Category: Fiber Transceivers

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

How to Test an SFP+ Transceiver Module?

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

It is particularly important to test the compatibility and interoperability of each fiber optic transceiver in the network, for most optical networks today use components that may come from various suppliers. Verifying the performance of an SFP+ transceiver module when it is first deployed is necessary and straightforward. How to test an SFP+ transceiver module to make sure that it can function well? This article will discuss SFP+ transceiver module test.
SFP+ Background
SFP+ is a hot-pluggable multi-rate optical transceiver for data communications and storage-area network (SAN) applications. As SFP+ transceiver becomes more pervasive, engineers need to become more familiar with some of the key challenges linked to testing SFP+ capable devices. We know that basically an SFP+ transceiver consists of a transmitter and a receiver. When a transmitter connects with a receiver through a fiber, the system doesn’t achieve your desired bit-error-ratio (BER). Where is the problem? Is it the transmitter or the receiver? Perhaps both are faulty. A low-quality transmitter can be compensated by a low-quality receiver (and vice versa). Thus, specifications should guarantee that any receiver will interoperate with a worst-case transmitter, and any transmitter will provide a signal with sufficient quality such that it will interoperate with a worst-case receiver. The picture below shows a Brocade 10G-SFPP-SR 10GBASE-SR SFP+ transceiver.
SFP+ Transceiver Test
The test of an an SFP+ transceiver module can be divided into two parts: the transmitter testing and the receiver testing.
SFP+ Transmitter Testing
SFP+ transmitter parameters may include wavelength and shape of the output waveform. There are two steps to test a transmitter:
1. The input signal used to test the transmitter must be good enough. Measurements of jitter and an eye mask test must be performed to confirm the quality using electrical measurements. An eye mask test is the common method to view the transmitter waveform and provides a wealth of information about overall transmitter performance.
2. The optical output of the transmitter must be tested using several optical quality metrics such as a mask test, OMA (optical modulation amplitude), and Extinction Ratio.
SFP+ Receiver Testing
SFP+ receiver may specify tolerance to jitter and bandwidth. To test a receiver, there are also two steps:
1. Unlike testing the transmitter, where one must ensure that the input signal is of good enough quality, testing the receiver involves sending in a signal that is of poor enough quality. To do this, a stressed eye representing the worst case signal shall be created. This is an optical signal, and must be calibrated using jitter and optical power measurements.
2. Then, testing the electrical output of the receiver must be performed, which includes three basic categories of tests:
A mask test, which ensures a large enough eye opening. The mask test is usually accompanied by a BER (bit error ratio) depth.
Jitter budget test, which tests for the amount of certain types of jitter.
Jitter tracking and tolerance, which tests the ability of the internal clock recovery circuit to track jitter within its loop bandwidth.
SFP+ Transceiver Test
SFP+ Testing Challenges
During the process of SFP+ transceiver testing, there are several challenges that you need to pay attention to. One challenge is moving seamlessly from a compliance environment to a debug environment. If a measurement fails, how can the designer determine which component is causing the failure and debug the issue to arrive at the root cause? Another problem that most designers face today relates to connectivity: how to get the signal out from the device under test (DUT) to an oscilloscope. Yet another challenge is the increased port density and the testing time required with 48 or more ports per rack.
Summary
Testing an SFP+ transceiver module is a complicated job, and it is also an indispensable step to ensure its performance. Basic eye-mask test is an effective way to test a transmitter and is still widely used today. To test a receiver seems more complex and requires more testing methods. Fiberstore provides all kinds of compatible SFP+ transceivers, like Avago AFBR-709SMZ compatible SFP+ module or HP J9150A compatible 10GBASE-SR SFP+ module, which can be compatible with many brands such as Cisco, HP, Arista, Brocade, etc. And every SFP+ transceiver from Fiberstore has been tested to ensure our customers with superior quality.

