2016年4月29日星期五

What Is WDM?

WDM (Wavelength-division Multiplexing) is the technology of combing a number of wavelengths onto the same fiber simultaneously. A powerful aspect of WDM is that each optical channel can carry any transmission format. WDW increases the capacity of a fiber network dramatically, thus recognized as the Layer 1 transport technology in all tiers of the network. The purpose of this article is to giver a brief overview of WDM technology and its applications.
Why We Need WDM?
Due to the rapid growth in telecommunication links, high capacity and faster data transmission rates over farther distances are required. To meet these demands, network managers are relying more and more on fiber optics. Typically, there are three methods for expanding capacity: installing more cables, increasing system bitrate to multiplex more signals and wavelength division multiplexing.
The first method, installing more cables, will be preferred in many cases, especially in metropolitan areas, since fiber has become incredibly inexpensive and installation methods more efficient. But when conduit space is not available or major construction is necessary, this may not be the most cost effective.
Another way for capacity expansion is to increase system bitrate to multiplex more signals. But increasing system bitrate may not prove cost effective either. Since many systems are already running at SONET OC-48 rates (2.5 GB/s) and upgrading to OC-192 (10 GB/s) is expensive, requires changing out all the electronics in a network, and adds 4 times the capacity, may not be necessary.
The third alternative, WDM has been proved more cost effective in many instances. It not only allows current electronics and current fibers, but also simply shares fibers by transmitting different channels at different wavelengths (colors) of light. Besides, systems are already using fiber optic amplifiers as repeaters also do not require upgrading for most WDM.
From the above comparison of three methods for expanding capacity, we can easily draw a conclusion that WDM is the best solution to meet the demand for more capacity and faster data transmission rates.
How Does WDM Work?
Actually, it is not difficult to understand the operating principle of WDM. Consider the fact that you can see many different colors of light: red, green, yellow, blue, etc. all at once. The colors are transmitted through the air together and may mix, but they can be easily separated using a simple device like a prism, just like we separate the “white” light from the sun into a spectrum of colors with the prism. WDM is equivalent to the prism in the operating principle. A WDM system uses a multiplexer at the transmitter to joint the several signals together, and a demultiplexer at the receiver to split them apart, as shown in following diagram. With the right type of fiber, it is possible to have a device that does both simultaneously, and can function as an optical add-drop multiplexer.
This technique was originally demonstrated with optical fiber in the early 80s. The first WDM systems combined only two signals. Modern systems can handle up to 160 signals and can thus expand a basic 10 Gbit/s system over a single fiber pair to over 1.6 Tbit/s. Because WDM systems can expand the capacity of the network and accommodate several generations of technology development in optical infrastructure without having to overhaul the backbone network, they are popular with telecommunications companies.
Wdm-operating-principle
CWDM VS DWDM
WDM systems are divided into different wavelength patterns: CWDM (Coarse Wavelength Division Multiplexing) and DWDM (Dense Wavelength Division Multiplexing). There are many differences between CWDM and DWDM in spacings, DFB lasers and transmission distances.
The channel spacings between individual wavelengths transmitted through the same fiber serve as the basis for defining CWDM and DWDM. Typically, spacing in CWDM systems is 20 nm, while most DWDM systems today offer 0.8 nm (100 GHz) wavelength separation according to the ITU standard. Due to wider CWDM channel spacing, the number of channels (lambdas) available on the same link is significantly reduced, but the optical interface components do not have to be as precise as DWDM components. CWDM equipment is thus significantly cheaper than DWDM equipment.
Both CWDM and DWDM architectures utilize DFB (Distributed Feedback Lasers). However, CWDM systems use DFB lasers that are not cooled. These systems typically operate from 0 to 70℃ with the laser wavelength drifting about 6 nm over this range. This wavelength drift, coupled with the variation in laser wavelength of up to ±3 nm, yields a total wavelength variation of about ±12 nm. DWDM systems, on the other hand, require the larger cooled DFB lasers, because a semiconductor laser wavelength drifts about 0.08 nm/℃ with temperature. DFB lasers are cooled to stabilize the wavelength from outside the passband of the multiplexer and demultiplexer filters as the temperature fluctuates in DWDM systems.
Due to the unique attributes of CWDM and DWDM, they are deployed for different transmission distances. Typically, CWDM can travel anywhere up to about 160 km. If we need to transmit the data over a very long range, DWDM system solution is the best choice for long-haul transport and large metro rings requiring high capacity. DWDM employs the 1550 wavelength band which can be amplified, enhancing transmission distance to hundreds of kilometers.
Conclusion
WDM works by combining and splitting signals in different systems ranging from telecommunications to imaging systems. There are many WDM products including CWDM MUX/DEMUX, DWDM MUX/DEMUX, CWDM & DWDM optical add-drop multiplexer, WDM filter and so on. From the above introduction of WDM technology, you can better understand these WDM products.
cwdm-mux-demux dwdm-mux-demux
optical-add-drop-multiplexer wdm-filter

