Test and Troubleshooting Guide for Optical Fiber Cabling and
Contents
1. Advanced troubleshooting OptiFiber Pro offers advanced troubleshooting features When a test is completed the window shows the event with the worst measurement If the border is green the measurements for the event don t exceed limits If the border is red a measurement exceeds the limits If the border is blue the tester doesn t assign a pass or fail result because it can t do a full analysis This occurs for OTDR Port Hidden and End events When you use a test limit with a reflectance limit Hidden events show a fail status if their reflectance exceeds the limit To see details for the event tap the window To see information for another event tap another icon on the map Note Events before the launch cord connector and after the tail cord connector don t have a pass or fail status Bail iy Lied fiat TABLE Fiber Length 20837 m Fiber Length 155 78 m Overall Logs 1 92 46 io m Overall Loss 1 01 d 51 24 m alda eee ru L Lid mi aim T k ll m Fikr Trp OM Mutia B Teel Lirik AELTIE IE 057 Figure 22 EventMap diagnostics The optional video probe connects to the USBA port on the OptiFiber Pro tester to let you inspect the end faces in fiber optic connectors The probe lets you see dirt scratches and other defects that can cause unsatisfactory performance or failures in fiber optic networks a Turn ON the OptiFiber Pro You will see the Home screen2. s u u nnsul Sunoous lqnoli pue 3s l sq qid 5 yni xipu ddy 195 1591 5501 SHA 3s L d qiq 220 00 1 pue H lN 1 MOd Old ID x q Old s qluildulis s r BuiueayD ndo 4036201 Ne4 JEnsiA 1nE4IS A FLUKE networks For more information please visit www flukenetworks com Your authorized Fluke Networks distributor Fluke Networks Box 777 Everett WA USA 98206 0777 Fluke Networks operates in more than 50 coun tries worldwide To find your local office contact details go to www flukenetworks com contact 2012 Fluke Corporation All rights reserved Printed in U S A 9 2012 3481323C r
3. Plug the SC adapter with red boot plugs into the transmitter OUT connection Do not unplug red boot on source after setting the reference After the reference is set do NOT disconnect TRC from light source For a multimode optical link use the proper mandrel Reference must be reset after the units are powered down Maintain precise launch conditions of the reference 3 Run an autotest Select Autotest The test standard you select for an Autotest determines the test parameters and the Pass Fail criteria for each test Polarity A successful Autotest using the DTX Fiber Modules ensures polarity Connect the black boot of the TRC to the fiber in the link under test transmitting the light This end of the link needs to be connected to the transmitter of the network device Light leaves the TRC at the black boot The red boot end of that cord is con nected to the output on the tester Connect the red boot of the TRC to the fiber in the link under test receiving the light from the other end of the link e When the connections to the link under test are established the instrument will chirp a happy tone to indicate connectivity has been established and the polarity of the link is good Length The tester measures the length as well as the link loss When you select an application standard during the setup it includes the maximum length for the application depending on the bandwidth rating of fiber used in the link
4. and explain it For example in figure 11 an experienced eye can spot that one side of a cross connect shows excessive loss e Event analysis software The latest OTDRs run sophisticated software that automates trace analysis and set up of test parameters Fluke Networks OTDRs can automatically choose setup parameters not only telling you where events instances of reflectance and loss are on the trace but also indicating what the events are and qualifying each of them 130m 7m 80 m Figure 11 Sample OTDR trace with high loss connector at 137m Dead zone The length after a connector splice break or macro bend along the fiber cabling where the OTDR can make an attenuation measurement or differentiate between closely spaced events such as connectors Event dead zone is the minimum distance between two consecutive reflective events that the OTDR can make a measurement At tenuation dead zone is the minimum distance after a reflective event that the OTDR can make a loss measurement Dynamic range Determines the length of fiber that can be tested The higher the dynamic range the longer the fiber under test can be However as the dynamic range increases the wider the OTDR pulse becomes and as a result the dead zone increases Ghosts Not as scary as they might seem ghosting is caused by an echo due to highly reflective events in the link under test Fluke Networks OTDRs identify ghosts on the trace and tell you where
