Category: Fiber Transceivers

Optical transceivers, Active Optic Cables, data center switches, and cable management in data centers.

What is DWDM and Why is it Important?

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

It has been almost 20 years since DWDM came on the scene with Ciena’s introduction of a 16 channel system in March of 1996, and in the last two decades it has revolutionized the transmission of information over long distances.  DWDM is so ubiquitous that we often forget that there was a time when it did not exist and when accessing information from the other side of the globe was expensive and slow.  Now we think nothing of downloading a movie or placing an IP call across oceans and continents.  Current systems typically have 96 channels per optical fiber, each of which can run at 100Gbps, compared to the 2.5Gbps per channel in the initial systems.  All of this got me thinking about how it often takes two innovations coupled together to make a revolution.  Personal computers did not revolutionize office life until they were coupled with laser printers.  Similarly, the benefits of DWDM were enormous because of erbium doped fiber amplifiers (EDFAs).
DWDM stands for Dense Wavelength Division Multiplexing, which is a complex way of saying that, since photons do not interact with one another (at least not much) different signals on different wavelengths of light can be combined onto a single fiber, transmitted to the other end, separated and detected independently, thus increasing the carrying capacity of the fiber by the number of channels present.  In fact non-Dense, plain old WDM, had been in use for some time with 2, 3 or 4 channels in specialized circumstances.  There was nothing particularly difficult about building a basic DWDM system.  The technology initially used to combine and separate the wavelengths was thin film interference filters which had been developed to a high degree in the 19th Century.  (Now a ’days photonic integrated circuits called Arrayed Waveguide Gratings, or AWGs are used to perform this function.)  But until the advent of EDFAs there was not much benefit to be had from DWDM.
Fiber optic data transmission began in the 1970s with the discovery that certain glasses had very low optical loss in the near infrared spectral region, and that these glasses could be formed into fibers which would guide the light from one end to the other, keeping it confined and delivering it intact, although reduced by loss and dispersion.  With much development of fibers, lasers and detectors, systems were built which could transmit optical information for 80km before it was necessary to “regenerate” the signal.  Regeneration involved detecting the light, using an electronic digital circuit to reconstruct the information and then retransmitting it on another laser.  80km was much farther than the current “line of sight” microwave transmission systems could go, and fiber optic transmission was adopted on a wide scale.  Although 80 km was a significant improvement, it still meant a lot of regeneration circuits would be needed between LA and New York.  With one regeneration circuit needed per channel every 80 km, regeneration became the limiting factor in optical transmission and DWDM was not very practicable.  The then expensive filters would have to be used every 80 km to separate the light for each channel before regeneration and to recombine the channels after regeneration.
Since full regeneration was expensive, researchers began to look for other ways to extend the reach of an optical fiber transmission system.  In the late 1980s Erbuim Doped Fiber Amplifers (EDFAs) came on the scene.  EDFAs consisted of optical fiber doped with Erbium atoms which, when pumped with a laser of a different wavelength, created a gain medium which would amplify light in a band near the 1550nm wavelength.  EDFAs allowed amplification of the optical signals in fibers which could counter the effects of optical loss, but could not correct for the effects of dispersion and other impairments.  As a matter of fact, EDFAs generate amplified spontaneous emission (ASE) noise and could cause fiber nonlinearity distortions over a long transmission distance.  So EDFAs did not eliminate the need for regeneration completely, but allowed the signals to go many 80 km hops before regeneration was needed.  Since EDFAs were cheaper than full regeneration, systems were quickly designed which used 1550nm lasers instead of the then prevailing 1300nm.
Then came the “ah ha” moment.  Since EDFAs just replicated the photons coming in and sent out more photons of the same wavelength, two or more channels could be amplified in the same EDFA without crosstalk.  With DWDM one EDFA could amplify all of the channels in a fiber at once, provided they fit within the region of EDFA gain.  DWDM then allowed the multiple use of not only the fiber but also the amplifiers.  Instead of one regeneration circuit for every channel, there was now one EDFA for each fiber.  A single fiber and a chain of one amplifier every 40~100 km could support 96 different data streams. Regenerators are still needed today, every 1,200~3,500km, when the accumulated EDFA ASE noise exceeds a threshold that a digital signal processor and error correction codec can handle.
Of course, since the gain region of the EDFA was limited to about 40 nm of spectra width, great emphasis was placed on fitting the different optical wavelengths as close together as possible.  Current systems place channels 50GHz, or approximately 0.4 nm, apart, and hero experiments have done much more.
In parallel, new technologies have increased the bandwidth per channel to 100 Gbps using coherent techniques that we have discussed in other blog posts.  So a single fiber that in the early 1990s would have carried 2.5Gbps of information, now can carry almost 10 Terabits/sec of information, and we can watch movies from the other side of the globe.