2016年4月28日星期四

An Introduction of Fiber Optic Splitter

The fiber optic splitter, known as fiber coupler, is a special fiber optic device with one or more input fibers to distributing optical signals into two or more output fibers at a certain ratio. It is one of the most important passive devices in the optical fiber link, especially applicable to a passive optical network (EPON, GPON, BPON, FTTx, etc.), to connect the MDF (Main Distribution Frame) and the terminal equipment and to achieve the branching of the optical signal. This paper will make an introduction of fiber optic splitter from its features and common types.
Features
The fiber optic splitter comes in a wide range of styles and sizes to split or combine light with minimal loss. All splitters are manufactured in a very simple proprietary process that produces reliable, low-cost devices. Their fiber lengths and/or with terminations of any type are optional. Most splitters are available in 900µm loose tube and 250µm bare fiber. 1x2 and 2x2 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.
The fiber optic splitter comes in singlemode and multimode fiber modes. Typical connectors installed on the fiber optic splitters are FC or SC type, but many couplers are also compliant with LC, LC/APC, SC, SC/APC, FC, FC/APC, and ST. Because the splitter is a passive device, it is immune to EMI (Electromagnetic Interference), consumes no electrical power and does not add noise to system design. Its passive design is bi-directional and operationally independent of wavelength, constrained only by the physical properties of the PMMA (Poly (Methyl Merthiolate)) fiber core.
Common Types
According to the technology used to fabricate splitters, there are two common types optical splitters: FBT splitter and PLC splitter. Each type has both advantages and disadvantages when deploying them in a passive optical network.
  • FBT (Fused Biconic Tapered)
FBT splitters are fused with a heat source similar to one-to-one fusion splice. The fibers are aligned in a group to create a specific location and length. Heat is applied to the aligned fibers while the fibers are monitored for polarization-dependent loss (PDL), split ration and insertion loss (IL). Once the desired parameters have been met on all fibers, the fusion process stops.
FBT splitters are well-known and are easy to produce, thus reducing cost of production. They can split unequal ratio, either symmetrical or non-symmetrical, according to the needs of real-time monitoring. Besides, FBT splitters can work on three different operating bands, such as 850 nm, 1310 nm and 1550 nm. Due to these benefits, these splitters are widely deployed in passive networks, especially for instances where the split configuration is smaller (1x2, 1x4, etc).
However, FBT splitters are limited in the number of quality splits that can be achieved in a single instance, so several must be spliced together when a larger split configuration is required. Besides, its poor uniformity can not ensure uniform spectroscopic and the insertion loss changes greatly with temperature variation.
fbt
  • PLC (Planar Light-wave Circuit )
PLC splitters use an optical splitter chip to divide the incoming signal into multiple outputs. The chip, either silica or quartz-based, is available in varying polished finishes. It is composed of three layers: a substrate, the waveguide and the lid. Waveguides are fabricated using lithography onto a silica glass substrate, which allows for routing specific percentages of light. The physical appearance of the splitter varies depending on final assembly.
PLC splitters have high quality performance but low failure rate, such as low insertion loss, low PDL, high return loss and excellent uniformity over a wide wavelength range from 1260 nm to 1620 nm. In addition, its compact configuration and small size occupy little space. Different from FBT splitters, PLC splitters split equal splitter rations for all branches. When larger split configurations are required, PLC splitter is a better solution.
However, FBT fabrication process is very complex, thus setting a high technical threshold in application. Besides, they are more expensive than FBT splitters in the smaller ratios.
plc
Conclusion
The fiber optic splitter is a passive device that plays an increasingly significant role in many of optical networks. From FTTX systems to traditional optical networks, fiber splitters provide capabilities that help customers maximize the functionality of optical network circuits.Thus an educated decision regarding splitter selection determines the long-term success and financial viability of a network build.

2016年4月19日星期二

How to Choose Fiber Optic Transceiver

Do you know the common IEEE descriptions like LX, SR and ZR? Many people are confused by the specification of the transceiver when choosing transceivers, thus making the transceiver selection painful. To make the right transceiver decision, you need take many parameters into consideration. This following paper is to introduce some important parameters frequently used in the selecting of the matching optical transceivers.