5. select Tools see figure 23 b Connect the Inspector Probe to the USB port to OptiFiber Pro c Tap Tools Aisin Tt of TEST Figure 23 Main Menu Tools Option a Hu netvvorks The FaultMap test shown in Figure 24 helps you record the connections in a fiber link and identify bad connections It can show short patch cords and find connections that have high reflectance The FaultMap test gives you these results Shows a map of the connectors in the link might not show on the OTDR EventMap The map includes connectors that are hidden in the dead zones made by previous events The FaultMap test shows patch cords as short as 0 5 m for lengths lt 2 km e Highlights connections that are poor due to high reflectance gt 35 dB Reflective events that are apparently not connectors don t show on the FaultMap diagram Loss events are also not shown The FaultMap test finds events that have a reflectance larger than approximately 50 dB on multimode fiber and 60 dB on singlemode fiber More negative values mean less reflectance and a better connection For example a connector with a reflectance of 40 dB is better than one with 35 dB Troubleshooting basics There are simple ways to avoid complex trouble shooting exercises If you follow these best prac tices you won t spend as much time fault finding and performing OTDR analysis Keep it clean Dirty connections are the bi
6. When testing a fiber link or channel change the wavelength easily to view the trace Zoom in to see detail loss info and event characteristics e Jump to next previous event e Pinch to zoom out e Reverse pinch to zoom in e Drag to move the trace e Slide to adjust x or y zoom e Double tap to zoom to 100 Aruh nam Eveaithag hm LA a ili G nmw Q en amp g 650 Figure 14 OptiFiber Pro TRACE example As mentioned at the beginning of this section there are different types of OTDRs avail able The OptiFiber Pro OTDR with its advanced feature set and capabilities would be an excellent choice for certifying enterprise fiber cabling But since many contractors and network owners use the DTX Compact OTDR for closet to closet certification we will demonstrate how to perform this type of testing with the DIX CableAnalyzer view Figure 15 Connecting OTDRs to installed fiber using launch fiber compensation OTDR certification set up OTDR Results Setting up for OTDR Certification Testing eee FHBL LIMIT Penne Turn the rotary to Setup and choose Multimode 50 Settings from menus in five setup screens Dual 850 1300 nm 1 First select which port you want to test from End 1 DATA CENTER multimode or singlemode which test limit you want to use the fiber type and desired wavelength It is possible to create multi
7. hygiene Dust fingerprints and other oily contamination cause excessive loss and permanent damage to connector end faces Too many connections in a channel Simple but it is important to consider the total allowable loss per intended application standard and typical loss for connector type during the design process Even if the connectors are properly terminated if there are too many in a channel the loss may exceed specifications Misalignment The best way to achieve good fiber alignment 15 to fuse the two fibers together with a precision splicing machine But for several practical reasons connection of fibers is often done mechanically There are many commercially available connector types and all have their advantages and disadvantages Typical loss specifications are a good proxy for how well they can to align fibers Specifications used for data communi cations should be compliant with Fiber Optic Connector Intermatibility Standard FOCIS standards Poor quality connectors or faulty termination Good quality connectors have very tight tolerances in order to maintain precise alignment End face geometry Performance of fiber optic connectors is largely a function of the geometry of the end face This geometry can be measured in a laboratory with precision interferometry equipment In the field the following parameters are inferred in loss and reflectance measurements Roughness Scratches pits and chips produce excess lo
8. need to certify singlemode fiber use the DTX SFM2 modules a Once the tester is turned on turn the rotary Kol dial to Setup and select 04 16 2009 5 15 52 p m 2 Twisted Pair Instrument Settings to input the operator R name job name etc e pee b Select Fiber Loss from the Setup screen as Fiber OTDR shown in figure 2 Under this setup screen Network Settings choose from a menu of standards to select Instrument Settings the correct limits Select the Test Limit option as shown in figure 3 Note that the selected fiber type limits the test limit choices Popular fiber types are also included in the instrument a Highlight item Press ENTER menu Figure 2 As figure 3 shovvs the same setup screen allovvs Fiber Loss you to select the Remote End Setup When using 1 Ee the DTX Smart Remote equipped with the fiber test module select Smart Remote as we have done in MS ZA a this example In this mode the tester automati un OFS LaserWave 300 50 cally measures the length of the link under test Remote End Setup Smart Remote Bi Directional Wo Lastly this screen allows you to tell the tester whether you need to test the link under test in both directions If this is the case remember never to disconnect the test reference cord TRC from ya na a Highlight item the test modules Always swap the TRC at the con press ENTER nection with the link under test Choose a referen