HOW DOES FIBER-OPTIC INTERNET COMPARE WITH THE COMPETITION?

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

Because of the cost of installation and natural resistance to change, many businesses and individuals are hesitant to pursue a Fiber-Optic connection. This decision is perfectly rational when it comes to a home environment: if you are happy with your current connection, then why change? When it comes to commercial use, however, the stakes are a bit higher. Your competition may already be utilizing this technology of the future, whether you have invested in it or not. And the benefits which Fiber-Optics offer are undeniable.
Let’s take a look at what sets fiber optic internet apart from alternative internet options — and why such a connection may be a smart investment for your business to make.
Dial-Up Internet
Though its use is now mostly limited to extremely rural areas and the homes of the incredibly stubborn, dial-up does still exist, and this method continues delivering slow-speed internet using telephone lines.
Practically the only advantage of dial-up is that it is available pretty much everywhere — its disadvantages include being infuriatingly slow and blocking your telephone line!
Digital Subscriber Lines
Part of the reason why we bothered mentioning dial-up (aside from it being a good example of how foolish over-resistance to change can be) is the fact that DSL connections actually operate in a very similar manner. These options also use telephone lines — the only difference is that they do so in a manner which does not impede phone calls, and they deliver more modern speeds.
The main advantages of DSL connections? They offer consistently decent speeds, and Digital Subscriber Line connections tend to be reasonably affordable. The disadvantages? DSL is slower than most of the options we will discuss next — and its speed and reliability both depend upon your distance to the central office of your DSL provider.
Cable Broadband
One of the first widely-available internet options to not rely upon telephone lines, cable broadband shares (as you might imagine) the same infrastructure used to deliver cable television to homes and businesses around the world.
The second-fastest option on the market (next to Fiber Optic connections) cable broadband suffers from two main drawbacks. It tends to be rather expensive, and it tends to slow down during peak internet/cable usage hours.
Satellite
We mentioned earlier that internet options can sometimes be limited in remote areas — and one useful solution (and merciful alternative to dial up) that has been developed in recent years is satellite internet.
The downside of this method? Satellite connections are slower and more expensive than every other modern broadband option. The upside, of course, is that at least it’s not dial-up!
Fiber
So, now that we have presented all the major alternatives to fiber optic internet service, let’s talk about what makes Fiber Optic internet special. First and foremost, it is worth point out that the technology that makes these networks possible is truly incredible — utilizing ultra-thin glass cables that literally transmit data using light!
Of course, businesses aren’t investing in fiber optic internet simply because its hardware is impressive. Fiber Optic offers, by far, the fastest and most modern internet connection available. Download/upload speeds over 50 times faster than even cable connections, improved cybersecurity, more reliability, and the potential to offer a lower lifetime cost than other alternatives are just a few of biggest advantages to Fiber Optic connections.

Why true full fibre is the only future for MDU property

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

We believe passionately that infrastructure built using fibre optic cable technology is the only way to deliver the growing capacity and speeds that the market demands. So what exactly is a fibre optic cable and why is it superior?
The history of fibre optic cables for telecommunications stretches as far back to the early days of the telephone. In 1880 Alexander Graham Bell created a very early precursor to fibre-optic communications, the Photophone. The device allowed for the transmission of sound on a beam of light, however, it would not prove practical until advances in laser and optical fibre technologies. It wasn’t until the mid 1970’s that the first optical fibre cables were produced capable of delivering long distance communication, but costs remained high and adoption low. The growth of the internet and the demand for voice and data traffic demonstrated the need for new more capacity and higher speeds were needed. This revolution really kick started the demand for the technology.
Historically most telecommunications infrastructure in the UK has relied on copper cables delivered to a property either underground or by overhead pole. This legacy network has been upgraded in recent years via schemes such as Fibre to the Cabinet (FTTC) and Fibre to the Home (FTTH). However these methods continue to use copper cabling either from the cabinet to the property or throughout the property itself. This method seriously compromises the gains made by using fibre throughout the rest of the journey, meaning the network is slower and has less capacity than if fibre had been used throughout.
PCCW Global likes to do things differently. The growing demand for MDU property (apartments) provides the perfect opportunity to deliver True Full Fibre to these customers. The fibre cable doesn’t stop when it reaches a cabinet or the building itself but instead continues to every apartment in that building. This forward thinking approach means decades will pass before any cabling upgrades will need to be made. Today commercially, speeds of 1Gbps are possible but 10Gbps and beyond are not far away.
This super capacity, high speed, True Full Fibre infrastructure is also the perfect foundation on which to add other smart technology to a building. We’re leading the way in increasing compliance and security and delivering operating cost reductions to building owners and managers as well as improving the experience for residents.