Transceiver Type
Before selecting transceiver, you’d better have a basic knowledge of transceiver types. Transceiver is a device with both a transmitter and a receiver which are combined and share common circuitry or a single housing. Typically, the fiber optic transceiver can be divided into different catalogs according to different standards. Usually, we can classify it by its package, transmission rate, and function (with or without hot pluggable). Among these classifications, the common one is divided by its package, thus we can get GBIC, SFP, SFP+, QSFP+, CFP, XFP, XENPAK and X2 and so on.
transceiver
Protocol and Data Rate
In fiber optic technology, the protocol is the special set of rules used in transceiver application. Well, the data rate is usually measured by seconds in the transmission speed. Since different switch/router supports different protocol and data rate, you should make sure the protocol and data rate support your transceiver when selecting. The following are the most common protocol and data rate types.

  • Gigabit Ethernet: 1 GE/10 GE/40 GE/100 GE
  • Fiber Channel: 1 GFC (1.25 Gbps)/2 GFC/4 GFC/8 GFC/16 GFC
  • SDH STM-1 (155 Mbps)/STM-4 (622 Mbps)/STM-16 (2.5 Gbps/STM-64 (10 Gbps)
  • Multirate (155 Mbps to 2.67 Gbps)
  • CPRI up to 6 Gbps (for Video Transmission)


  • Transceiver Media
    Transceiver can work over copper, single-mode fiber (SMF) and multi-mode fiber (MMF). In different Ethernet applications, media can achieve different link lengths when combined with transceivers. For example, the single-mode transceiver can reach a transmission distance of 5 km to 120 km, while multi-mode transceiver is defined to have the maximum reach of 550 m, with copper solution establishing even fewer link length at 25 m.

    Power Budget
    The power budget refers to the amount of loss that a data link (transmitter to receiver) can tolerate in order to operate properly. It has to be 2-3 dB larger than the measured link loss. Sometimes the power budget needs at least a minimum value of loss so that it does not overload the receiver and a maximum value of loss to ensure the receiver has sufficient signal to operate properly. As for the calculation of the link loss, transmission distance [km], number of ODFs, patches and passive optical components (Muxes) have to be considered. The following diagram describes how the power budget comes into being.
    power-budget

    In conclusion, transceivers are devices widely used in optical communication network, such as metropolitan-area networks (MAN) and local area network (LAN). It is not easy to choose the right type of transceiver for your network, but above discussed parameters can guide you to transceiver selection.


    Additional Information for common IEEE description:


  • Base -T: “copper” SFP with electrical RJ45 interface
  • SX: SFP 850 nm, MM, grey, 1GE, approx. 500 m
  • LX: SFP 1310 nm, SM, grey, 1GE, approx. 8 km
  • ZX: SFP 1550 nm, SM, grey, 1GE, approx. 70 km
  • CX4: “copper” XFP with electrical IB4x connector
  • SR: SFP+ or XFP 850 nm, MM, grey, 10GE, approx. 300 m
  • LR: SFP+ or XFP 1310 nm, SM, grey, 10GE, approx. 10 km
  • ER: SFP+ or XFP 1550 nm, SM, grey, 10GE, approx. 40 km
  • ZR: SFP+ or XFP 1550 nm, SM, grey, 10GE, approx. 80 km
  • SR4: QSFP 850 nm, MM, 40GE, approx. 100 m
  • SR10: CFP 850 nm, MM, 100GE, approx. 100 m
  • LR4: CFP or QSFP 1310 nm, SM, 40GE (CFP or QSFP) or 100GE, approx. 10 km
  • MM = multimode
  • SM = single mode
  • 2016年4月14日星期四

    Active Optical Cable

    The AOC (Active Optical Cable) is the industry’s optical solution for connections of 20 meters or less, which is ideal for data center, storage network, and high performance computing applications. Usually, the wire transmission of optical communication should belong to passive part, but AOC is an exception. AOC consists of multimode optical fiber, fiber optic transceivers, control chip and modules. It uses electrical-to-optical conversion on the cable ends to improve speed and distance performance of the cable without sacrificing compatibility with standard electrical interfaces. Typically, Passive cabling provides a direct electrical connection between corresponding cable ends. Active cables provide the same effect but, by embedding optics and/or electronics within the connectors, can overcome some of the limitations of passive cables. While passive cables are always copper-based, active cables can use either copper wire or fiber optics to provide the link between the cable ends.

    Active Optical Cable

    SFP+ to SFP+ AOC

    The SFP+ to SFP+ AOC is a preferable interconnect solution for Data Center, Storage and all high speed data applications that accepts the same electrial inputs. It uses the optical fiber and electrical optical conversion on the cable ends to improve speed and data transmission distance of the cable while not sacrificing compatibility with standard elecrtical interfaces. The SFP+ AOC have a cable length up to 20m. These AOCs can be used as an alternative solution to SFP+ passive and active copper cables, while providing improved signal integrity, longer distances, superior electromagnetic immunity and better bit error rate performance.