Two Core Sizes of Multimode Fiber Optic Cable

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

Fiber jumpers continue to provide a cost-effective cabling solution for data centers, local area networks (LANs), and other enterprise applications. Singlemode fiber optic patch cordsand multimode fiber optic patch cords are two options. Compared to singlemode fiber, multimode fiber has a large diameter core, which allows multiple wavelengths of light traveling in the fiber core at the same time. Multimode fiber optic patch cord comes with two core sizes: 50 micron and 62.5 micron. And this article will talk about these two core sizes of multimode fiber optic cables.
Overview
The numbers 50µm and 62.5µm refer to the diameters of the glass or plastic core, the part of the fiber that carries the light which encodes your data. The dimensions are sometimes specified as 50/125μm and 62.5/125μm, to include the diameter of the cladding, which confines the light to the core because it has a lower index of refraction. You can use both in the same types of networks, although 50µm cable is recommended for premise applications, like backbone, horizontal, and intrabuilding connections. They both can use either LED or laser light sources. The main difference between 50µm and 62.5µm cable is in bandwidth, 50µm cable features three times the bandwidth of standard 62.5µm cable, particularly at 850nm. The 850nm wavelength is becoming more important as lasers are being used more frequently as a light source. Other differences are distance and speed. 50µm cable provides longer link lengths and higher speeds in the 850nm wavelength.
multimode fiber
62.5µm Multimode Fiber Optic Patch Cords
OM1 fiber optic cable is the 62.5/125 multimode fiber cable. OM1 fiber has a bigger core diameter, which makes it better at concentrating the light and bend-resistance. OM1 fiber was the indoor cabling standard chosen by AT&T, ANSI and IBM. For OM1 fiber cable, the max attenuation is 3.5dB/km working at 850nm, 1.5dB/km at 1300nm. Overfilled launch of OM1 fiber optic cable at 850nm is 200MHz*km, at 1300nm is 500MHz*km. Today, OM1 fiber optic cables are still a popular indoor use multimode fiber optic cable.
50µm Multimode Fiber Optic Patch Cords
50µm fiber includes OM2, OM3, OM4. OM2 fiber optic cable refer to the commonly used 50/125 traditional multimode fiber cable. OM1 and OM2 are both orange jacketed cable, and you cannot judge from the outer diameter to identify OM1 and OM2 fiber cable, because the 50/125 and 62.5/125 refer not to whole cable diameter but to the fiber inside. OM2 multimode fiber cables are used in fiber optic telecommunications and high speed transmission systems that require simultaneous, bi-directional data transfer.
OM3 cable and OM4 cable are both optimized for laser based equipment that uses fewer modes of light. As a result of this optimization, they are capable of running 10 Gigabit Ethernet at lengths up to 300m and 550m respectively. OM4 is completely backwards compatible with OM3 fiber and shares the same distinctive aqua jacket. OM4 was developed specifically for VSCEL laser transmission. OM4 multimode fiber optic cable is the highest level of multimode fiber optic cable that you can use. They can be used in networks where an overwhelming or extreme amount of data transfers will take place.
Which One Should You Choose?
Given its superior technical characteristics for high-speed links, 50μm fiber is the clear choice for new multimode fiber links in most circumstances. OM3-grade, high-bandwidth 50/125-micron fiber cable increases the flexibility of network designs and achieves data transfer rates up to 10Gbps at the lowest available cost. 50μm multimode fiber is the medium of the future, with 62.5μm fiber being supported chiefly for legacy purposes. However, the majority of the fiber deployed in the world today is 62.5μm, so backward compatibility is an important concern. On the other hand, there are no technical drawbacks to using different fiber types in separate network links, as long as the ports at both ends of the link are compatible with the cable. In a word, installing 50μm fiber for new network links is a good investment for future growth.
Summary
With the increasing demand for network capacity, upgrades must be planned with an eye to the future. Installing 50μm multimode fiber today brings immediate benefits of longer cable reach and improved light loss budget margins, and prepares the network for future upgrades.