9. ties or bend radius violations result in excessive and unexpected loss e Breaks Light will no longer propagate past a location where the glass is crushed or cracked in an optical fiber e Intersymbol interference ISI Disturbed Signal is usually the result of poor system design A system that isn t certified with the application standard in mind is suscep tible to ISI Modal dispersion from violation of distance limitations on multimode fibers Reflections from too many highly reflective connectors cause increased bit errors due to excessive return loss Simple fault finding Continuity and polarity problems from breaks or unlatched connectors are common and sometimes difficult to locate and identify with loss testers Visual fault locators and optical fault finders like FlukeNetworks Fiber QuickMap and Fiber OneShot PRO are recom mended to find breaks or unplugged connectors in a fiber link A fiber troubleshooter quickly and efficiently locates connections and breaks in either mul timode or singlemode fiber As single ended testers launch cables are recommended Simply plug the Fiber QuickMap shown at right into one end of a fiber channel and press Test but ton to reveal locations of incidents of interest confirm channel connectivity and distance to failures Lasers such as the VisiFault provide the simplest troubleshooting Just shine it down a fiber link and check the far end or visual signs of high loss
10. yet easiest to prevent causes of failure damaged and dirty fiber end faces Damage occurs in the form of chips scratches cracks and pits to the core or cladding and can result from mating contaminated end faces Tiny foreign debris left on the core can also damage end faces as they are connected together during the mating process As alluded to earlier sources of contamination are everywhere whether from the touch of a finger or the brush of clothing much less the omnipresent dust or static charged parti cles in the air Ports are also subject to the same contamination but are often overlooked Mating a clean connector to a dirty port not only contaminates the previously clean con nector but can also cause fiber damage or failure Even the protective coverings or dust caps on straight from the package connectors and assemblies can cause contamination due to the nature of the production process and materials Many people assume a quick visual check of the end faces is sufficient to verify cleanli ness As mentioned previously the cores of these fibers are extremely small ranging from roughly 9 to 62 5 um Put into perspective with a diameter of 90 um the average human hair is anywhere from 1 5 to 9 times larger With such a tiny core size it s impossible for end face defects to be spotted without the aid of a microscope See figure 25 and 26 for set up and end face examples There are two types of fiber inspection m
11. 7777177 7 25 Conclusion a da be On ao eee Sar ee Kee Ba 26 GLOSSA bid Hey on 0000 27 Appendix Fluke Networks Fiber Test and Troubleshooting Instruments 28 1 Introduction As fiber links support higher speed network bandwidths with increasingly stringent requirements it s becoming more important to ensure your backbone links meet tightening loss standards The need for higher data transmission capacity continues to increase as net work applications grow and expand These higher transmission speeds demand cabling that delivers increased bandwidth support This test and troubleshooting guide outlines cabling performance requirements field testing certification and troubleshooting techniques and instruments to ensure the installed optical fiber cabling supports high data rate applications such as 1 and 10 Gigabit per second Gbps Ethernet Fibre Channel and 40 and 100 Gbps Ethernet applications A local area network LAN or an enterprise premises network typically connects users up to a distance of 5 km It encompasses intra building connectivity as well as inter building or campus cabling Optical fiber cabling is pnmarily used for longer distance higher band width connectivity while twisted pair copper cabling typically provides the connection to the end user or edge devices This copper cabling can support network connectivity to a distance of 100 meters 328 feet Optical fib