     SFP+ to SFP+ AOC

    QSFP+ to QSFP+ AOC

    The QSFP+ to QSFP+ AOC is a high performance interconnection solution for hort-range multi-lane data communication and interconnect applications. It integrates four data lanes in each direction with 40Gbps aggregate bandwidth. Each lane can operate at 10Gbps with lengths ranging from one to 100m. The QSFP+ to QSFP+ AOC is permanently attached to the fiber, with no air gaps, providing protection from environmental contaminants and other user disturbances during installation. It is available in standard lengths up to 300m and custom lengths up to 4km (2.49 miles) for design flexibility.In addition, the QSFP+ to QSFP+ AOC can provide state-of-the-art performance, helping IT organizations achieve new levels of infrastructure consolidation while expanding application and service capabilities.
    QSFP+ to QSFP+ AOC

    QSFP+ to 4 SFP+ AOC

    The QSFP+ to 4 SFP+ AOC is a parallel active optical cable storage, data, and high-performance computing interconnectivity, which transmits four separate streams of data over ribbon cables in a point-to multipoint configuration. The QSFP+ to SFP+ is commonly known as a “fanout” assembly that contains a QSFP+ module on one end and four separate SFP+ modules at the other ends. It features low weight for high port count architectures, High-density 40Gb/s interconnectivity and Low power consumption. Complies with QSFP+ and SFP+ MSA form factors. In the market, there are two common AOC for 40g Ethernet: QSFP to 4 SFP+ breakout AOC and QSFP to QSFP AOC. 

    QSFP+ to 4 SFP+ AOC 

    QSFP+ to 4 SFP+ DAC

    The QSFP+ to 4 SFP+ DAC offers IT professionals a cost-effective interconnect solution for merging 40G QSFP port on one end and to four 10G SFP+ports on the other end. It is suitable for very short distances and offers a very cost-effective way to connect within racks and across adjacent racks. Currently these passive cables in lengths of 1, 3, and 5 meters and active cables in lengths of 7 and 10 meters can be offered in the market. The QSFP+ to 4 SFP+ DAC can bridge the gap between your 10G and 40G capable switches/host adapters and it is fully compliant to the latest SFP+ & QSFP MSA (Multi-Source-Agreement).
    QSFP+ to 4 SFP+ DAC

    QSFP+ to QSFP+ DAC

    The QSFP+ to QSFP+ DAC consist of a cable assembly terminated with QSFP+ transceivers on either end, which is suitable for in-rack connections between QSFP+ ports of EX Series switches. It can be used for short distances of up to 16.4 ft (5m), making it ideal for highly cost-effective networking connectivity within a rack and between adjacent racks. The QSFP+ to QSFP+ DAC can be fully compliant to the QSFP+ MSA and SFF-8436 for guaranteed compatibility. It is widely used in Gigabit Ethernet, Data Center Cabling Infrastructure, Storage Area Networks( SAN), Network Attached Storage, Storage Servers and Fiber Channel.
    QSFP+ to QSFP+ DAC


    SFP+ to SFP+ DAC

    The SFP+ to SFP+ DAC is the cost-effective alternative that offers the smallest 10 Gigabit form factor and a small overall cable diameter for higher density and optimized rack space in 10 Gigabit Ethernet uplinks and 10 Gigabit Fiber Channel SAN and NAS input and output connections. SFP+ to SFP+ DAC delivers lower power, lower latency and higher density for Data Centers and Storage Area Networks. The use of SFP+ Direct Attached Cables can cost up to three times less than fiber optic solutions, while offering lower latency and consuming up to 50% less power per port than current copper twisted-pair cabling systems.
     SFP+ to SFP+ DAC

    Direct Attach Cable

    The DAC (Direct Attach Cable) is an alternative to optical transceiver by eliminateing the separable interface between transceiver module and optical cable. It meets the SFF standards and can reach the speed up to 40Gb/s throughput with QSFP+. DAC is about 1/3 Size of Copper Cable 3.0 mm O.D and 1/3 Weight of Copper Cable. DAC cables are a cost effective, proven solution for interconnecting networking applications. It Uses the same port as an optical transceiver, but with significant cost savings and power savings in short reach application. The products are continuing to evolve to meet industry needs of higher data rates and densities with low power consumption Ethernet and Fibre Channel, and InfiniBand standards are increasing in speed to support this increase.
    Direct Attach Cable

    SC Connector

    The SC Connector (Standard Connector or Subscriber Connector) is a fiber-optic cable connector that uses a push-pull latching mechanism similar to common audio and video cables. There are single-mode and multimode fiber-optic cabling for SC Connectors. SC Connectors come in both simplex and duplex form and they are typically used in data communication, CATV, and telephony environments. SC is covered in the TIA connector intermateability standard FOCIS-3 (TIA-604-3). SC and LC connectors both use a push-pull plug similar to audio and video plugs and sockets. SC connectors have a 2.5mm ferrule, whereas the smaller LC is only 1.25mm.
    SC Connector