Why Choose A Fiber Optic Computer Network?

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

Before we even go there—you may already be wondering what a fiber optic cable is. Chances are you’ve heard the term before. But what is it?
Fiber optics refer to a method of transmitting information and data through pulses of light along glass or plastic fibers to a receiver. This method is far more efficient and can transmit large amounts of information very quickly—much more than your average copper wire. Fiber optics also cut down on electromagnetic interference, establishing a stronger, more reliable connection.
However, high-speed internet and long-distance calls aren’t the only mediums seeing upgrades; computer systems are also getting ‘hooked up.’ BlackBox.com brings the benefits:
Greater Bandwidth
Fiber optics service higher bandwidth than copper wires—and can even deliver performance of up to 10 Gbps—that’s tens of billions of “bits” per second! Imagine the magnitude and speed of data transmission that could serve you and your business.
Speed and Distance
Fiber optic signals are able to travel a thousand feet and upward of 25 miles using a single-mode cable. Distance and speed may vary depending on a given cable, however, they are much greater than that of copper. And because fiber optics carry light, little to no signal is lost during transmission of data.
Security
Not only are fiber optic cables faster and more efficient, but they are extremely difficult to tap or tamper with, ensuring higher security for your network. When a fiber cable is cut or tapped, it will leak light, which will cause the system to completely shut down, so you will know it firsthand if something is suspicious.
Immunity and Reliability
Fiber provides extremely reliable data transmission. It’s completely immune to many environmental factors that affect copper cable. The core is made of glass, which is an insulator, so no electric current can flow through. It’s immune to electrometric interference and radio-frequency interference (EMI/RFI), crosstalk, impedance problems, and more. You can run fiber cable next to industrial equipment without worry. Fiber is also less susceptible to temperature fluctuations than copper and can be submerged in water.
A standout feature of fiber optics is resistance to environmental factors. A fiber optic cable can run underwater or near large industrial equipment without interference or hazard. Because the cables are mostly made of glass fibers, no electrical currents can be conducted. Optics are also immune to EMI and RFI interference—providing you with the most reliable connection possible.
Design
Fiber is lightweight, thin, and more durable than copper cable. To get higher speeds using copper cable, you need to use a higher grade of cable, which typically have larger outside diameters, weigh more, and take up more space in cable trays. With fiber cable, there is very little different in diameter or weight. Plus, fiber optic cable has pulling specifications that are up to 10 times greater than copper cable, depending on the specific cable. Its small size makes it easier to handle, and it takes up much less space in cabling ducts. And, fiber is easier to test than copper cable.
Cost
Fiber optics are also cheaper to produce and to purchase, compared to traditional copper wires. The overall price for cables, components, and hardware has declined over the years as its popularity has been on the incline. What more do you need to consider?

What’s the Difference Between Fiber Optic Cabling and Others?

