MPO Cable Testing Overview

Nowadays, the existing bandwidth is not adequate to meet enterprises’ increasing appetite. In the meanwhile, optical technologies like cloud computing, virtualization and storage area networks are all in the fast development, which pushes the further development of higher-bandwidth tech like 40/100G Ethernet. Thus under this circumstance, new devices are greatly required. Besides the new optical transceivers and fiber optic cables, a steady proliferation of fiber connections—MPO (Multifiber Push-On) came into being.

MPO cables, featured by its compact, pre-terminated advantages, has become the default cabling solution for the increasing bandwidth requirements. However, a flaw of the MPO cable may hinder its development. The testing process of the MPO cable can be complex and error-prone. Have you been through the scene? When you prepare to test a MPO cable, you have to throw polarity of all 12 fiber connections into the mix. And if it comes to migrating 10 Gbps to 40/100 Gbps on the same cable, all the testing job you have done is in vain. Since the testing process is pretty uneasy, The following text will provide some detailed information about it to help you do the right MPO cable testing.

 

Problems You Should Know About MPO Cable Testing

Typically, a MPO cable contains 12 optical fibers, and each fiber is thinner than human’s hair. So if you want to test the cable, you must test every fiber of it, which is quite difficult for inexperienced engineers. The common way to do this is to use a fan-out cord to make the 12 fibers separate, then testing. One fiber testing would take you 10 seconds. So if your customer ask you to test 48 MPO trunks cable in data center which has a 30,000-MPO data center installation, that means you need to spend 3,120 hours. Such a huge project! To avoid this expensive and time-consuming process, modular factory-terminated MPO cables promise simplicity, lower cost, and true plug-and-play fiber connectivity.

Additional, when you are about to test a MPO cable, you should check whether the MPO cable is in the good state. Because cables must be transported, stored, and later bent and pulled during installation in the data center, which may lead to the performance uncertainties before fiber cables are deployed. Proper testing of pre-terminated cables after installation is the only way to guarantee performance in a live application.

What’s more, fiber polarity is also an important factor you should take into account. The simple purpose of any polarity scheme is to provide a continuous connection from the link’s transmitter to the link’s receiver. For array connectors, TIA-568-C.0 defines three methods to accomplish this: Methods A, B and C. Deployment mistakes are common because these methods require a combination of patch cords with different polarity types.

The Relationship Between Bandwidth and Testing

The market trend of telecom industry implies that 10G network has already been deployed in a large scale. And now 40G is main stream. As for 100G, people also already prepare for it. So bandwidth would always be a hot topic.

We have said before that MPO cable can solve the problem of bandwidth. As data center bandwidth steadily climbs to 10, 40, and 100Gbps, a dense multi-fiber cable becomes the only option. That’s why the use of MPO cables has steadily risen over the past 10 years. With the MPO cabling system, 40/100G migration path seems to be a simple and easy solution. Just remove the 10Gbps cassette from the MPO cable and replace it with a bulkhead accommodating a 40Gbps connection. Later it might be possible to remove that bulkhead and do a direct MPO connection for 100 Gbps at a later date. Figure 2 shows a 40G connectivity with the use of the 12-fiber MPO cable. A 40G QSFP like QSFP-40G-SR4 connects to a 12-fiber MPO cable. A 12-fiber MPO fanout cable is also used to connect four 10G SFP+ transceivers like 46C3447 with a MPO FAP.

The problem is that while this migration strategy is an efficient way to leverage the existing cabling, in comparison to 10Gbps connections, the 40Gbps and 100Gbps standards call for different optical technology (parallel optics) and tighter loss parameters. In short, each time you migrate you need to verify the links to ensure the performance delivery the organization requires.

How to Do the Proper MPO Cable Testing

When you move to this part, you may think that MPO testing may be a tough obstacle for us to conquer. So is there a simple way to do the testing? The answer is yes. You can just test all 12 fibers—the whole cable—simultaneously and comprehensively (including loss and polarity). That sort of test capability changes the fiber landscape, enabling installers and technicians to efficiently validate and troubleshoot fiber—flying through the process by tackling an entire 12-fiber cable trunk with the push of a button.

To do a proper MPO cable testing, you must need some proper testing tools as shown in Figure 3. The tools to perform this type of test are emerging on the market, and promise to reduce the time and labor costs up to 95% over individual fiber tests. Characteristics to look for in such a tool include the following parts.