    LC

    LC ( Lucent Connector) is a small form fiber optic connector that uses a 1.25 mm ferrule, half the size of the SC. Otherwise, it's a standard ceramic ferrule connector, easily terminated with any adhesive. LC connectors are available in industry standard beige (multimode), blue (singlemode) and green (angle polish) colors, With its six-position tuning feature, the connector may be used to achieve unprecedented insertion loss performance by optimizing the alignment of the fiber cores. The LC connnector is widely used in telecommunications networks, local area networks, data processing networks and device terminations and so on.
    LC 

    MPO connector

    An MPO (Multi-position Optica) connecter is a multi-fiber optic Interconnecting device and passive component with the size of a fingernail and contains 12 optical fibers, each less than the diameter of a human hair and each one needs to be tested separately. It's main use is for preterminated cable assemblies and cabling systems. This connector is sometimes called a MTP which is used by US Conec to describe their connectorters. The US Conec MTP product is fully compliant with the MPO standards. So the MTP connector is an MPO connector. MTP/MPO assemblies utilize a push-pull connector housing for a quick and reliable connection. For optical device interconnections, MTP/MPO assemblies interface on the daughter card to Molex’s HBMT and BMTP adapters on the backplane. 
     MPO connector


    optical fiber connector

    An optical fiber connector holds the fibers and aligns fibers for mating. It uses a mating adapter to mate the two connector ferrules that fits the securing mechanism of the connectors (bayonet, screw-on or snap-in ). The ferrule design is also useful as it can be used to connect directly to active devices like LEDs, VCSELs and detectors. During the development of fiber optic technology over the last 35 years, many companies and individuals have invented the "better mousetrap" - a fiber optic connector that was lower loss, lower cost, easier to terminate or solved some other perceived problem. Now, about 100 fiber optic connectors have been introduced to the marketplace, among them the leaders are ST, SC, FC and MT-RJ style connectors. Since the earliest days of fiber optics, orange, black or gray was multimode and yellow singlemode. However, the advent of metallic connectors like the FC and ST made color coding difficult, so colored boots were often used. The TIA 568 color code is used for connector bodies, such as Beige for multimode fiber, Blue for singlemode fiber, and Green for APC (angled) connectors.
    optical fiber connector

    MPO fiber optic patch cable

    MPO/MTP fiber optic patch cables stand for “Multiple-Fiber Push-On/Pull-off” allowing high-density connections between network equipment in telecommunication rooms. MTP fiber optic cables are available in Female to female or a male to male and male to female configurations. The male version has MTP pins. These can be made with 12 fiber MTP connectors, 24 Fiber MTP connectors, 48 Fiber MTP connector variations. MPO fiber optic cables are used in various applications for all networking, such as Data Centers, Storage Area Networks(SAN), Local Area Networks (LAN) and any 10G, 40G, or 100G Networks and so on.
    MPO fiber optic patch cable


    2016年4月12日星期二

    Single-mode Fiber Patch Cable VS Multimode Fiber Patch Cable

    According cable mode, patch cables can be divided into single-mode and multimode fiber patch cables. The word “mode” means the transmitting mode of the fiber optic light in the fiber optic cable core. Of all the differences between Singlemode Fiber Patch Cables and Multimode Fiber Patch Cables are the size of the fiber’s core and the associated attenuation or loss and bandwidth of the fiber. 
    Singlemode Fiber Patch Cables are optical fibers with a small core (2-9 microns that supports one mode), which are most commonly used for transmitting data over long distances. They are usually used for connections over large areas, such as college campuses and cable television networks. And they have a higher bandwidth than multimode cables to deliver up to twice the throughput. Most Singlemode Fiber Patch Cables are color-coded yellow. 
    Mutimode Fiber Patch Cables are optical fibers with the core (25-200 microns) that supports several modes. Most Mutimode Fiber Patch Cables are orange color. In addition, there is 10G OM3 and OM4 Multimode Patch Cables which cable jacket are usually aqua. Mutimode Fiber Patch Cables are usually used in short distance, generally only a few kilometers, because their dispersion limits the frequency of digital signal transmission.     
     Multimode Fiber Patch Cable
    Single-mode Fiber Patch Cable

    patch cable

    A patch cable is an electrical or optical cable with connectors on the ends that is used to connect an end device to something else, such as a power source. One of the most common uses is connecting a laptop, desktop or other end device to a wall outlet. Different types devices are connected with patch cables, for example, a switch connected to a computer, or a switch to a router. Typically, a copper cable has an RJ45, TERA or GG45 connector on both ends, although hybrid versions exist that have different types of connectors on the ends. While fiber patch cable, typically called fiber jumpers, is either a standard jumper or a mode conditioning jumper.
    patch cable 