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

If you’re looking at high-speed internet options and find that fiber optic cable is available in your area, you may not understand the differences. fiber optic cablingAfter all, the cables look similar, and they install similarly from the lay-person’s perspective. Generally, that is where the similarities end.
Inside the Cable
Standard cable is known as coaxial cable. If you looked inside, you will find a central, copper core surrounded by insulation wrapped in twisted copper or metal wires before being covered in a plastic jacket. This is the same cable that comes into your house if you have cable television. It’s easy to run and shorten and connect to outlets and televisions. The cable is available in many different lengths and is nearly ubiquitous…plenty of homes have at least one coaxial cable sitting around.
Fiber optic cable, on the other hand, is built a bit differently, and high density fiber optic cables are very complex inside and can transmit a lot of data. High density fiber optic cables won’t come into your home, but if you have fiber optic internet, your home will connect to one of these cables. Fortunately, they work on the same principle…high density just has more protected cables inside, like lanes in a freeway.
The central core of a fiber optic cable is made of tiny strands of glass or plastic known as optical fibers. A single cable can have a few strands or as many as several hundred. Directly coating the strands is something known as cladding…which directs the signal down the strand to increase the distance of cabling that can be used before a repeater (a device that receives the signal on one end and retransmits it on the other to prevent data loss) is required. Then, just like coaxial cable, it contains insulation and a protective jacket.
The difference between these two cables is that one transmits an electromagnetic signal (coaxial) and one transmits light (generally LEDs or lasers).
What Does This Mean for the Consumer?
While standard, coaxial cable internet is available in nearly every urban and suburban area, fiber optics are just rolling out. It can be difficult to find a fiber optic internet provider if your city’s infrastructure or local cable provider hasn’t invested to have fiber optic cabling run to near your house.
Because fiber optics requires less repeaters and other equipment, and cost less to maintain, fiber optic cabling tends to cost less to the consumer than traditional cable internet does. Fiber optics are also much faster than traditional high speed internet because the optical threads have the capacity for greater bandwidth, and fiber optic cable weighs less because it requires less insulation and jacketing.
You can also feel good that fiber optics are more eco-friendly than traditional coaxial cables. Not only does it generate less heat at data centers to use fiber optic cable, but fiber optic cables require less insulation and jacketing, which often involve heavy metals, which can leach into the environment.
Fiber optics are also more secure than traditional coaxial cables. It’s more difficult to tap fiber optic cables because it requires special tools and receivers. Attempting to tap into the system is more likely to just disrupt the system, providing no benefit. Also important to note that information transmitted via pulses of light do not transmit electricity, which makes it harder to “listen” and intercept data from fiber optic cabling systems.

How does the POE switch apply to the Security Network monitoring field?