Multimode Fiber Optic Patch Cable Overview

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

We know that fiber optic patch cables play a very important role in the connection between devices and equipment. When talking about fiber optic patch cables, we usually divide them into multimode fiber optic patch cables and singlemode fiber optic patch cables according to the modes of the cable. What is multimode fiber optic patch cable? How many types of multimode patch cables are there? And what is the difference between multimode and singlemode patch cables? What are the applications of multimode patch cables? This text will solve those questions one by one.
Introduction
Multi-mode fiber patch cables are described by the diameters of their core and cladding. There are two different core sizes of multi-mode fiber patch cords: 50 microns and 62.5 microns. Both 62.5 microns and 50 microns patch cable feature the same glass cladding diameter of 125 microns. Thus, a 62.5/125µm multi-mode fiber patch cable has a 62.5µm core and a 125µm diameter cladding; and a 50/125µm multi-mode fiber patch cable has a 50µm core and a 125µm diameter cladding. The larger core of multi-mode fiber patch cords gathers more light and allows more signals to be transmitted, as shown below. Transmission of many modes of light down a multi-mode fiber patch cable simultaneously causes signals to weaken over time and therefore travel short distance.
Types of Multimode Fiber Optic Patch Cable
Multimode fiber optic cables can be divided into OM1, OM2, OM3, and OM4 based on the types of multimode fiber. The letters “OM” stands for optical multimode. OM1 and OM2 belong to traditional multimode fiber patch cable, while OM3 and OM4 belong to the new generation fiber patch cable which provides sufficient bandwidth to support 10 Gigabit Ethernet up to 300 meters. The connector types include LC, FC, SC, ST, MU, E2000, MPO and so on. Different type of connector is available to different equipment and fiber optic cable.
By the materials of optic fiber cable jackets, multimode fiber patch cord can be divided into four different types, PVC, LSZH, plenum, and armored multimode patch cable. PVC is non-flame retardant, while the LSZH is flame retardant and low smoke zero halogen. Plenum is compartment or chamber to which one or more air ducts are connected and forms part of the air distribution system. Because plenum cables are routed through air circulation spaces, which contain very few fire barriers, they need to be coated in flame-retardant, low smoke materials. Armored fiber patch cable use rugged shell with aluminum armor and kevlar inside the jacket, and it is 10 times stronger than regular fiber patch cable.
Difference Between Singlemode and Multimode Patch Cables
Multimode and singlemode fiber optic patch cables are different mainly because they have different sizes of cores, which carry light to transmit data. Singlemode fiber optic patch cables have a core of 8 to 10 microns. Multimode fiber patch cable allows multiple beams of light passing through, while singlemode fiber cable allows a single beam of light passing through. As modal dispersion happens in multimode fiber cable, the transmission distance is relevantly nearer than singlemode fiber cables. Therefore, multimode fiber optic patch cable is generally used in relevantly recent regions network connections, while the singlemode fiber cable is often used in broader regions.
Applications of Multimode Fiber Optic Patch Cable
Multi-mode fiber patch cables are used to connect high speed and legacy networks like Gigabit Ethernet, Fast Ethernet and Ethernet. OM1 and OM2 cables are commonly used in premises applications supporting Ethernet rates of 10Mbps to 1Gbps, which are not suitable though for today’s higher-speed networks. OM3 and OM4 are best multimode options of today. For prevailing 10Gbps transmission speeds, OM3 is generally suitable for distance up to 300 meters, and OM4 is suitable for distance up to 550 meters.
Conclusion
Fiber optic patch cords are designed to interconnect or cross connect fiber networks within structured cabling systems. Typical fiber connector interfaces are SC, ST, and LC in either multimode or singlemode applications. Whether to choose a singlemode or multimode fiber patch cable, it all depends on applications that you need, transmission distance to be covered as well as the overall budget allowed.