    FC SFP

    FC (Fibre Channel) is a high network technology (commonly running at 2-, 4-, 8- and 16-gigabit per second rates) primarily used to connect computer data storage. It is standardized in the T11 Technical Committee of the International Committee for Information Technology Standards (INCITS), an American National Standards Institute (ANSI)-accredited standards committee. Well, FC SFP is a transceiver offering maxium performance, reliability and compatibility for storage and computing products. There are Singlemode FC SFP and Multimode FC SFP for 2Gigabit Fibre Channel, 4Gigabit Fibre Channel, Gigabit Ethernet and Gigabit Fibre Channel with LC connector.
    FC SFP

    SONET

    SONET (Synchronous Optical Networking) is the American National Standards Institute standard for synchronous data transmission on optical media using lasers or highly coherent light from light-emitting diodes (LEDs). The international equivalent of SONET is synchronous digital hierarchy (SDH). Together, they ensure standards so that digital networks can interconnect internationally and that existing conventional transmission systems can take advantage of optical media through tributary attachments. The method was developed to replace the plesiochronous digital hierarchy (PDH) system for transporting large amounts of telephone calls and data traffic over the same fiber without synchronization problems.

    SONET 


    DWDM SFP

    DWDM SFP is based on the SFP form factor which is an MSA standard build. The maximum speed of the product is 1.25G and it is also available as 2.5G, 4G and of course the popular 10G DWDM SFP+. It is mostly compatible with 1G DWDM Ethernet solution, but can also be deployed as 1x Fiber channel. The DWDM SFP has a specific tuned laser which emits a “color” which is defined in the DWDM ITU grid. There are different DWDM ITU grids and the 100GHz C-Band is the most used in the telecom industry. 

    DWDM SFP

    CWDM SFP

    As is known to all, CWDM is the technology that combines multiple signals on laser beams at various wavelengths for transmission along fiber optic cables. Well, CWDM SFP is a hot-swappable input/output device that plugs into an SFP port or slot of a switch or router, linking the port with the fiber-optic network. The Cisco CWDM SFP is a multirate part that supports both Gigabit Ethernet 1.25 Gbps full-duplex links with an optical link budget of 29 dB and Fibre Channel 1.06 and 2.12 Gbps full-duplex links with an optical link budget of 28 dB. The Cisco CWDM SFP is supported across a variety of Cisco switches, routers, and optical transport devices, which allows enterprise companies and service providers to provide scalable and easy-to-deploy Gigabit Ethernet and Fibre Channel services in their networks. 
     CWDM SFP

    DWDW

    DWDW (Dense Wavelength Division Multiplexing) is an optical technology used to increase bandwidth over existing fiber optic backbones by combining and transmitting multiple signals simultaneously at different wavelengths on the same fiber. There are two different versions for DWDW: an active solution and a passive solution. An active solution is going to require wavelength management and is a good fit for applications involving more than 32 links over the same fiber. In most cases, passive DWDM is looked at as a more realistic alternative to active DWDM. DWDM offers essentially the same benefits of CWDM, especially when evaluating a passive solution. However, there are still many differences between DWDM and CWDM. Usually, DWDM is defined by frequencies for long-haul transmission, while CWDM is defined by wavelengths for short-range communications. Besides, DWDM works by breaking the spectrum into big chunks and the light signal isn’t amplified, but CWDM dices the spectrum into small pieces and the signal amplification may be used. 

    CWDM

    CWDM (Coarse Wavelength Division Multiplexing) is a passive technology allowing multiple signals on laser beams at various wavelengths for transmission along fiber optic cables, such that the number of channels is fewer than in dense wavelength division multiplexing (DWDM) but more than in standard wavelength division multiplexing (WDM). Due to its lower cost, it proves to be the initial entry point for many organizations. CWDM typically supports the rate of 2.5Gbps and up to 10Gbps. CWDM is a simple and affordable method to maximize existing fiber by decreasing the channel spacing between wavelengths. There are many benefits of CDWM, including no use of electrical power, extended temperature range (0-70˚C) and lower cost per channel than DWDM and so on.