PoE switch performance is more advanced and sophisticated, the appearance is more and more handsome. With the development of network monitoring, PoE switch applications are more and more common, so a lot of information about PoE switch can be found on the Internet.
So, there are a lot of articles on the PoE switches and network monitoring, and some people say PoE switches to promote the development of network monitoring, and some others say that network monitoring to promote the development of PoE switches, then in the end who promoted who?
Referred to the surveillance camera, is really all over the city streets in various places, as long as you live in the city, everywhere you can see his shadow. Although sometimes very annoying, but have to say that a variety of monitoring measures do put an end to a lot of violations of the crime, but also can provide a basis for the incident.
With the planning of “Safe China”, “Intelligent City” and other projects, as well as the increased safety awareness of people, the scale of video surveillance installation and the radiation area are getting bigger and larger, the project scope of which involves the whole city, the camera reaches tens of thousands. However, not every place is suitable for the installation of network cameras, that is to say, the installation of network video surveillance equipment is constrained by the environment, which to some extent restricts its development.
We know that all devices need the power to work, and surveillance cameras are no exception. In the traditional monitoring system, usually using mains power or centralized power supply, and in network monitoring, these modes of power supply sometimes can not meet the needs. Because it is network monitoring, of course, a need of network cable, if you want to supply additional cable, especially in some inconvenient power supply environment, the construction becomes extremely complex and troublesome, at this time, have to redeploy the camera installation location, this also lost the significance of monitoring.
How to solve this difficulty? Thus, the technology of PoE, which can be powered by Ethernet, has received wide attention and attention. Through the technology of PoE Power supply, the power signal can be added to the network cable, which is transmitted to the other end of the equipment which needs to be powered. This can be an excellent solution to network monitoring power supply problems, as long as the power and data through a cable can be completed transmission, not only solve the power supply problems, and make the project easy to do, as long as the network cable to the place, you can make equipment to obtain a steady supply of electricity.
In order to make PoE better applicated in the security network monitoring, PoE switches can be quickly promoted. Commonly used PoE power supply equipment includes PoE module and PoE switches, that is the most common used.
PoE switch is also a kind of switch, the biggest difference between ordinary switches is that it can be a power supply, not only has the ability to transfer data. In other words, the PoE switch can not only transmit data can also power supply, which is also appropriate for the network monitoring needs, because the surveillance cameras need both power supply, there is a need to collect the monitoring data sent out. With the PoE switch, the surveillance camera can be installed at any optimal point without the need for environmental and power access restrictions. PoE switch is also favored by many system integrators because of its high performance, simple use, easy management, convenient networking and low construction cost.
The PoE switch that we often refer to is the standard PoE switch, which supports IEEE802.3AF/T power supply standards, but there are also non-standard PoE switches on the market. Non-standard PoE switch Although the price is relatively cheap, but because of the existence of the hidden dangers of the front-end cameras, we recommend that you choose carefully.
Conclusion
What is the relationship between network monitoring and PoE switch? Our view is that they are two different concepts, but can promote each other, but it is necessary to note that network monitoring is not a PoE switch can still be done, and the PoE switch is not network monitoring, its application will be greatly compromised. It can be understood that the PoE switch is a transmission power supply device for network monitoring.PoE switch performance is more advanced and sophisticated, the appearance is more and more handsome. With the development of network monitoring, PoE switch applications are more and more common, so a lot of information about PoE switch can be found on the Internet.
So, there are a lot of articles on the PoE switches and network monitoring, and some people say PoE switches to promote the development of network monitoring, and some others say that network monitoring to promote the development of PoE switches, then in the end who promoted who?
Referred to the surveillance camera, is really all over the city streets in various places, as long as you live in the city, everywhere you can see his shadow. Although sometimes very annoying, but have to say that a variety of monitoring measures do put an end to a lot of violations of the crime, but also can provide a basis for the incident.
With the planning of “Safe China”, “Intelligent City” and other projects, as well as the increased safety awareness of people, the scale of video surveillance installation and the radiation area are getting bigger and larger, the project scope of which involves the whole city, the camera reaches tens of thousands. However, not every place is suitable for the installation of network cameras, that is to say, the installation of network video surveillance equipment is constrained by the environment, which to some extent restricts its development.
We know that all devices need the power to work, and surveillance cameras are no exception. In the traditional monitoring system, usually using mains power or centralized power supply, and in network monitoring, these modes of power supply sometimes can not meet the needs. Because it is network monitoring, of course, a need of network cable, if you want to supply additional cable, especially in some inconvenient power supply environment, the construction becomes extremely complex and troublesome, at this time, have to redeploy the camera installation location, this also lost the significance of monitoring.
How to solve this difficulty? Thus, the technology of PoE, which can be powered by Ethernet, has received wide attention and attention. Through the technology of PoE Power supply, the power signal can be added to the network cable, which is transmitted to the other end of the equipment which needs to be powered. This can be an excellent solution to network monitoring power supply problems, as long as the power and data through a cable can be completed transmission, not only solve the power supply problems, and make the project easy to do, as long as the network cable to the place, you can make equipment to obtain a steady supply of electricity.
In order to make PoE better applicated in the security network monitoring, PoE switches can be quickly promoted. Commonly used PoE power supply equipment includes PoE module and PoE switches, that is the most common used.
PoE switch is also a kind of switch, the biggest difference between ordinary switches is that it can be a power supply, not only has the ability to transfer data. In other words, the PoE switch can not only transmit data can also power supply, which is also appropriate for the network monitoring needs, because the surveillance cameras need both power supply, there is a need to collect the monitoring data sent out. With the PoE switch, the surveillance camera can be installed at any optimal point without the need for environmental and power access restrictions. PoE switch is also favored by many system integrators because of its high performance, simple use, easy management, convenient networking and low construction cost.
The PoE switch that we often refer to is the standard PoE switch, which supports IEEE802.3AF/T power supply standards, but there are also non-standard PoE switches on the market. Non-standard PoE switch Although the price is relatively cheap, but because of the existence of the hidden dangers of the front-end cameras, we recommend that you choose carefully.
Conclusion
What is the relationship between network monitoring and PoE switch? Our view is that they are two different concepts, but can promote each other, but it is necessary to note that network monitoring is not a PoE switch can still be done, and the PoE switch is not network monitoring, its application will be greatly compromised. It can be understood that the PoE switch is a transmission power supply device for network monitoring.