12. Cabling installation is a multi step process It is prudent to certify the cabling system after installation to ensure all installed links meet the expected level of performance Cer tification will likely identify some failing or marginally passing results In order to deliver a high quality cabling system defects that cause failures and marginal passes must be uncovered and corrected Fluke Networks full suite of fiber certification instruments Appendix 2 has an unparal leled history of providing unique and powerful diagnostics assistance to installation technicians By knowing the nature of typical faults and how the tester s diagnostics report them you can significantly reduce the time to correct an anomaly an installation error or a defective component Personnel responsible for network operation also benefit from the diagnostic capabilities of a certification test tool by reducing network downtime We recommend you familiarize yourself with the capabilities of your test tool It truly is modest investment that pays for itself many times over In addition to your precision instrument Fluke Networks also provides a wide variety of expert and timely support op tions Whether you are an installer network owner or contractor the following resources are available e White papers and Knowledge Base articles insightful studies and helpful advice on relevant structured cabling topics e Unsurpassed technical assistance from the highly
13. Test Set a baseline Tier 1 certification instrument that measures the loss of a link over its length LSPM Light Source Power Meter basic fiber verification instrument composed of a power meter and a source to measure loss over a link TRC Test Reference Cord a high quality fiber cord 1 to 3 meters long with high performance connectors ideally with end faces with special scratch resistant hard ened surfaces that enable numerous insertions without degradation in loss performance VCSEL Vertical Cavity Surface Emitting Laser commonly used in multimode light sources Verification testing the process of testing the transmission performance of an installed cabling system to ensure it meets a minimum threshold VFL Visual Fault Locator optical source that transmits a low powered laser to identify breaks in fiber links ue Jase ue ase NsaJ 1591 JUaWINIOG SHNS I Ley sseg Z JILL sjUaWainseaw SSO 1 JNSL W S U9A9 SSO pue suon uuo ld nul 2 S31nE 35201 2 T LL bus 5501 s qu lenq p p x you yabpnq sso insu 0 UL 19A0 SSO L A bepulep uoyeurwezuo Jaqy 40 2 lpol daro pedwo yum 1 q 4 YUM old JaqI4ndO JazAjeuy 3 qe gt JazAjeuyajqe gt s do so 511 4 O PHA 024 Jopadsupiaqi4 Df
14. atic charged particles equally detrimental in causing failures Clean fiber end face Contaminated fiber end face Figure 29 Comparison between a clean and dirty fiber end face The same problem occurs when using shirt sleeves or clean cloths to wipe connectors In fact the trace amounts of lint and dust attracting static from these materials will likely add contamination rather than reduce it Even isopropyl alcohol IPA which has histori cally been an acceptable solvent is proving to be inferior to specially formulated solu tions 5 inability to dissolve non ionic compounds such as pulling lube and buffer gel and the residue it leaves after evaporation make engineered solvents the superior choice When using these solvents the proper cleaning order is wet to dry using clean lint free wipes Figure 30 Figure 30 Wet to dry cleaning methodology Ap ply a small spot of solvent to the starting edge of a wipe Holding the end face connector perpendicularly swipe the end face from the wet spot to the dry zone Cleaning resources vary in complexity and price ranging from simple wipes to devices that incorporate ultrasound with water Which tool you use depends on need and budget But for the majority of the cabling jobs and projects lint free wipes and swabs with engi neered solvents now found in fiber inspection certification and cleaning kits will be sufficient 7 Conclusion
15. b 4 j KWEK j d L I a J la yo J i FEL d he a 1 ln ra T s C a A a gt E PERF r I 1i IES L 2 z r Test and Troubleshooting Guide for Optical Fiber Cabling and DataCommunicat ions Table of Contents 1 Introduction l Ba r b aaa a Body 5 Fiber Verification Testing 6 How to Certify Optical Fiber Cabling with OLTS and LSPM 7 How to Certify Optical Fiber Cabling with an OTDR 13 OTDR built specifically for the enterprise 14 OTDR certification set up 17 e Summary of extended certification 18 e Cable certification test strategy 19 Finding and Analyzing Fiber Cabling Faults 20 S uc 11000 0 0 20 Simple fault finding 21 Advanced troubleshootinq 22 Troubleshooting basics 23 End face Inspection and Cleaning 24 s MOVECO 0020 ee ee ae 0 0000 24 CaN graze a 777