FIBER PATCH CABLES AND THEIR USES

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

Fiber patch cables are the backbone of the fiber optics industry. These fiber patch cables are strands of optically pure glass as thin as human hair.
These cables carry information via mode of transmission of light. Short patch leads usually made with stranded wire are flexible patch cables. The fiber patch cables are used to plug one piece of equipment into another. To sum, these cables are the most opted solution these days for the networking and broadcasting industry.
They have various uses in all kinds of industries. Fiber patch cables are used in:
Medical imaging
Mechanical engineering
LAN applications
Cable TV networks
Telephone lines,
and More!
Fiber patch cables have revolutionized the total network industry of telephones, cable, internet, audio applications, etc. The fiber patch cables offer accurate signal transfer which is totally distortion free. Thus due to these cables the audio or video transmission is completely distortion free and crystal clear. Since these fiber patch cables use light as a mode of transmission there is no hazard of electric interferences or any tampering.
Fiber Patch Cables Used for?
Fiber patch cables are used to two nearby components with fiber connectors. Fiber patch cables come with their respective connectors. They can be an ideal and easy replacement of copper cables because they use the same RJ45 connector as copper patch cables.
What are Fiber Patch Cables Available in?
Fiber patch cables are available in simplex, duplex, multimode, single mode with STST, STSC, SCSC connectors. Fiber patch cables are of two prominent types – single mode and multimode. Single mode fiber patch cables are used in long-distance high capacity voice applications like telephone transmission or long distance gigabit networking. These fiber patch cables can use 9/125 micron bulk fiber cables and connectors at both ends.
Multimode fiber patch cables are used in computer industry which is standard for data applications like local area network, wide area network, etc. Fiber patch cables in multimode are available in 50µm and 62.5µm. SC, ST, LC, FC, MT-RJ, E2000 and MU connectors have polished ceramic ferrules for precision and durability. The SC and LC duplex fiber patch cables come equipped with a clip to maintain polarity.
ST to ST fiber patch cable gives unlimited bandwidth at high speeds over long distances. These fiber patch cables are ideal for connections between fiber patch panels, hubs, switches, media converters and routers, etc. Fiber patch cables provide higher speeds and increased bandwidth, compared to conventional twisted-pair copper cable. These fiber patch cables are compatible with all standard fiber optic equipment and connectors. Ceramic connectors of these fiber patch cables ensure low signal loss and high reliability along with total immunity to electrical and electromagnetic interference.

A Brief Introduction to PON

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

Optical fiber is reliable and cost-effective, therefore FTTx (fiber to the x) is widely used as a new generation of broadband solutions. How to implement FTTx? PON, passive optical network, is generally considered to be the best approach. The text will provide a basic introduction to PON.
PON Technologies
A passive optical network is a single, shared optical fiber that uses unpowered optical splitters to enable a single optical fiber to serve multiple end-points. PON is a point to multipoint (P2M) network. Each customer is connected into the optical network via a passive optical splitter, therefore, no active electronics in the distribution network and bandwidth is shared from the feeder to the drop. Purely optical passive components in a PON architecture can withstand severe and demanding outside plant environment conditions without the need to consume energy between the central office exchange and the customer premises. The low maintenance requirements of these passive optical components will significantly reduce the cost of upgrades and operating expenditures. The picture below shows a PON architecture.
PON infrastructure
PON Standards
There are three main varieties of PON today: APON/BPON, GPON, EPON.
APON/BPON
ATM (asynchronous transfer mode) passive optical network (APON) was initiated in 1995 by ITU/FSAN and standardized as ITU-T G.983. APON was the first PON based technology developed for FTTH deployment. APON is renamed as broadband passive optical network (BPON). BPON is stable standard that re-uses ATM infrastructure. APON/BPON systems typically have downstream capacity of 155 Mbps or 622 Mbps. Upstream transmission is in the form of cell bursts at 155 Mbps.
GPON
While BPON may still be used in some systems, most current networks use Gigabit passive optical network (GPON) initiated by FSAN in the year 2001 for designing networks over 1Gbps. GPON architecture offers converged data and voice services at up to 2.5 Gbps, and enables transport of multiple services in their native format, specifically TDM and data. GPON uses generic framing procedure (GFP) protocol to provide support for both voice and data oriented services. A big advantage of GPON over other schemes is that interfaces to all the main services are provided and in GFP enabled networks packets belonging to different protocols can be transmitted in their native formats.
EPON
Ethernet passive optical network (EPON) is one of the solutions considered by new IEEE 802.3ah in September 2004, focusing on direct support of Ethernet services. EPON uses CWDM and TDM to provide bi-directional and point-to-point communications over a fiber and maintains frame structure for both upstream and downstream. EPON standards networking community renamed the term ‘last mile’ to ‘first mile’ to symbolize its importance and significance as part of the access network. The system architecture is the same as GPON but data protocols are different.
PON Components
A PON generally consists of an optical line terminal (OLT) at the service provider’s CO (central office), a number of optical network units (ONUs) or optical network terminals (ONTs) near end users, passive optical splitters and transceivers.
OLTOLT: The optical line terminal is the main element of the network and it is usually placed in the Local Exchange and it’s the engine that drives FTTH system. OLT has two float directions: one is upstream getting distributing different type of data and voice traffic from users, the other is downstream getting data, voice and video traffic from metro network or from a long-haul networkand sending it to all ONT modules on the optical distribution network (ODN). The picture on the left shows an OLT.
ONTONU/ONT: Optical network terminals or units are deployed at customer’s premises. ONTs are connected to the OLT by means of optical fiber and no active elements are present in the link. A single ONT can serve as point of access for one or multiple customers and be deployed either at customer’s premises or on the street in a cabinet. The ONU usually communicates with an ONT, which may be a separate box that connects the PON to TV sets, telephones, computers, or a wireless router. The ONU or ONT can be the same device. The picture on the right shows an ONT.
PON Splitter: Passive optical splitters divide a single optical signal into multiple equal but lower-power signals, and distribute the signals to users. The final splitting ratio can be achieved using a single splitter device.
PON Transceiver: PON transceiver is generally a bi-directional device that uses different wavelengths to transmit and receive signals between the OLT at the CO and the ONUs at the end users’ premises over a single fiber. PON transceiver can be divided into OLT transceiver module and ONU transceiver module. OLT transceiver is typically more complex than ONU transceiver.
PON splitter & transceiver
PONs offer low cost connectivity for a large number of users with high security and relatively low management needs. Telecommunications companies use PONs to provide triple-play services including TV, VoIP phone, and Internet service to subscribers. A PON could also serve as a trunk between a larger system, such as a CATV system, and a neighborhood, building, or home Ethernet network on coaxial cable. As PONs grows into millions of homes, it can be seen that a new era of access networks is upon us. Fiberstore offers a series of high reliability and affordable fiber optical access devices for PONs, including OLT, ONU/ONT, PON splitters and transceivers, to meet customers’ fast growing demand of PON deployment.

