THE DATA CENTER JOURNAL | 23 www.datacenterjournal.com

TOTAL DATA CENTER ENERGY CONSUMPTION

Support systems

ITequipment

In today’s always-on, always efficient data center environments, it’s easy to get caught up in the numbers, especially when it comes to UPS performance.

High efficiency is now a standard in UPS design, but selecting the system with the biggest savings potential requires you to take a close look at the fine print. With newer eco-mode models advertising efficiency as high as 99 percent, it pays to know what is real and what is fantasy.

Following are three things you need to know when selecting your UPS system and managing it to achieve real energy savings.

Avoid the ratings gameThanks to advances in UPS technology, the potential to cut energy costs by tens of thousands of dollars annually has never been greater. But it’s not going to happen because you bought the 99% efficient UPS system versus the one that’s 97% efficient. While efficiency ratings matter, the high numbers advertised are based on full load levels — something the vast majority of data centers never see in their lifetime.

Bottom line: Don’t assume the UPS with the highest efficiency rating will cut total cost of ownership the most. Make it part of your decision making process, but not the determining factor.

Higher voltage = bigger savingsIt might sound strange to think that upping your power distribution voltage can actually save energy, but it can — and a lot of it. In most data centers, the UPS delivers power to the server at 208V. By raising your voltage to 240V, you can expect energy savings of 2% or more, depending on the power distribution configuration.

Bottom line: Higher voltage is a good thing, and most data centers are equipped to handle it. However, not all UPS systems are, so select one that can provide higher voltage.

By the Numbers48% Energy use of infrastructure equipment —

cooling, UPS, PDU and lighting

56% Growth rate of electricity consumption globally between 2005 and 2010

$6K Estimated cost to operate a server annually in a typical data center

6-7% Estimated savings achieved by deploying a UPS with higher voltage and Intelligent Eco-mode Source: Energy Logic © 2008, 2012

Think eco-intelligent Eco-mode has done wonders for improving UPS efficiency, but it comes with a cost: Some methods of switching to eco-mode and back again may leave availability vulnerable. To address this issue, Emerson Network Power offers an improved version called Intelligent Eco-mode.™ This advanced technology employs an active inverter to create an almost seamless transfer of power with a smooth waveform. While the power requirements are fractionally higher than other methods, the result is an estimated 4% to 5% energy savings over standard operation, all without compromising availability.

Bottom line: To maximize energy savings and maintain reliability, select a UPS with Intelligent Eco-mode.

Got a power management question for Peter or want a complete UPS selection checklist? Visit knowUPS.com.

The Liebert NXL™ from Emerson Network Power is one of the most efficient and reliable high-power UPS systems available, due to features such as Intelligent Eco-mode™ and active inverter technology.

Eco-mode EconomicsIs your high-efficiency UPS really that eco-nomic? By Peter Panfil, Vice President Liebert AC Power, Emerson Network Power

Advertorial

EM0112b_12401.indd 1 9/18/12 2:46 PM

IT CORNER

Next Generation Optical Fiber Connectivity Solutions for the Mission Critical Data CenterBY BILL CHARUK

As today’s evolving data centers confront bandwidth capac-ity challenges, the migration from 10 gigabits per second (Gb/s)to 40 and 100 Gb/s,

and higher density and cloud comput-ing requirements , choosing the correct connectivity method has never been more important to meet the demands for opti-mum reliability, performance, scalability, cost effectiveness, and time to restoration. Various research studies assert that the physical layer accounts for nearly 60 to 80% of network downtime, elevating connectiv-ity from an important focus to a mission critical and crucial decision.

As the data center evolves with growing challenges, so must the connectiv-ity solutions evolve simultaneously and harmoniously to resolve those challenges. Therefore, optical fiber and connectivity manufacturers have innovated the next generation connectivity solution the field installable splice-on connector or SOC.

The splice-on connector (MPO, SC, LC, FC, ST) has now been added to the mix of familiar legacy field installable connec-tivity methods still widely used:

• Field installable (puck and polish) connectors,

• Pre-polished/Mechanical connectors• Factory Pre-terminated cable

assemblies

To make an educated connectiv-ity decision, it is important to become familiar with the splice-on connector and to evaluate the advantages and disadvan-tages of each popular connectivity method deployed today as they pertain to the high density data center environment and ac-cording to the following major criteria:

• Performance and reliability for mul-timode and single-mode fiber types

• Flexibility, speed, and ease of use for fiber installations and cable builds, MACs, and restoration

• Scalability and future proofing

Within the examination of the connector methods, references to cost effectiveness are also made, providing the essential information with which to deter-mine the correct connectivity decision to meet the needs of the data center today and tomorrow.

