How Does EDFA Amplifier Work for Extending DWDM System?

EDFA amplifier is the most common optical amplifier, used for boosting optical signals in optical applications, especially the DWDM systems. It is the key amplification device deployed in the optical system to enhance the signal power, so that the optical transmission distance can be greatly extended. Undoubtedly, the EDFA amplifier is an ideal choice for long-haul DWDM system. But how does it work for extending DWDM system? As shown in the following figure, EDFA amplifier can be placed at the transmitting side of the DWDM link, any intermediate point along the transmission DWDM link and the receiving end of the DWDM link, separately working as booster amplifier (or post-amplifier), in-line amplifier (or optical line amplifier) and pre-amplifier for optimizing the DWDM system reach. Let’s study the related knowledge in details.

What’s EDFA Amplifier?

EDFA amplifier is a kind of optical amplifier that can directly amplify any input optical signal without the need of optical-electrical-optical conversion. It can not only save the cost for long-haul transmission, but also reduce the signal loss and unwanted noise, compared to the traditional optical-electrical-optical amplification. As the fiber attenuation limits the reach of a non-amplified fiber link to about 200 km, EDFA amplifier is an ideal choice for building wide area purely optical networks.

How Does EDFA Amplifier Work?

As mentioned before, EDFA amplifier can be deployed in three places of the DWDM link to make the power compensation, the transmitting side of the link, the intermediate point along the link and the receiving end of the link. If placed at the transmitting side, it can be called as booster optical amplifier or post-amplifier, offering high input power for the wide fiber span. If placed at the intermediate point along the link, you can call it in-line amplifier or optical line amplifier. The optical line amplifier is used for compensating the fiber loss in the transmission link. When you call it pre-amplifier, it must be deployed in the receiving end, for boosting the signal power to the the necessary receiver level. The following will introduce these three different deployments of EDFA amplifier and how does the it work in the three link.

Placed at the Transmitting Side: in this application, we always call EDFA as booster optical amplifier that features high input power, high output power and medium optical gain. It can directly amplify the aggregated optical input signal multiplexed by the DWDM Mux Demux, to achieve DWDM network transmission distance extension. By placing the EDFA amplifier at the transmitting side of the DWDM link, the transmitted signal power can be enhanced to the necessary transmitting level and the optical loss caused by the laser and optical fibers can be also compensated. Hence, the EDFA booster optical amplifier is always deployed when the DWDM Mux Demux attenuates the signal channels.

Placed at the Intermediate Points: as shown in the figure below, the EDFA in-line amplifier can be put at any intermediate point along the long transmission link. This kind of EDFA optical amplifier is designed with low input power, high output power, high optical gain and low noise figure, which are normally deployed every 80-100 km to amplify signals between any two link nodes on the main optical link, with the aim of compensating the loss caused by fiber transmission and other factors. Thereby, the optical signal level can stay above the noise floor.

Placed at the Receiving Side: EDFA optical amplifier operates at the receiving side of the link is also referred to as pre-amplifier, which has the features of medium to low input power, medium output power and medium gain. This optical pre-amplifier put before the receiver end of the DWDM link is to compensate for losses generated by the demultiplexer located near the optical receiver. With the use of pre-amplifier, the optical signal level can be enhanced before the photo detection, hence improving the receive sensitivity for a long-haul fiber DWDM link.

Conclusion

In conclusion, the EDFA optical amplifier can be deployed as booster optical amplifier in the transmitting side of the DWDM link to provide high input signal power for the wide fiber span. It can also work as in-line amplifier at the intermediate point along the link for compensating the fiber loss in the transmission link. What’s more, as the pre-amplifier deployed in the receiving end, it amplifies the signal power to the the necessary receiver level. No matter where the EDFA optical amplifier is deployed in the DWDM link, the signal power can be always enhanced for making a longer DWDM system.

How to Build an Economical Long-haul 500Gbps Metro Network?

Through years of persistent endeavor, experts have already published 40Gbps and 100Gbps solutions to address the need for higher bandwidth, which have been gradually used for bandwidth-hungry applications. In spite of this, the trend for higher bandwidth seems never ending and now 500Gbps solution for Metro network has been also put forward for thousands of kilometers transmission, in order to meet the increasing network requirements. Considering that the deployment cost for 500Gbps Metro network is very high, the following will offer a cost effective 500Gbps solution that utilizes singlemode fiber patch cable, DWDM Mux and Demux and optical amplifier to build the long-haul 500Gbps Metro network.

Singlemode Fiber Patch Cable for 500Gbps Metro Network

As we know, many fiber patch cables are required in the long point-to-point connections, which would cost high. Hence, in order to build an economical long-haul 500Gbps Metro network, it is necessary to take the fiber patch cable cost into account. Which kind of fiber should be used for the long-haul 500Gbps network? Can it save the cost? Is there any solution to save fibers? The following text will seek the answers.