16. ce method and set it Figure 3 As described earlier setting a reference is a critical to obtaining accurate test results The _ E power meter and light source are connected 01500 0 Bite together and the povver level 1s measured by the 2al Reimane Kaht meter to establi the ret forl view Delete Results 1g me er to establish the reference for loss EEEIEE ETTE REE calculations Tone Generator Memory Status Steps for setting a reference Battery Status Self Test Step A Turn the rotary switch to Update Software 2 2 7 Version Information Special Functions and choose Set Reference Figure 4 a Renkami Talin Y press ENTER Step B Press Enter and connect the TRCs between main and remote as shown on Figure 4 the screen and press Test to make the reference measurement With the DTX Series in Smart Remote setup you can test the two fibers that make up the transmission link in one test Each fiber test module is equipped with a light source and light meter In the setup you ll use two duplex TRCs One fiber will connect the output light source at the main unit to the input light meter at the remote unit The second connects the output at the remote unit to the input at the main unit Special note The DTX TRCs use the following Set Reference convention to quickly make connections and verify the polarity of the link under test the Remote End Setup light enters the cord at the red bo
17. ding end face inspection and cleaning should be a part of technician s standard operating procedures Throughout the cable installation process and before certification you should measure the loss of cabling segments to ensure the quality of the installation workmanship This test is normally done with a Light Source and Power Meter LSPM test set Fiber verification test tools are typically less expensive tools they re also effective in troubleshooting links A quick inspection of the end to end link 1055 may indicate whether or not the optical fiber cable is suspect or whether other network functions are the cause of the malfunction An LSPM determines the total light loss along a fiber link by using a known light source at one end and a power meter at the other But before the test can be done measure and record a reference power level from the source to set a baseline for the power loss calcula tion After this reference is established plug the meter and source into the opposite sides of the fiber link to be tested The source emits a continuous wave at the selected wave length On the distant end the power meter measures the level of optical power it receives and compares it to the reference power level to calculate the total amount of light loss Figure 1 If this total loss is within the specified parameters for the link under test the test passes A loss budget should be well established and used as a benchmark during cabling ins
18. e fiber length and the overall loss of the fiber Use this screen to quickly locate con nectors and faults on the fiber To see details for an event tap the event in the map then tap the LOSS REFLECT TYPE 4191 OTDR Pot information window for the event Trace shows the OTDR trace Use this screen to Figure 12 ptifiber Pro TABLE example see the dead zones of reflective events and examine the characteristics of unexpected events such as ghosts and gainers The characteristics of the link will show in the EventMap Note Test result Pass Fail and events shown depend on the characteristics of the test link Tap Summary Bubble to look at the details EventMap View In figure 13 is an example of a PASSING test using launch and tail fiber e Different icons distinguish events such as Passing reflective event Failing reflective event Hidden reflective event Passing loss event Failing loss event Hidden event s loss is added to previous events loss e Details are provided for the events loss reflectance and segment attenuation 02 07 2012 4 42 15 Hirnull net eared j dm Elen ili not caver 4 Fiber Length 310 84 m Event Type Reflector nem Overall Lows 1 46 dE Location 103 10 m uzu nm 1300 nn ATTPARUATION OW eens OY Figure 13 OptiFiber Pro EventMap example by tapping on bubble to drill in for more information Trace View
19. e ring near the red boot indicates the location of the mandrel for multimode fiber Step C After the tester measures the reference power level it displays these values as shown in figure 7 If your reference values are acceptable press the F2 softkey to store these values and to proceed with link certification Acceptable Reference Values 62 5 um Multimode 50 um 9 um Multimode Singlemode SFM SFM2 nominal level Step D Now disconnect your TRCs at the Input ports only and create the connection shown on the screen Figure 8 Disconnect the black boots from the input ports and connect the unused ends with the black boots in the duplex cord set to the adapter on the input port of the unit to which the duplex mate has been con nected You have separated the main and remote units so you can connect a unit at each end of the optical fiber link to be tested Guidelines for setting a reference Use high quality TRCs Clean TRC ends before you set the reference Use preferred one jumper reference method View Reference Remote End Setup Smart Remote 850 1300 nm Input dBm 19 16 19 51 Output dBm 18 54 18 92 Test Method Method B Reference set 05 08 2009 4 46 03 p m Figure 7 View Connections Remote End Setup Smart Remote Figure 8 Let the tester warm up to a steady state internal temperature about 10 minutes with ambient temp and storage temp difference of lt 20 F