• An onboard MPO connector to eliminate the complexity and manual calculations associated with a fan-out cord.
• A single “Scan All” test function that delivers visual verification via an intuitive interface for all 12 MPO fibers in a connector.
• Built-in polarity verification for end-to-end connectivity of MPO trunk cables.
• “Select Individual Fiber” function that enables the user to troubleshoot a single fiber with more precision.

Summary

The insatiable need for bandwidth ensures that the integrity of the data center, which has also become inextricably linked to the strength of the fiber cabling infrastructure. Now more and more MPO trunk cables are put into use, to make sure the better performance, you should be able to test the MPO connection. Fiberstore offers a variety of MPO products including MPO trunk cables, MPO harness cable, 12-fiber or 24-fiber MPO cable and so on. All of our products can also be customized. Please feel free to contact us.

How to Minimize the limitations on the Transmission Distance

Transmission distance is the NO.1 factor that designers would take into account when deploying network because the exact transmission distance that fiber optic can support is usually limited by many factors. How to avoid this situation? Is there a method that can help us to achieve long transmission distance? This article today will pay attention to the factors that limit optical transmission distance and provide some practical solutions accordingly.

Optical Cable Type
The maximum transmission distance of fiber optic cable (single-mode or multi-mode fiber) is typical limited by dispersion. Multi-mode transmission is affected by the modal dispersion, while single-mode fiber is limited by chromatic dispersion. The core of the single-mode fiber optic is much smaller than that of multi-mode fiber. That’s why single-mode can transmit over longer distance than multi-mode fiber. Most designers should attach importance to review the specifications and limitations of transceivers and have them work optimally in their devices. Then it is highly recommended that we use multi-mode fiber optic transceivers for shorter distances and single-mode fiber for long distance transceivers. Take QFX-QSFP-40G-SR4 as an example, it is the compatible Juniper 40GBASE-SR4 QSFP+ transceiver that operates over multi-mode fiber. Although our application may call for an long reach, we can only use multi-mode fiber on this module for a distance of 150m. If you use an single-mode fiber on this transceiver, it may cause an error.

Light Source of Fiber Optic Transceiver
Optical signals must be converted into electronic signals over the optical transceiver because most of the devices are electric based. And the conversion between them is largely depend on a LED (light emitting diode) or a laser diode inside the optical transceiver. Fabry Perot (FP) laser, Distributed Feedback (DFB) laser and Vertical-Cavity Surface-Emitting (VCSEL) laser are the common type of light source inside the transceiver module that may have an impact on optical transmission distance. Table 1 present a comparison between these light sources, which would be a factor that designers should take into account when picking an optical transceiver to achieve long transceiver distance.

Splice and Optical Connectors
The signal loss can be caused when passing through fibers or connector, which will largely affect the transmission distance. Fusion splicing is the method of joining two optical fibers end-to-end using heat. Alternatives to fusion splicing include using optical fiber connectors or mechanical splices both of which have in general higher insertion losses, lower reliability and higher return losses than fusion splicing. Network designers nowadays choose to use fusion splicing because the goal of such a way that optical signal passing through the fibers is not attenuated or reflected back by the splice. In other word, fusion splicing will have less effect in the transmission distance that fiber optic cable can support. Here are some tips for fusion splicing that may help you.

1. Clean the fiber
2. Stripping the coating off the two fibers that will be spliced together
3. Cleaning of the stripped fiber
4. Each fiber must be cleaved so that its end-face is perfectly flat and perpendicular to the axis of the fiber
5. Aligning of two end-faces of the fibers. This is normally done by the splicing machine by means of: fixed V-groove, optical core alignment, cladding alignment or local injection and detection of light (LID)
6. The two fibers are fused together
7. Check mechanical strength of the splice (normally done by the splicing machine)
8. The bare fiber area around the splice is protected with a splice protector and use the same batch of high quality bare fiber on a route
9. Choose installers who have adequate training and rich experience in fiber connection

As noted above, the optical transmission distance is affected by a variety of factors, like fiber optic cable type, light source of transceiver, and splices and connectors. Frequency of transmission and bandwidth should also be considered to minimum the limitations on the transmission distance. I hope all the suggestions that I have provided above can help you to achieve long transmission distance. Fiberstore offers a variety of high-quality fiber optic cable and optical transceiver modules (like the popular 40G QSFP) that are fully tested. Meanwhile, components like repeater and optical amplifiers are also useful to support the long distance transmission. If you have any interest in our products, please contact us directly.

