Category: Fiber Transceivers

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

Know the Difference between CWDM and DWDM

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

A WDM (Wavelength Division Multiplexing) is a system that uses a multiplexing (at the transmitter) and a demultiplexer (at the receiver) for the completion of the process and transmission of the signals.
The WDM is divided into three types (WDM, CWDM and DWDM) on the basis of wavelength difference among the three. The article discusses the main differences among CWDM and DWDM.
CWDM stands for Coarse Wavelength Division Multiplexing, and DWDM is the acronym for Dense Wavelength Division Multiplexing. Whether DWDM or CWDM, both are the types of WDM mechanism and have an array of differencess.
Let’s get acquainted with the chief difference between CWDM and DWDM:
The Coarse WDM has less than 8 active wavelengths per optical fiber whereas the DWDM has more than 8 active wavelengths per optical fiber.
The CWDM has lower capacity strength and hence is low in costs; conversely the DWDM possesses high capacity –this leads to an augmented price which is worth its qualities.
When it comes to the difference between the distance of the two, the CWDM has short range communication because the wavelength is not amplified, and DWDM has long range communication.
CWDM Mux and Demux systems are developed to be used in multiplexing multiple CWDM channels into one or two fibers.
Another major difference is that DWDM systems are made for longer haul transmittal, by keeping the wavelengths closely packed. Also, a DWDM device can transmit more data over long distances and to a significantly larger run of cable with lesser interference than a comparable CWDM system which has a shorter haul transmittal.
Furthermore, the Dense Wavelength Division Multiplying systems are capable to fit more than forty different data streams in the amount akin to that of fiber used for two data streams in a CWDM system.
Apart from all the difference there is one more and that is wavelength drift is possible in CWDM, but when it comes to the DWDM –precision lasers are needed to keep channels on the target.
Beyond being different from each other –these systems play different roles in the effective transfer of the signals, and thereby both are important enough.

Know All about the DWDM and its Utilization and Significance

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

WDM is the abbreviation for Wavelength Division Multiplexing, it is a popular technology used in currently fiber optic communication systems. By WDM, we can split a number of optical lights in an optic fiber into a number of discrete wavelengths. Each wavelength can be considered to an independent channel running at a special data rate of 5Gbit/s, 10Gbit/s, 40Gbit/s or even 100Gbit/s. If the light in the fiber is split into 16 channels, and each channel running at 40Gbit/s, the total data transmission rate will be 640Gbit/s. In effect, this means maximized use of a single fiber optic to transmit and receive a large number of signals, minimizing costs for telecom companies. WDM technology is also the working principle of optical amplifiers, multiplexers, and demultiplexers. Next, I will give a separate introduction about WDM/CWDM/DWDM technologies.
DWDM and Conventional WDM
DWDM stands for Dense Wavelength Division Multiplexing. It means the divided wavelength channels are very narrow and close to each other. It is widely used for the 1550nm band so as to leverage the capabilities of EDFA (Erbium Doped Fiber Amplifiers), which are effective for wavelengths between approximately 1525-1565 nm (C band), or 1570-1610 nm (L band). Conventional WDM Conventional WDM uses the 3rd transmission window with a wavelength of 1550nm, accommodating up to 8 channels. DWDM basically is the same however along with the higher density channel. An ultra-dense WDM is capable enough to work at the spacing of just 12.5 GHz, allowing some more channels.
CWDM
CWDM refer to Course wavelength division multiplexing, in CWDM technology, it shared the fact that the choice of channel spacing and frequency stability which is the EDFA could not use. There is an increase in channel space; it cannot be used in EDFA. One basic meaning for the CWDM is two (or more) signals are multiplexed onto the single fiber, where one signal was into the 1550 nm band, and then another one into the 1310 nm band. Currently, there is an increase in the channel space. This means the need for less sophisticated and less costly transceivers devices. Working into the similar window of 1550 nm as well as making the utilization of OH-free silica fibers, the maximum efficiencies are gained into the channels 31, 49, 51, 53, 55, 57, 59 and 61 utilizing the wavelengths from 1270 nm through 1610 nm along with the channel spacing of 20 nm. CWDM devices are commonly used in fewer precision optics and lower cost, un-cooled lasers with lower maintenance requirements? Compared with DWDM and Conventional WDM, CWDM is much more cost-effective and less power consumption of laser devices.
Currently, kinds of related CWDM MUX/DEMUX or DWDM MUX/DEMUX or optical amplifiers are available in the market. Networking solutions provider is the right ones to ask for guidance for use of CWDM, DWDM or WDM technology. Choosing the right one means the correct, integrated devices for error-free high-speed data transmission over fiber optic networks. Cost-effective CWDM solutions with optimized performance and built-in expansion capabilities are available from a host of online network solution companies. Choosing the most experienced one to get the reliable CWDM solution is critical.