20. ed The result shown in figure 10 pertains to the fiber that is connected to the input port at the main tester unit The screen fiber connected to the input port on the title Loss R M which means Loss from the main tester unit The result includes the Remote unit to the Main unit also indicates the loss for both multimode wavelengths installation test standard fiber for result displayed Once you ve tested all the links and saved each record you can download results to a PC inspect and manage them with LinkWare Results Management software You can also print a Summary Test Report for the job as well as a professional report for each link tested LinkWare lets you create reports as PDF files Testing MPO cabling components To test optical links and channels constructed with multifiber MPO cabling components it is recommended to use a special tester for increased efficiency With Fluke Networks MultiFiber Pro Power Meter and Light Source you can follow similar procedures and test all 12 fibers at once The MultiFiber Pro brings simplicity to multi fiber cable testing in any environment It is a true MPO connector fiber tester able to simultaneously test all 12 fibers in an MPO trunk cable To test a multi fiber cable start with setting the reference e As usual clean the end face connectors with an MPO fiber cleaner then simply connect one of the test cords to the power meter and light
21. er cabling is the preferred medium for distances beyond 100 meters such as nser cables in a building This guide reviews best practices for test and troubleshooting methods as well as rec ommended test tools to ensure installed optical fiber cabling provides the transmission capability to reliably support LAN or enterprise network applications Certification or the process of testing the transmission performance of an installed cabling system to a specified standard ensures a quality installation It also provides official documentation and proof that the requirements set by various standards committees are fully satisfied Optical fiber is a reliable and cost effective transmission medium But because precise align ment of very small fibers is crucial problems ranging from end face contamination to excess modal dispersion can cause failures Regardless narrowing down the source s of failure is often a time consuming and resource intensive task That s why Fluke Networks created this enterprise focused fiber troubleshooting guide to help you better assess the quality of a cable installation And to help you troubleshoot more effectively so you can fix a problem faster rather than spending time trying to identify it Note this guide doesn t address issues especially germane to the long haul telecommunica tions application of the fiber optic technology 2 Fiber Verification Testing Fiber verification testing inclu
22. ggest cause of failing connections and testing chal lenges Clean fibers each time they are connected You can verify fibers are clean by using an instru ment such as a FiberInspector microscope to examine fiber end faces Figure 25 FiberInspector set up from Tools menu Dust blocks light transmission Finger oil reduces light transmission Dirt on fiber connectors spreads to other con nections Contaminated end faces make testing difficult Remember to inspect equipment ports like routers switches and NICs They get dirty too Use the right test setup Test standard per specifications will ensure you get the most ac curate consistent understandable and repeatable results Use recommended fiber mandrels to improve loss measurement accuracy and repeatability Figure 26 FiberInspector results view e Always use high quality TRCs and launch fibers Avoid random questionable quality test cords A L TRCs for loss testing should be delivered with good test result data Test cords should make polarity easy for you Fluke Networks cords feature red boots on the end where light enters and black boots on the end where light exits Keep cords clean and replace them when they show signs of wear Choose test limits appropriate to both generic cabling standards and application standards 6 End Face Inspection and Cleaning Inspection Proper inspection helps detect two of the most common