    2016年4月11日星期一

    WDM

    WDM (Wavelength-division multiplexing) is the basic technology combining multiplexing signals on laser beams at various infared (IR) wavelengths for transmission along fiber optic media. In early WDM systems, there were two IR channels per fiber. At the destination, the IR channels were demultiplexed by a dichroic (two-wavelength) filter with a cutoff wavelength approximately midway between the wavelengths of the two channels. It soon became clear that more than two multiplexed IR channels could be demultiplexed using cascaded dichroic filters, thus giving rise to coarse wavelength-division multiplexing (CWDM) and dense wavelength-division multiplexing (DWDM). 
    WDM 

    BIDI SFP

    The BIDI SFP is a compact optical transceiver module used in optical communications for both telecommunication and data bidirectional communications applications. It interfaces a network device mother board (for a switch, router or similar device) to a fiber optic or unshielded twisted pair networking cable. It is a popular industry format supported by several fiber optic component vendors. The host-swappable BIDI SFP Transceiver is available in multimode and single-mode with155mb, 1g, 2G and 4G speeds and operates a distances up to 160km. BIDI SFP can be compatible either with SC or LC simplex port, that is used both transmission and receiving. The most typical wavelength combination is 1310/1490, 1310/1550, 1490/1550 and 1510/1570.
    BIDI SFP


    QSFP28

    The QSFP28 Transceiver, capable of transmitting and receiving 100 Gbps simultaneously, is a 4-channel transceiver used for data communications applications. The QSFP specification accommodates Ethernet, Fibre Channel, InfiniBand and SONET/SDH standards with different data rate options. Featuring Coolbit optical engines, the QSFP28 transceiver performs at high speeds while consuming extremely low power—allowing for > 50% reduction in power consumption compared to 4 SFP+ interconnects. Its digital diagnostic monitoring interface is similar to that used by SFP+ modules allowing customer access to key module parameters as well as providing alarm and warning flags. This improves customer system management capability.
    QSFP28


    100G CXP

    The 100G CXP is a hot-swappable input/output device that offers customers a wide variety of high-density 100Gbps connectivity solutions for short-reach data center networking, high-performance computing networks, enterprise core aggregation, and service provider transport applications. Because the 100G CXP is targeted at the clustering and high-speed computing markets, we usually called it high-density CXP. The 100G CXP includes 12 transmit and 12 receive channels in its compact package, which is achieved via a connector configuration similar to that of the CFP. However, CXP is for short reach applications while CFP is for longer reach applications.
    100G CXP 

    CFP4

    The CFP4 Transceiver is a fully integrated 100Gbps optical transceiver module designed for optical communication applications compliant to 100GBASE-LR4 of the IEEE P802.3ba standard. The module converts 4 input channels of 25Gbps electrical data to 4 channels of LAN WDM optical signals and then multiplexes them into a single channel for 100Gbps optical transmission. Reversely on the receiver side, the module de-multiplexes a 100Gbps optical input into 4 channels of LAN WDM optical signals and then converts them to 4 output channels of electrical data. Its compact size is half smaller than the first generation CFP.
    CFP4

    CFP2

    The CFP2 Transceiver is hot pluggable and high-density, designed for use in 100 Gigabit Ethernet links and 4x28G OTN client interfaces over single mode fiber. They are compliant with the CFP2 MSA and IEEE 802.3ba 100GBASE-SR10 and IEEE 802.3ba 100GBASE-LR4. Digital diagnostics functions are available via the MDIO, as specified by the CFP2 MSA. The transceiver is RoHS-6 compliant and lead-free. There are two types of GFP2: 100G GFP2 SR10 100m MMF with MPO-24 connector and 100G CFP2 LR4 10km SMF with LC connector. Compared with CFP, CFP2 has smaller size and lower power consumption and thus it is sold well when shipping into the market.
    CFP2

    2016年4月8日星期五

    CFP Transceiver

    The CFP Transceiver (C form-factor pluggable Transceiver) is a ultra high speed pluggable I/O interface supporting 40 and 100Gb/s Ethernet applications that is specified by a multi-source agreement(MSA) between competing manufacturers. It was designed after SFP, but is significantly larger to support 10Gbits/s. Its product type includes 100G CFP SR10, 100G CFP LR4, 100G CFP2 SR10, 100G CFP2 LR4, 100G CFP4 SR4, 100G CFP4 LR4, 40G CFP SR4, 40G CFP LR4 and 40G CFP ER4. A CFP Transceiver is composed of position biasing spring places, connector nose, shell latch places contact solder tails and PC board slot. The CFP Transceiver is a static-sensitive device, so an ESD wrist strap or similar individual grounding device is necessary when handling the CFP Transceivers or coming into contact with the modules.
     CFP Transceiver 

    QSFP

    QSFP (Quad Small Form-factor Pluggable) is a hot-swappable I/O interface products that offers 4 channels, providing 3 times the density of SFP/SFP+ ports. It is widely used in data center, high-performance computing networks, enterprise core and distribution layers, and service provider applications. The QSFP application mainly consists of a 38-position high speed surface mount connector for the host board, a cage which provides EMI containment and guidance for the mating plug and so on. Besides, QSFP cages and connectors are not only designed for data rates up to 10 Gb/ supporting Fiber Channel, Ethernet, SDH/SONET and INFINIBAND standards, but also accept optical or copper interfaces.
    QSFP