3×1 Multimode Fiber High Power Combiners (Power per Multimode Input: 25W)

FM SKU#:SKU00210G2
Model#:FM-PC-3X1-25W
MFG PART#:

3 × 1 Multimode Pump Combiners

3 × 1 Multimode Pump Combiners can be used for high power fiber laser and fiber amplifier. These devices can be used to combine the power from several multimode laser diodes with high coupling efficiency. We could provide 4X1, 7X1 Multimode Pump Combiners, also the configurations such as number of input fibers and different fiber types can be fully customized based upon request. If you need, please contact sales@fiber-mart.com.

 

Applications

    • High Power All-Fiber Lasers
    • High Power Fiber Amplifiers
    • Medical, industrial, defense

 

Features

    • High Signal Transfer Efficiency
    • High Pump Efficiency
    • Wavelength Insensitive>
    • Custom Configurations Available

 

Product specifications

    • Pump Operating Wavelength: 800-1000nm
    • Configuration: 1XN
    • Pump Fiber (core/clad, NA): 105/125, 0.15
    • Output Fiber (core/clad, NA): 200/240, 0.22
    • Power per Multimode Input: 25W
    • Fiber length: 0.8m
    • Package Dimension: Φ3.5xL40mm or 65x12x7.5mm for high power

 

Dimensional Drawing


 

Specification

Configuration Pumpfiber Ouputfiber Min.PumpEfficiency Max.PowerHandling Package
2×1 105/1250.15 105/1250.22 90% 50W/leg P32
3×1 105/1250.15 200/2200.22 95% 50W/leg P32
3×1 105/1250.22 200/2200.22 93% 50W/leg P32
4×1 105/1250.15 200/2200.22 95% 50W/leg P32
4×1 105/1250.22 220/2420.22 90% 50W/leg P32
4×1 200/2200.22 400/4400.22 90% 150W/leg P32
7×1 105/1250.15 200/2200.22 90% 80W/leg P32
7×1 105/1250.15 x/125DC 93% 80W/leg P32
7×1 105/1250.22 x/125DC 90% 80W/leg P32
7×1 200/2200.22 x/400DCF 96% 200W/leg P32,P33
7×1 220/2420.22 x/400DCF 96% 200W/leg P32,P33
19×1 105/1250.15 400/4400.22 90% 50W/leg P32,P33
19×1 105/1250.15 x/200DC 95% 50W/leg P32,P33
19×1 105/1250.22 x/250DC 95% 50W/leg P32,P33
  • Remark: x=core dia., above are popular types, total >50 N×1 types are available.

PM(1+1)×1 Pump and Signal Combiner

FM SKU#:SKU00226G2
Model#:FM-PC-PM(1+1)x1-A
MFG PART#:

PM(1+1)x1 PM Pump and Signal Combiner

PM(1+1)x1 PM Pump and Signal Combiner feature high power handling, low loss and high coupling efficiency from multimode pump fibers to PM signal fiber. This PM (1+1)×1 multi-mode fiber combiner combines 1 pump lasers and one PM signal channel into one double cladding PM output fiber. Fiber type can be customized. If you need more details, please contact at sales@fiber-mart.com.

 

Applications

 

  • High Signal Transfer Efficiency
  • High Power Fiber Amplifiers
  • Medical, industrial, defense

 

 

Features

 

  • Signal Operating Wavelength:
  • High Signal Transfer Efficiency
  • High PER
  • Wavelength Insensitive
  • Custom Configurations Available

 

 

Product specifications

 

  • Signal Operating Wavelength:1530-1575 nm
  • Pump Operating Wavelength: 800-1000nm
  • Configuration:PM(1+1)x1
  • Pump Fiber (core/clad, NA):105 /125 μm 0.15 or 0.22NA
  • Signal Input Fiber (core/clad, NA): PM 8/125um GDF 0.14/0.46NA
  • Output Fiber (core/clad, NA):PM 8/125um GDF 0.14/0.46NA
  • Total Input Power:14W/50W
  • Fiber length: 0.8m
  • Package Dimension: Ø4.0×60mm(14W) or 70×13×8mm(50W)