PERFORMANCE AND RELIABILITY

To determine any methodology’s appropri-ateness for a network, industry standards and specifications must be considered. Table 1 shows the current allowable con-nection and channel insertion loss for next generation systems operating at 40 or 100 Gigabits per second. Notice the low loss requirements for the connections in the optical pathway.

The last highlighted column lists the allowable connection loss budget that comprises a cumulative loss based upon fiber, lengths, channel insertion and other specific characteristics and, not connector loss (i.e. the total loss of a mated pair of connectors). All connector methods used in data centers need to meet these specifica-tions to allow for seamless system upgrades to the next generation speeds and to ensure that the network will work reliably over the installed fiber optic link.

The field installable puck and polish method’s advantages can be rapid deploy-ment in the field and low cost. Its success, however, depends on the experience of the

Data Rate Designation Mb/s Fiber Type

Number of Fibers

Max Link Length (Meters)

Max Channel Insertion Loss (dB)

Allowable Connection Loss Budget (dB)

40-Gbe 40GBase-SR4 40,000 OM3 8 100 1.9 1.5

40-Gbe 40GBase-SR4 40,000 OM4 8 150 1.5 1.0

100-Gbe 100GBase-SR10 100,000 OM3 20 100 1.9 1.5

100-Gbe 100GBase-SR10 100,000 OM4 20 150 1.5 1.0

Table 1: Channel Insertion Loss and Connection Loss Budgets for 40G and 100G Systems

24 | THE DATA CENTER JOURNAL www.datacenterjournal.com

installer and requires a fairly high skill set to achieve required insertion and return loss performance by hand polishing the end face of the ferrule to precisely the correct angle. Limitations include use of epoxies, an average 10% failure rate in large projects due to human error and fatigue, limited viability in single-mode systems, and often unacceptable return loss for APC (angled polish connectors). Another disadvantage is that puck and polish connectors are blind terminations, for which no actual or esti-mated loss associated with the connector is available until the full link is completed and personnel are in place at both ends of the link to complete power through testing.

The mechanical connector method aligns a cleaved fiber with a pre-polished stub and utilizes a cam or crimp mecha-nism to mechanically splice the fibers. The advantages of this termination method include installation speed, low skill set, and the factory polished and inspected end face. Unlike the puck and polish method, these relatively expensive connectors offer various end face polishes from the factory, which are tested prior to use. The major disadvantage to this method is the reflec-tance and attenuation associated with the mechanical splice. To combat this, index matching gel is used to ensure reflections do not occur.

However, this also presents a risk to the data center systems. The refractive index of index matching gel is temperature dependent. Figure 2 shows the relationship between temperature and the return loss as a function of the refractive index of the gel. Obviously, when the data center systems are operating normally, the performance of index matching gel is a low risk. If the data center should experience a temperature ex-cursion, the gel may not be able to maintain system optical integrity or could even begin to flow out of the connector.

While a data center may never see these temperatures, it is prudent to design the optical network in such a manner where this will not be a possible outcome of a temperature excursion due to loss of cooling capability, even for brief periods. Another consideration is that this method is also a blind termination process, requiring additional test equipment and time to test.

Pre-terminated cable assemblies offer strong advantages, primarily the installed

connectors that have been tested to meet attenuation performance standards. They also do not require any skill, other than connector cleaning, for use.

Unfortunately, this solution has non-technical drawbacks that make them an expensive and inconvenient solution for the data center. The pre-terminated cable method is costly when ordered from the factory. With space at a premium, storage of cable slack can be problematic. Even when the lengths are engineered, the addi-tion of a small amount of cable length can lead to storage issues over time.

The next generation solution, the splice-on connector (MPO, SC, LC, ST), is a hybrid technology consisting of a pre-polished connector (APC, UPC, PC) and fiber stub that can be fusion spliced directly on the end of an optical fiber.