Singlemode fiber patch cable is undoubtedly the best choice for long-haul 500Gbps Metro network. But its cost would takes a certain percentage in the whole network budget. How to solve it? Under this case, using DWDM technology to deploy the 500Gbps network is highly recommendable that requires only one singlemode fiber to transmit multiple signals, allowing for a big cost saving. When it comes to DWDM network, the DWDM Mux and Demux can’t be ignored. It is the most indispensable optical component to multiplex and demultiplex signals with different wavelengths, which make the 500Gbps transmission over one singlemode fiber possible. In order to save fiber cost, let’s learn how to deploy 500Gbps DWDM network over one singlemode fiber patch cable, instead of point-to-point fiber connections.

DWDM Mux and Demux for 500Gbps Metro Network

How to use the DWDM Mux and Demux to deploy a cost effective 500Gbps network? Firstly, we should choose two 40 channels DWDM Mux and Demux and insert the 10G DWDM SFP+ transceivers into the 40 channels. Hence, a total 400Gbps load is achieved. Secondly, utilizing the extra 1310nm or 1550nm port on the DWDM Mux and Demux with the 100G QSFP28 LR4/ER4 transceiver to support a total 100Gbps transmission. Hence, the whole transport 500Gbps (400G + 100G) can be finished. If you only need a 440Gbps network, you can just insert the 40G QSFP+ LR4/ER4 transceiver into the extra port. What should be noted is the wavelength of the 100G or 40G transceiver should be the same to that of the extra port. To better know how does the 500Gbps network work, here offers a figure that illustrated the network design to run such huge network load over a single fiber.

Optical Amplifier for Long 500Gbps Metro Network

Although the singlemode fiber patch cable and DWDM Mux and Demux can address the 500Gbps issue, we still need to use optical amplifiers including semiconductor optical amplifier (SOA) and erbium-doped fiber amplifier (EDFA) to enhance the signal power when the 500Gbps transmission distance is quite long. As shown in the following figure, the semiconductor optical amplifier is deployed in the extra link for boosting the 100G signals, which can extend the transmission up to 60 km. While the erbium-doped fiber amplifier should be deployed in the DWDM transmission link to enhance the 40 10G signals, enabling hundreds of kilometers transmission. Hence, the long 500Gbps Metro network can be finally built.

Conclusion

Due to the high cost for upgrading the current network equipment to higher data rate, it would be be more cost effective to build a long-haul 500Gbps DWDM Metro network with the use of DWDM Mux and Demux and optical amplifier (semiconductor optical amplifier and erbium-doped fiber amplifier). The DWDM Mux and Demux makes the 500Gbps network load possible through a single fiber, while the optical amplifier allows the 500Gbps signals to be transmitted longer. These two DWDM optical components are very critical to deploy the economical long-haul 500Gbps Metro network.

Analysis of A Practical CWDM System Deployment Case

As the need for high capacity increases so fast, the WDM (wave division multiplexing) technology meets with great favor in today’s optical network that can be mainly divided into CWDM (coarse wave division multiplexing) and DWDM (dense wave division multiplexing) technology. Although the CWDM cannot transmit the signals so long as that of DWDM, it costs much less to deploy the WDM system and keeps the scalability to increase the network capacity. For this reason, CWDM technology is much more popular then the DWDM one. In this post, it will simply study the two key components for deploying a CWDM system and analyze one practical CWDM system deploying case for you.

Key Components for Deploying CWDM System

CWDM technology is to multiplex multiple wavelengths for transmitting several kinds of signals through only one fiber, with the aim of solving the capacity-hungry issue. As the CWDM system is more complicated than a common system which consists of much more components, it is necessary to know the key components used for building CWDM system before learning the practical CWDM system deployment case.

CWDM Mux Demux: it is the basic and key component for a CWDM system. It is designed for multiplexing 4, 8 or even 16 different wavelengths to transmit up to 16 kinds of signals as an integrated signal over one fiber at the same time and then demultiplexing the integrated into individual signals. That’s to say, 3, 7 or even 15 virtual fibers are created in the process with much higher capacity. If you are facing the capacity-hungry issue, then the compatible CWDM Mux Demux would be a necessity for you to deploy a higher capacity system.

CWDM OADM: it can be also called CWDM Optical Add Drop Mux. It is mainly used for add and drop (multiplex and demultiplex) channels on both directions in a CWDM system. You can use the Add Drop Mux to add new access points in anywhere of your CWDM system, which has no influence on the other channels.