Reference:
http://www.cisco.com/c/en/us/products/collateral/interfaces-modules/transceiver-modules/white_paper_c11-463677.pdf

Fibre Channel Over Ethernet in the Data Center

Ethernet and Fibre Channel are the two typical networks that data center will utilize to present operational and maintenance issues. Traditional Ethernet is a family of frame-based computer networking technologies for local area networks (LANs), whereas Fibre Channel is used for storage area networking (SANs). Fiber over Ethernet (FCoE) is a storage networking protocol that supports Fibre Channel over Ethernet. This article will provide an overview of FCoE, describe the importance to data center that make up the new ecosystem, and explains how the technology is developed today.

What Is FCoE?
Today’s network use different protocols to send information between devices, FCoE is a newly proposed standard that encapsulates Fibre Channel frames into an Ethernet frame at the server (Figure 1), allowing them to run alongside traditional Internet Protocol (IP) traffic. The server encapsulates Fibre Channel frames into Ethernet frames before sending them over the LAN and de-encapsulates them when FCoE frames are received. Server I/O consolidation combines the NIC and host bus adapter (HBA) cards into a single converged network adapter (CNA), which reduces server cabling and power/cooling needs. At present, the Ethernet frame is removed at the Ethernet edge switch to access the Fibre Channel frame, which is then transported to the SAN.

FCoE combined with the advent of 10 Gigabit Ethernet (10 GE) fabrics will grant companies the ability to consolidate their I/O, cables, and adapters while at the same time increase the utilization of their servers. Conceptually FCoE can be broken down into three components: encapsulation of a Native Fibre Channel Frame into an Ethernet frame , the extension of Ethernet to become a lossless fabric, the replacing of a Fibre Channel link with MAC addresses in a lossless Ethernet fabric.

Why Is FCoE Important to the Data Center? 
I/O consolidation is simple in concept: the sharing of both Fibre Channel and Ethernet traffic on the same physical cable or in cases that network isolation is desired, the flexibility to use and configure the same hardware for either type of network load. The benefits end-users will realize from this simple idea are significant. Companies that leverage I/O consolidation will be able to realize significant gains in server slot efficiency with the use of multi-function network/storage. These benefits are further detailed below.

I/O consolidation means a customer can use multi-function network/storage adapters in place of single-function network-specific and storage-specific cards, thereby reducing the number of server slots and switch ports, as well as reducing the number of power consumed for I/O and necessary cooling. This also results in fewer points of management administrators will have to control. A reduction in NICs through I/O consolidation has an additional important advantage. The ability to cool a set amount of heat generated per rack is the primary barrier to data-center expansion and inefficiency encountered today. Reducing the amount of NICs in servers can reduce the amount of heat those servers generate.

Looking Ahead 
As enterprise data centers converge Ethernet and Fibre Channel networks, they can improve performance and reduce power consumption, infrastructure complexity, and cost. The Third generation FCoE architecture with the exception that the core switch now forwards the FCoE frame directly to storage where the Fibre Channel frame is accessed. This architecture solution reduces the server interconnect cabling and adapter card number by at least 50 percent, eliminates the Fibre Channel HBA to SAN optical fiber trunk cable and eliminates the core switch to SAN director fiber trunk cable. Optical connectivity shall be in accordance with IEEE 802.3ae (10GBASE-SR) utilizing OM3 optical fiber.

Summary
FCoE offers a data center unified fabric solution that simplifies operational and maintenance of the cabling infrastructure. FCoE facilitates utilization of low-cost Ethernet electronics and OM3 or OM4 optical connectivity to support 10, 40 and 100 Gigabit data rates. Fiberstore has great advantage of 1000BASE-T/SX/LX SFP, BiDi SFP, 10GBASE-SR/LR SFP+, DWDM SFP+, whole series 40G QSFP+ optics and cables, as well as the 100G CFP2 and CFP4, etc. which help you solve the cost issue in fiber project. Especially the 40G QSFP optics, with the passive optic design, they can be compatible with all the equipment of all major brands.

Reference:
http://www.cisco.com/c/dam/en/us/solutions/collateral/data-center-virtualization/ieee-802-1-data-center-bridging/white_paper_FCIAFCoE.pdf