 

 

Parameter PM(1+1) ×1 PM(1+1) ×1
Signal Operating Wavelength 1530-1575 nm 1000-1200nm
Pump Operating Wavelength 800-1000 nm 800-1000 nm
Pump Fiber core/clad diameter NA 105 /125 μm; 0.15 or 0.22 105 /125 μm; 0.15 or 0.22
Signal Input Fiber core/clad diameter NA PM8/125umGDF 0.14/0.46 PM10/125umGDF 0.14/0.46
Output Fiber core/clad diameter NA PM8/125um GDF 0.14/0.46 PM10/125um GDF 0.14/0.46
Total power 14/50W 14W/50W
Maximum Signal Insertion Loss <0.5dB <0.5dB
ER (dB) ≥18 dB ≥18 dB
Pump Efficiency ≥90% ≥90%
Mechanical Specifications
Package Ø4.0×60mm(14W) or 70×13×8mm(50W) Ø4.0×60mm(14W) or 70×13×8mm(50W)
Fiber Length >800mm >800mm

Testing Fiber Optic Splitters Or Other Passive Devices

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fiber optic splitter is a device that splits the fiber optic light into several parts by a certain ratio. For example, when a beam of fiber optic light transmitted from a 1X4 equal ratio splitter, it will be divided into 4-fiber optic light by equal ratio that is each beam is 1/4 or 25% of the original source one. A Optical Splitter is different from WDM. WDM can divide the different wavelength fiber optic light into different channels. fiber optic splitter divide the light power and send it to different channels.
Most Splitters available in 900µm loose tube and 250µm bare fiber. 1×2 and 2×2 couplers come standard with a protective metal sleeve to cover the split. Higher output counts are built with a box to protect the splitting components.
Testing a coupler or splitter (both names are used for the same device) or other passive fiber optic devices like switches is little different from testing a patchcord or cable plant using the two industry standard tests, OFSTP-14 for double-ended loss (connectors on both ends) or FOTP-171 for single-ended testing.
First we should define what these passive devices are. An optical coupler is a passive device that can split or combine signals in optical fibers. They are named by the number of inputs and outputs, so a splitter with one input and 2 outputs is a 1×2 fiber splitter, and a PON splitter with one input and 32 outputs is 1×32 splitter. Some PON splitters have two inputs so it would be a 2X32. Here is a table of typical losses for splitters.
Important Note! Mode Conditioning can be very important to testing couplers. Some of the ways they are manufactured make them very sensitive to mode conditioning, especially multimode but even singlemode couplers. Singlemode couplers should always be tested with a small loop in the launch cable (tied down so it does not change and set the 0dB reference with the loop.) Multimode couplers should be mode conditioned by a mandrel wrap or similar to ensure consistency.
Let’s start with the simplest type. Shown below is a simple 1X2 splitter with one input and two outputs. Basically, in one direction it splits the signal into 2 parts to couple to two fibers. If the split is equal, each fiber will carry a signal that is 3dB less than the input (3dB being a factor of two) plus some excess loss in the coupler and perhaps the connectors on the splitter module. Going the other direction, signals in either fiber will be combined into the one fiber on the other side. The loss is this direction is a function of how the coupler is made. Some couplers are made by twisting two fibers together and fusing them in high heat, so the coupler is really a 2X2 coupler in which case the loss is the same (3dB plus excess loss) in either direction. Some splitters use optical integrated components, so they can be true splitters and the loss in each direction may different.
So for this simple 1X2 splitter, how do we test it? Simply follow the same directions for a double-ended loss test. Attach a launch reference cable to the test source of the proper wavelength (some splitters are wavelength dependent), calibrate the output of the launch cable with the meter to set the 0dB reference, attach to the source launch to the splitter, attach a receive launch cable to the output and the meter and measure loss. What you are measuring is the loss of the splitter due to the split ratio, excess loss from the manufacturing process used to make the splitter and the input and output connectors. So the loss you measure is the loss you can expect when you plug the splitter into a cable plant.
To test the loss to the second port, simply move the receive cable to the other port and read the loss from the meter. This same method works with typical PON splitters that are 1 input and 32 outputs. Set the source up on the input and use the meter and reference cable to test each output port in turn.
What about the other direction from all the output ports? (In PON terms, we call that upstream and the other way from the 1 to 32 ports direction downstream.) Simply reverse the direction of the test. If you are tesing a 1X2 splitter, there is just one other port to test, but with a 1X32, you have to move the source 32 times and record the results on the meter.
What about multiple input and outputs, for example a 2X2 coupler? You would need to test from one input port to the two outputs, then from the other input port to each of the two outputs. This involves a lot of data sometimes but it needs to be tested.
There are other tests that can be performed, including wavelength variations (test at several wavelengths), variations among outputs (compare outputs) and even crosstalk (put a signal on one output and look for signal on other outputs.)
Once installed, the splitter simply becomes one source of loss in the cable plant and is tested as part of that cable plant loss for insertion loss testing. Testing splitters with an OTDR is not the same in each direction.
Other Passive Devices
There are other passive devices that require testing, but the test methods are similar.
Fiber optic switches are devices that can switch an input to one of several outputs under electronic control. Test as you would the splitter as shown above. Switches may be designed for use in only one direction, so check the device specifications to ensure you test in the proper direction. Switches may also need testing for consistency after multiple switch cycles and crosstalk.
Attenuators are used to reduce signal levels at the receiver to prevent overloading the receiver. There is a page on using attenuators that you should read. If you need to test an attenuator alone, not part of a system, use the test for splitters above by using the attenuator to connect the launch and receive cables to see if the loss is as expected.
Wavelength-division multiplexers can be tricky to test because they require sources at a precise wavelenth and spectral width, but otherwise the test procedures are similar to other passive components.
Fiber optic couplers or splitters are available in a wide range of styles and sizes to split or combine light with minimal loss. All couplers are manufactured using a very simple proprietary process that produces reliable, low-cost devices. They are physically rugged and insensitive to operating temperatures. Couplers can be fabricated in custom fiber lengths and/or with terminations of any type.