Practical CWDM System Deployment Case

In this case, singlemode fiber cable or multimode fiber cable are used for connecting five buildings including Sheriff, Courthouse, Admin, Police & Fire Dept, and Public Works, as shown in the following figure. It deploys a simple network in city offices. But now, we should use the singlemode fiber cable to deploy a complete system that should link numerous buildings in the town. In details, the Public Works should connect with Youth & Recreation Center, Library, Immanuel Lutheran School and the Senior Center, both of which have unfiltered Internet. Meanwhile, the Waster Water Treatment Plant is designed to link with Middle School and then connect the Senior Center.

What can we do to meet the requirements? The answer is building a CWDM system. The following figure shows the detailed solution. 8 channel CWDM Mux Demux is used to connect the switch. Since the four buildings Youth & Rec Center, Library, Immanuel and Senior Center should be connected with the Public Works that need unfiltered services, we should put a 4 channel CWDM OADM behind the 8 channel CWDM Mux Demux. Hence, four signals with different wavelengths can be drop and transmitted into these four buildings. On the other hand, to meet the another requirement, we should put a CWDM OADM on Senior Center to serve the Waster Water Treatment Plant.

Conclusion

After learning the practical CWDM system deployment case, do you also want to deploy a CWDM system like this for higher capacity? If yes, the key components like Mux Demux and OADM for building CWDM system are available at FS.COM with good price. Except these two devices, other components for WDM system like EDFA amplifier, dispersion compensation module and WDM Transponder are also available.

Why Do We Need Optical Transponder (O-E-O)?

Nowadays, more and more data centers utilize the WDM technology to gain bigger capacity for various applications, such as, 10G LAN, SONET/SDH, Fiber Channel, etc. Through this method, we can not only reduce the multiple fiber use, carry the signals through only one fiber, but also expand our network capacity. Since there are such benefits from WDM technology, why not use it to deploy our network? At present, there are various kinds of equipment required for WDM system, for instance, WDM Mux Demux, optical fiber amplifier and optical transponder. To build a high performance WDM network, this paper will mainly introduce the optical transponder, an important component in the WDM network, and illustrate why we need optical transponder.

What’s Optical Transponder (O-E-O)?

Optical transponder is an optical component designed for amplifying and shaping signals, and even for converting the wavelength and the pattern of the signals, which is commonly used in optical transmission. It can be also reffered to as WDM converter, OEO converter or WDM transponder. With the use of optical transponder, the optical transmission distance can be much extended and the cost for deploying long transmission can be highly reduced. It is really an cost effective solution for long transmission. Furthermore, it features small and handy shape which is very easy to install. To better know the optical transponder, here offers a kind of 10g transponder that enables SFP+ to XFP, SFP+ to SFP+ or XFP to XFP fiber connections.

Why Do We Need Optical Transponder (O-E-O)?

The optical transponder can be applied in various occasions for different aims. For instance, it can be regarded as optical repeater, signal wavelength converter, transmission mode converter, etc, for optimizing the signal quality, extending the transmission distance, converting the signal wavelength and the transmission mode. Let’s study these common functions of the optical transponder.

Optical Repeater: the optical transponder can act as an optical repeater to amplify the signals, so that transmission distance can be extended. Meanwhile, it can also dejitters and retransmits the degraded signal for optimizing the signal quality. Hence, a smoother, longer transmission can be achieved.

Signal Wavelength Converter: the optical transponder is always used as signal wavelength converter. It can convert an original kind of signals into several kinds with different wavelengths, hence the WDM network connection can be built on the base of a traditional network connection. When the signals pass through the optical transponder, they can be received, converted and transmitted with other kinds of wavelengths. But the signal content will not be changed in the process. To illustrate how the optical transponder works as signal wavelength converter, the following figure shows the signal wavelength conversion from traditional 850 nm, 1310 nm and 1550 nm into DWDM wavelengths in 10G LAN, SONET/SDH, Fiber Channel applications for your reference.

Transmission Mode Converter: we can also use the optical transponder to change the fiber transmission mode, such as, converting multimode into singlemode transmission and duplex into simplex transmission. Here offers a multimode into singlemode convertion design as an example. From the figure, you can learn that the signal is firstly transmitted through multimode fiber. And after passing through the first optical transponder, it can be transmitted through singlemode fiber at lengths 90 km. To extend the transmission distance, the second optical transponder is deployed and the transmission is extended from 90 km to 165 km. Finally, the signal will pass through the third optical transponder and the transmission mode will be converted into multimode again. Thereby a long singlemode transmission up to 165 km can fit with the existing multimode system.

Conclusion

It can’t be denied that the optical transponder plays an important role in our network. It can not only highly extend the transmission distance, but also increase the network capacity by converting the traditional signals into CWDM or DWDM signals to fit with the WDM system. What’s more, it can also change the fiber transmission mode. Except for these common functions, there are still several functions not mentioned, for instance, offering a redundant fiber path for extra protection. Then, why not use the optical transponder to optimize our network?