Essentially, the SOC provides the advantages of a pigtail without the negative inventory or storage issues for a splice tray or cable slack. The SOC also takes advan-

tage of a factory polished end face that has been tested for attenuation and inspected for other defects. The use of fusion splicing is an advantage in and of itself in that there is no serious question in the industry of the fusion splice’s quality for reduced attenu-ation and the elimination of reflectance. When the fusion splice is hermitically sealed within the heat shrink or protective sleeve, an ultra reliable optical fiber termi-nation is achieved that is more robust and optically superior to the mechanical splice.

The SOC, in effect, is a connector/pigtail that generates a factory-quality connection in a field installable method. The connector can be attached directly to a 250 micron or 900 micron buffered fiber, affording the flexibility for customized on-site cable builds at exact lengths, while eliminating the limitations of factory pre-terminated cables.

To install this connector, today’s easy to use, low skill fusion splicer with the appropriate fiber/connector holders is

Figure 2: Return Loss and Refractive Index as a Function of Temperature

Image 1: LC, SOC Components

THE DATA CENTER JOURNAL | 25 www.datacenterjournal.com

required. As backward compatibility with existing fusion splicers allows for more widespread adoption of this technology, connector jigs have been developed to retro-fit on many popular fusion splicers already owned by many installers.

In addition to the factory polished end face, there are other major advantages. First, by using a fusion splicer with splice loss estimation capability, the technician can overcome the blind splice and get a reading of the estimated splice loss before actually fusing the fiber onto the pre-cleaved fiber stub of the connector. This step increases both productivity and yield while imme-diately ensuring acceptable insertion loss within specified tolerances. Figures 3 and 4 show the comparative performance results of the various connector methodologies.

FLEXIBILITY, SPEED, AND EASE OF USE FOR FIBER INSTALLATIONS AND CABLE BUILDS, MACS, AND RESTORATION

The data center is a unique environ-ment within the enterprise network. The data center is the only network where speed, reliability, security and optical performance must remain uncompromised at all times. This is true during initial installations of op-tical links, repairs and restorations, moves, and any changes or rerouting that may oc-cur over the life of the data center.

Next generation technologies have the overall advantage of having solved the limitations of preceding technologies. Like-wise, the splice-on connector has essentially

eliminated the weaknesses of the connec-tor methods having preceded it. By using the fusion splicer with immediate perfor-mance feedback, the SOC solves the blind terminations and blind splices, along with the problematic epoxies, associated with the puck and polish and mechanical connector methods to improve speed, productivity and performance. Also, the SOC comes in all varieties of needed connector types and polishes not all made available by these methods.

The SOC also solves the major limita-tions of pre-terminated cables by eliminat-ing the shorts, excess slack, storage, pulling terminated cables through conduit that can damage the connectors, and logistic delays associated with this method. Pre-terminated cables are often used in emergency repair situations and are ordered for same day or next day delivery. Significant downtime of the optical path is possible when waiting for delivery of the assembly. If inventory is kept on site for these occurrences, having the correct length of jumper will result in high inventory costs. Similarly, the pre-terminated cable method slows down immediate data center moves, adds, and changes (MACs) while continually adding to project costs.

With the SOC, exact cable builds can be now be accomplished on-site quickly and easily, as well as repairs, restorations, and any MACs crucial to the data center. If a new optical link needs to be established or an old one repaired, one end of an optical cable can be connectorized. The cable can then be easily routed to the termination point within the data center without having to be concerned about damaging connec-tors during the installation. The second end can then be terminated at the exact required length so there is no additional slack needed to be stored anywhere along the pathway.

Figure 3: Insertion Loss Comparison

Figure 4: Return Loss Comparison

The data center is a unique environment within the enterprise network. The data center is the only network where speed, reliability, security and optical performance must remain uncompromised at all times. This is true during initial installations of optical links, repairs and restorations, moves, and any changes or rerouting that may occur over the life of the data center.

www.datacenterjournal.com26 | THE DATA CENTER JOURNAL

Whether the case is installing new equipment requiring new type of connec-tors or addressing any MACs, the fusion splice-on connector allows for real-time scalability and upgrades. The technician can exchange connector types and build customized cable assemblies on-site in minutes, thereby eliminating dependency on the factory and its related logistical de-lays and costs. The same applies for quick restorations.

Since the fusion splicer completes the connection operation, all the techni-cian needs to do is move the SOC from the splice area, move the heat shrink protection sleeve over the splice and place it in the curing oven on the splicer. Assembly of the final connector is simple; slide the connec-tor housing over the ferrule assembly and capture the strength yarns on the backside of the connector; the total process of a single fiber termination takes less than three minutes to complete.