23. icroscopes e Optical Figure 27 tube shaped and compact they enable you to inspect the end faces directly Popular because they are inexpensive However they aren t able to view end faces inside equipment or through bulkheads e Video Figure 28 small optical probe is connected to a handheld display The probe size makes them excellent for examining ports in hard to reach places large displays enable easy identification of end face defects They are also safer as they show an image and not the actual end face being observed reducing the risk of exposing one s eye to harmful lasers Figure 27 Optical microscope When it comes to showing the user what the naked eye can t see the best microscope is the one that can detect the smallest object Cleaning Properly cleaned end faces can actually add up to 1 39 dB onto your loss allowance Figure 29 In other words if you have a fiber plant with an overall loss of 5 0 dB against a specified budget of 4 5 dB cleaning dirty end faces may drop the link loss down to just above 3 6 dB providing a Pass and plenty of head room Consequently it s important to choose your cleaning tools and methods wisely while avoiding common bad habits Perhaps the most Figure 28 Video microscope typical mistake is using canned air to blast fiber con nectors or ports While helpful for displacing large dust particles it is ineffective on oils residues or tiny st
24. idence that every component in a fiber optic cabling system was properly installed See Pass result at 1550nm in figure 18 and at 850nm in figure 19 OTDR Trace 1550 nm FIBER 26 End1 dE 4 IX 14 l 36 1 1 202 4 mn Event Reflection 0 23 dB 4 Cursor Event Press ENTER to Set Mark Figure 18 Trace screenshot on the DTX Compact OTDR OTDR Trace dB 145 J2 3 8 1 6 1 Event 0 0 m Launch Event 0 05 dB PASS 4 Cursor Event Press ENTER to Set Mark Figure 19 Pass trace screenshot on the DTX Compact OTDR As with the first tier of testing you can download test results to a PC and manage them with LinkWare Results Management Software It is easy to merge OTDR test results with the other records if the same naming sequence is used These can be easily created printed or emailed as PDF files Cable certification test strategy There are several ways to perform a complete certification test of fiber optic cabling The standards are clear about defining required and optional tests test limits and acceptable test equipment But they don t suggest how the testing should be performed for optimum efficiency in the field Based on decades of work with con tractors installers and technicians ee Fluke Networks developed proven Figure 20 Sample LinkWare Results Management Software report best practice procedures t
25. o perform a complete fiber certification in the most efficient way e Make sure design criteria and test limits are established before installation Confirm proper fiber strand polarity end face conditions and verify loss with simple verification tools during installation e Perform extended tests using the tier 2 certification tests OTDR analysis as the first certification step Doing so Ensures connector performanc meets generic cabling standards or system designer s requirements Qualifies workmanship for cabling installation Identifies problems for immediate troubleshooting with OTDR e Secondly perform basic tier 1 test for the channel against the application standard This certifies channel length and loss and calculates margin based on the standard If bidirectional testing isn t required measure channel loss at the wavelength of the application 5 Finding and Analyz ng Fiber Cabling Faults Common Faults Insufficient power or signal disturbances from common faults cause failures in optical trans mission Fiber optic connections involve the transmis sion of light from one fiber core into another Fiber cores are smaller than the diameter of a human hair To minimize loss of signal power this requires good mating of two fiber end Figure 21 Example of a common cause of a fiber failure faces e Contaminated fiber connections The leading cause of fiber failures is poor connec tor
26. ot and leaves 2 the TRC at the black boot So one end of a TRC has a red boot and at the other end of that same cord 1s a black boot The light travels from red connect patch to black The DTX screen display shows the boot cords as shown color Figure 5 Figure 6 shows this reference setup This figure Press TEST uses a different color for the two duplex cords These colors don t relate to the actual cords but were chosen to make the figure more clear The Figure 5 yellow cord connects the output light source of the main unit s fiber module to the input light meter of the remote unit One of the yellow cords isn t connected in the reference setting One of the darker colored cords makes the connection in the opposite direction Figure 6 also shows the location of the mandrel near the end with the red boot that is to be connected to the light source The duplex cords have one longer leg with the red boot After this leg has been wrapped around the mandrel the lengths of both cords in the duplex arrangement are equal The DTX fiber modules output ports are always SC connectors The removable adapters for the input ports are chosen to match the end connectors of the link under test The example in figure 6 shows the link under test equipped with LC connectors LC Main to Remote Main Unit LC Adapters Remote Unit Figure 6 Setting the reference with duplex TRCs for a link under test ending with LC connectors Th