Commonly Utilized Multimode Pump Combiners

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

Multimode combiners can be utilized to consolidate the power from a variety of multimode laser diodes, with a signal feed (which is not essential), into a solitary, double or triple clad fiber output. These combiners are intended to address fiber optic applications utilized as a part of different markets, including telecom, research, industrial and medical.
There are several manufacturers of multimode pump combiner in China and their procedures are able to do high adaptability in the designing that leads to a large number of various fiber configurations. Most configurations are accessible with various power levels and with various packaging availabilities, made it suitable for your application whether you work with lower Watts or up to levels of multi-kW. Manufacturers work considering the design you will provide them according to your requirement on the basis of that they offer sufficient solutions with pump input ports that are coordinated with the pigtail fibers of all laser diodes that are available in the market.
End pump multimode combiner, this kind of multimode pump combiner is highly efficient in handling maximum power. These are especially enhanced to perform as co-pumped designs where you require the highest pump power. End Pump Multimode Combiners highlight extraordinary optical execution. These small devices can be utilized to consolidate the power from a few multimode laser diodes with a discretionary signal feed into a double or triple clad fiber output. Coordinated to the particular pump fiber you are utilizing, one can give a combiner that will fit your laser diode provider.
Some high power packages let the manufacturers to accomplish multi-kW control levels in a wide assortment of fiber setups. Their unparalleled comprehension of light spread in the fiber enables them to enhance the designs and limit transmission loss while protecting the transfer of brightness.
Side pump, multimode pump and signal combiners include excellent optical execution. These devices can be utilized to join the power from a few multimode laser diodes with a signal feed into a double clad fiber (DCF). In Side Pump combiners, the input and output ports are the same consistent fiber, giving excellent signal transmission execution and low signal debasement.
They are offered from 1 up to 6 pump input ports, in a wide assortment of fiber setups. Manufacturers provide these in low, medium or high-control packages.
Direct pump multimode combiners are made of glass at all and provide high brightness output; they are usually optimized for direct pumping applications or to be utilized in ‘combiner tree’ architectures. These devices can also be utilized for the same purpose that other two are utilized. They can meet an extensive variety of power handling prerequisites and a huge determination of input/output fiber composes.
These “all glass” or huge output center Multimode Combiners come in some powerful packages and offer a most extreme protection of brightness for high power applications like direct diode materials handling and first phase of “combiner tree” fiber laser designing.