SCALABILITY AND FUTURE PROOFING TO MEET THE NEEDS OF THE DATA CENTER TODAY AND TOMORROW

To ensure the high-density and 40 and 100 Gigabit speed migration of the data center, which requires at least six to 12 times more fiber, the next-generation MPO SOC connector has been developed. Until recently, the MPO has typically been installed in a factory and shipped to the field, since no puck and polish versions exist. With the escalated use of high precision mass fusion splicers, MPO SOCs are able to be field installed with very high qual-ity and reliability. The immediate on-site scalability of the SOC to custom-ize the optical fiber

infrastructure of the data center ensures an already future-proofed data center network.

The MPO version enjoys the same advantages of the single fiber connec-tor. Depending on the type of cable to be terminated, productivity and speed for fiber installations, MACs, and restora-tion are greatly improved. For example, terminating 12 fibers simultaneously on a ribbon cable versus twelve individual LC connectors on 3mm single fiber cable can save approximately 86% on installation

time. Chart 1 below shows a comparison of installation times using an MPO SOC con-nector versus single fiber connections on 3mm cable and 900 micron fiber. Chart 1 shows that as the fiber counts increase, the time savings increase dramatically when using the MPO SOC. Of course, to be a viable solution, the methodology must meet industry stan-dards for optical pathways. In Table 2, the initial Table 1outlining network standards is revisited and now includes the maxi-

Image 2: MPO SOC Components

Chart 1: Termination Time Study MPO Versus Single Fiber Solutions for Various Fiber Counts

THE DATA CENTER JOURNAL | 27 www.datacenterjournal.com

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IntroducingÊtheÊRevolutionaryÊ4thÊLevelÊDataÊCenterÊSolutionÉEnablingÊFlexibleÉÊReal-TimeÉÊOn-SiteÉOpticalÊFiberÊInfrastructureÊDesignOptimum Performance • Immediate Scalability • Faster Moves, Adds & Changes •Real-Time Cable Builds • Faster Restorations • Less Downtime…and more

Contact Customer Service Today at 800-358-7378info@sumitomoelectric.com | www.sumitomoelectric.com

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Data Rate Designation Mb/s Fiber Type

Number of Fibers

Max Link Length (Meters)

Max Channel Insertion Loss (dB)

Allowable Connection Loss Budget (dB)

LYNX2 MPO SOC Maximum Loss (dB)

40-Gbit Ethernet 40GBase-SR4 40,000 OM3 8 100 1.9 1.5 ≤0.70

40-Gbit Ethernet 40GBase-SR4 40,000 OM4 8 150 1.5 1.0 ≤0.70

100-Gbit Ethernet 100GBase-SR10 100,000 OM3 20 100 1.9 1.5 ≤0.70

100-Gbit Ethernet 100GBase-SR10 100,000 OM4 20 150 1.5 1.0 ≤0.70

mum expected connector loss for the MPO SOC. It is clear from the data presented that there exists ample headroom for ad-ditional splices in the system and still be able to meet the end to end loss budgets required for 40G/100G transmission. The MPO SOC complies to US: EIA/TIA-604-5, FOCIS 5 and International: IECX-61754-7 standards.

CONCLUSION

Next generation data centers require next generation connectivity solutions. By combining the advantages of legacy con-

nection technologies into one which uses the latest advancements in fusion splicer technology, the splice-on connector enables rapid, high quality connectivity with the speed, performance, and immediate scal-ability required by today’s evolving data center. As fiber counts continue to increase with the advent of 40G and 100G transmis-sion schemes, installation of single and MPO connectors in the field, resulting in excellent optical integrity, will be a require-ment for optimum customer service and reduced operating costs, while lowering risks associated with legacy methodology and connector design. Finally, the MPO

SOC is ready to support the coming higher speed networks, which will one day become ubiquitous in the data center and allow for graceful growth when further advance-ments in network transmissions continue to emerge.n

About the Author: With over 20 years of experience in the communications and information industry, Bill Charuk serves as senior technical manager for Sumitomo Electric Lightwave (www.sumitomoelectric.com), overseeing its Data Center Solutions division. Bill can be reached at bcharuk@sumitomoelectric.com.

Table 2: Network Specifications as They Relate to Limiting Case MPO SOC Connector.