss provides extreme performance up to 30 km or 18.75 miles, while laser-optimized multimode fiber is used for moderately long distances up to 2 km. The bend-insensitive fiber design enables a tight bend radius with minimal bending loss to simplify installation.
Fiberstore provides a wide range of optical fiber options so that our customers have the flexibility to choose a cable plant to best fit their needs. Only optical fiber that meets or exceeds industry standards is used to ensure quality products with best-in-class performance. Fiberstore Bulk Fiber Optic Cables are compatible with all Extron FOX Series products. We supply various kinds outdoor use fiber cables including both armored type and not armored type; these cables are competitive on prices and fast delivery.

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Optical Communication Definition

Optical communication is the lightwave carrier communication. To increase the bandwidth of the optical path, there are two methods: One is to increase the fiber single-channel transmission rate; second is to increase the number of single fiber transmission wavelength, the fact that the wavelength division multiplexing technology (WDM), optical communication equipment is only suitable in the last few km distance.
Development Status
Optical communication, the technology is mature, while the relative lack of business needs. For example, known as the ultimate goal of  broadband access for FTTH technology EPON is already fully mature, but the ordinary Internet users need high bandwidth, FTTH commercial use only a limited number of pilot areas. However, in 2006, with IPTV and other triple play services to carry out the bandwidth provided by the operators can not meet the requirements of the users of high-definition television, followed by the deployment of FTTH on the agenda. Coincidentally, ASON transport networks and flexible control, provides enterprise customers with personalized services, many operators to develop and maintain corporate customers, and spared no expense to invest in the construction of ASON.
All-Optical Network
The ultimate goal of the transmission network, to build all-optical networks, namely, in the access network, MAN, backbone network, the full realization of the optical fiber transmission instead of copper wires. Of all R & D progress toward the process of this goal.
The backbone network is the highest part of the network speed, distance and capacity requirements of ASON technology used in backbone networks is an important step in the intelligent optical network, the basic idea is the introduction of intelligent control plane in the optical transmission network, which realization of resources according to need. DWDM is also in the backbone network show their skills, the future may be completely replaced by SDH, in order to achieve IPOVERDWDM.
MAN will become the operator to provide bandwidth and services and bottlenecks, and at the same time, MAN will become the largest market opportunities. SDH-based MSTP technology is mature, good compatibility, in particular, is the adoption of new standards such as RPR, GFP, LCAS and MPLS, flexible and effective support for a variety of data services.
Access network, FTTH (fiber to the home) is a long-term ideal solution. FTTx evolutionary path will gradually be fiber to the user to push close to the process, from FTTN (Fiber to the district) to FTTC (fiber to the curb) and FTTB (fiber to the apartment building) and even finally to FTTP (fiber to the premises) . Of course, this is a very long transition period, in this process, fiber access will ADSLADSL2 + coexist.
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Spectroscopic Principle of An Optical splitter

Fiber splitter or fiber optic splitter is one of the most important passive devices in the fiber network, an optical fiber having a plurality of inputs and a plurality of output terminals tandem device, commonly used in M × N to indicate a splitter M inputs and N outputs. The optical splitter used in the CATV system, are generally 1 × 2, 1 × 3, and composed of them 1 x N optical splitter. Just the same with the coaxial cable transmission system, in a optical network system, an optic signal of a optical network system also needs to coupled to the branch distribution, which require a important fiber optic passive component – the optical splitter.
Optical splitter can be divided into two types according to the spectroscopic principle: Fused Biconical Taper (FBT) and Planar Lightwave Circuit (PLC). FBT splitter is to side fuse two or more fiber together. While the PLC Splitter is a micro-optical components product, which adapt of the lithography, forming an optical waveguide in the medium or on a semiconductor substrate. Basically the two type of fiber splitter share the similar spectroscopic principle. Both of them are coupled to each other by changing the optical fiber between the evanescent field (the degree of coupling, the coupling length) as well as to change the radius of the optical slender to achieve different size branching amount. On the contrary, things that combining multiple optical signals or vice versa into one single can be called Fiber synthesizer.
FTB Coupler
The working principle of FTB method is to fuse two or more optical fiber that without coating layer together by melting them under a high temperature environment, stretching the both sides to form a double cone zonespecial waveguide structured. Different spectral radios can be obtained by controlling the length of the fiber torsion angle and stretched. Finally, pull the cone on the quartz substrate with a curable adhesive curing and insert into a stainless brass. That’s how an FTB coupler formed.
There are some disadvantages of this method. Due to the coefficient of thermal expansion of the curing adhesive with a quartz substrate, the stainless steel tube inconsistencies, the degree of thermal expansion and contraction will be inconsistent when the ambient temperature changes. This is likely to cause damages to the optical splitter, which would become worse if in the wild. This is also the main reason that this fiber optic splitter is easy to get damaged. However, due to the making method of the FBT Coupler is simple, inexpensive, easy to connect to external fiber as a whole, and resistance in for-mechanical vibration and temperature changes, and other advantages, it has become the mainstream manufacturing technology in current the market.
PLC Splitter
The PLC splitter adopted semiconductor production process like photolithography, etching, developing technology and more. Waveguide array is located on the upper surface of the chips, the shunt function is integrated on the chip, which is implemented 1:1 branching on a chip. Then then coupled the multi-channel optical fiber array in the input terminal and output terminal of the chip, respectively, and last encapsulating.
Comparing with FTB coupler, PLC splitter shares some obvious advantages: meeting transmission needs of different wavelengths, compact structure, small size, uniform spectroscopic etc. At the same time, the main drawback of the PLC splitter is the complicated production process while the chip monopoly by several companies, as well as the cost disadvantages versus the FBT splitters.

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