    XENPAK Module

    XENPAK Module offers a wide variety of 10 Gigabit Ethernet connectivity options for data center, enterprise wiring closet, and service provider transport applications. It is mainly composed of captive installation screw, transmit optical bore and receive optical bore. It is also a hot-swappable input or output device plugging into an Ethernet XENPAK port of a specific switch or router to link the port with the network. There are six modules in this product family: XENPAK-10GB-CX4, XENPAK-10GB-LRM, XENPAK-10GB-SR, XENPAK-10GB-LR+, XENPAK-10GB-ER+, XENPAK-10GB-ZR. XENPAK Module is very convenient because it is supported by numerous network equipment manufacturers and module makers. Later,two related standards appeared: XPAK and X2. These two standards have the same electrical interface as XENPAK (known as XAUI) but different mechanical properties.
    XENPAK Module

    2016年4月7日星期四

    The 10G X2 Transceiver

    The 10G X2 Transceiver is a type of 10Gigabit Ethernet optical transceiver based on Xenpak Transceiver Module. X2 Module also can use one transceiver to fulfill all 10G Ethernet optical port function or 10G Fiber Channel versions. X2 Transceiver is better for density installation for it is only half size of the old generation Xenpark Transceiver Module. It is electrical interface for that host board can also be standardized and it is called XAUI (4x3.125Gb/s). Manufactures can supply X2 220m, X2 300m, X2 10km, X2 20km, X2 40km, X2 80km optical modules and all modules support Digital Optical Monitoring (DOM) function. 


    XFP Module

    XFP Module is a standard for transceivers for high-speed computer network and telecommunication links. It uses optical fiber that operates at near-infrared wavelengths(colors) of 850nm, 1310nm or 1550nm. XFP Module is hot-swappable and protocol-independent mainly applicable in 10Gigabit Ethernet, 10Gbit/s Fiber Channel, synchronous optical networking (SONET) at OC-192 rates, synchronous optical networking STM-64, 10 Gbit/s Optical Transport Network OTU-2, and parallel optics link. The XFP standard was specified by the XFP Mufti-Source Agreement Group. It can operate over a single wavelength or use dense wavelength-division multiplexing techniques with an LC fiber connector type to achieve higher density.

    SFP+ Module

    SFP+ Module(Small Form-factor Pluggable Plus Module) is an enhanced version of the SFP that supports applications for 8Gbps Fiber Channel, 10Gbps Gigabit Ethernet and Optical Transport Network standard OTU2. It is a popular industry format supported by many network component vendors. SFP+ uses the same space-per-port as standard SFP but leaves more circuitry to be implemented on the host board instead of inside the module. SFP+ module can be divided into limiting or linear type according to the functionality of the inbuilt electronics. Limiting SFP+ module includes the signal amplifier to re-shape the received signals whereas linear one does  not. Linear module is mainly used with the low bandwidth standard such as 10GBASE-LRM; otherwise, limiting modules are preferred.

    SFP Transceiver

    SFP Transceiver(Small Form-factor Pluggable Transceiver), the upgraded version of GBIC, is a compact,hot-pluggable transceiver widely applied in both telecommunication and data communications. Its form factor and electrical interface are specified by the multi-source agreement(MSA). SFP transceiver is expected to perform at data speeds of up to five gigabits per second (5Gbps), and possibly higher than traditional soldered-in modules because SFP is interchangeable fiber connector that can adapt to any existing network. Elector-optical or fiber optic networks can be upgraded and maintained more easier by installing it. Several companies have reached an agreement supporting the use of SFP to meet their common articles of broad bandwidth, small physical volume and removal and replacement.

    GBIC

    GBIC(Gigabit Interface Converter) is a standard for transceivers which can offer a convenient and cost effective solution for the adoption of Gigabit Ethernet and Fiber Channel in data center, campus, metropolitan area access and ring networks, and storage area networks. A variation of the GBIC is called the small form-factor pluggable transceiver(SFP), also known as Mini-GBIC, has the same functionality but in a smaller form factor. The GBIC module has a receiver port (RX) and a transmitter port (TX) that make up one optical interface. GBIC is available for the 1.25Gbps data rate being mostly used in Ethernet switches, and also in special converters like FIB1-1000TG GBIC to UTP fiber media converter.

    Optical Transceiver Module

    Optical Transceiver Module is mainly composed of electronic device including transmitter and receiver, function circuit and optical interface. The function of the optical module is photoelectric conversion in which the transmit end converts electrical signals into light signals while the receive end converts light signals into electrical signals. It is widely used in optical communication network, such as metropolitan-area networks (MAN) and local area network (LAN). Optical module is mainly divided into: GBIC, SFP, SFP+, XFP, SFF, CFP and the commonly used is the SFP, SFP+, XFP which is smaller and cheaper than GBIC.