Fiber Optic Tap Couplers for FTTx Systems

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

Maximizing the efficiency of optical line terminal (OLT) cards in passive optical networks (PON) in low-density and rural FTTx installations can be a major challenge. In most PON designs, it is considered ideal to connect 32 subscribers to a single OLT for maximum cost efficiency.

In rural installations, however, the density can range from a home every mile or two, to 20-30 homes scattered in random patterns. In these instances, connecting 32 users to a single OLT may be not be economical using standard optical splitters. Fortunately, tap splitters provide an easy method of maximizing OLT usage without being penalized by the number of subscribers connected.

Most PON networks use one of three physical topologies when using optical splitters.

  • The home run topology places the splitter within a service provider’s facility and is recommended for high density, short distance designs.
  • The centralized topology places a single 1:32 splitter in the OSP inside cabinet, pedestal, or even a splice closure.
  • The distributed topology has two or more splitters that are cascaded off one another, i.e., 1:2 x 1:4 x 1:4 = 32 subscribers.  It is this topology that provides the best solution.

A single 1:32 splitter adds an average of 15.8 dB of loss to the span, on top of the attenuation added by the fiber, splices, and connectors. In a standard distributed design, each 1:2 optical splitter would have a loss of 3.4 dB.  After the sixth 1:2 splitter, the total attenuation would be 20.4 dB.  After adding the fiber, splice, and connector attenuation values, the total loss would limit the number of subscribers to six or seven. Therefore, the OLT’s utilization rate would be only 20% rather than the desired optimum 100%.

For this reason, tap splitters offer a unique solution for low-density installations. These products can taper the split percentages in increments ranging from as low as 1/99 percent up to the standard 1:2 (50/50) types.  With a tap splitter in place, the cable near the first subscriber would have a drop cable spliced to the 1% leg of the splitter, and the other 99% of the optical power would be transmitted down the span.

As each subscriber would have different attenuation levels due to the splitter and span variations, a loss budget would need to be calculated for each subscriber between the OLT and their ONT. The maximum loss allowed per subscriber would vary as the distance from the OLT increases.  This — along with splitter attenuation differences based on the split percentage — requires attention to detail when planning the system.

This first subscribers on each fiber would use the 1/99 tap splitters until the loss budget required a larger split percentage such as a 2/98 splitter. The percentages would continue to increase to maintain the optical power level at the ONT until the last splitter is installed, which would normally be a 1:2 (50/50) split.

This technique helps to provide greater OLT utilization while still making use of standard OSP cables and closure products. Since tap splitters are the same size as most heat shrink protectors used to protect fusion splices, they can fit into standard splice trays, offering a cost effective technique for fiber access in low-density rural applications.