27. ple sets of OTDR test limits and select one for a particular job Each OTDR test passes Figure 16 or fails Figure 17 based on a comparison against the selected set of test limits Length Overall Loss Largest Event 2 On the second setup screen you can set launch Figure 16 Pass screen on the fiber compensation designate which end you are DTX Compact testing L and note what you want to call each OTDR Results end of the fiber Multimode 50 Dual 850 1300 nm End 1 DATA CENTER Using launch fiber compensation LFC Launch fiber compensation is used to simplify testing and remove the launch and receive fibers losses and lengths from measurements See figure 15 Length e It shows where your launch and or receive Overall Loss fiber is on the trace and eliminates it from the M Largest Event certification test results If you are a contractor your customers want to know where an event is in their fiber plant not where it is on your test setup When you enable LFC a connector 50m from the patch panel will show up at 50m not 150m on the trace Just turn the rotary switch to Setup go to the second tab and enable Figure 17 Fail screen on the Launch Fiber Compensation Then turn it again DTX Compact OTDR to Special Functions and choose Set Launch Fiber Compensation Choose Launch only if you are just using a launch fiber or Other Options if you are al
28. so using a receive fiber 3 Third designate the fiber characteristics allow default to the selected fiber in the first step or choose User Defined and select Numerical Aperture and Back scatter coefficient for the fiber under test 4 4 Now choose from the menu to set Distance Range Averaging Time Finally choose from the menu to set Pulse Widths and Loss Threshold With the DTX Compact OTDR many settings such as Distance Range Averaging Time Pulse Widths and Loss Threshold can be automatically set Just turn the rotary switch to Autotest and when you push the Test button the OTDR will choose the most appropriate setting for the fiber you are testing Running an autotest Now that you re all set up for testing turn the dial to Autotest plug in your launch fiber and press Test If it passes press Save name the test and test the next fiber If you want to see a trace just press the f1 softkey The event table and limits are also accessible via softkeys on the main screen Summary of extended certification OTDR traces characterize the individual components of a fiber link connectors splices and other loss events Extended certification compares the data to specifications for these events to determine if they are acceptable e Critical because it identifies faults that may be invisible to basic certification e Ev
29. source Make sure the light source is in Scan All mode with Auto Wavelength on e Press the Menu button on the power meter to enter the Set Ref mode Once the measurement is ready press F1 to save the reference e After you ve set the reference with the supplied MPO test cords select a loss limit Press Menu for 3 seconds and then use the arrow keys to move to Loss Limit Press Menu again and use the F1 or F2 key to set your designated loss limit value Now press Menu once to save Then press and hold the Menu key to go back to the main screen e Now simply connect your test cords to the MPO trunk cable and in less than 6 seconds you ll have the loss and polarity measurements for all 12 fibers The simple user inter face allows you to easily determine if the cable passes the loss criteria you ve set Any fiber that has excessive loss will be easy to spot in the simple bar graph Documenting the Results To simplify test results management MultiFiber Pro test results can be easily uploaded to the popular LinkWare 7 cable test management software Connect the meter to your laptop with LinkWare 7 running In LinkWare use the Import function to extract all the tests results from the MultiFiber Pro power meter and professional test reports can be created For the most recent version of LinkWare software please visit www flukenetworks com linkware 4 How to Certify Optical Fiber Cabling wi
30. ss and reflectance e Radius of curvature The convex surface of the connector should nicely mate up with another connector e Apex offset The core of the fiber should be centered near the highest point of the connector e Fiber height A protruding underpolished fiber doesn t mate well and an undercut overpolished connector will perform poorly due to an air gap Unseated connectors A connector may be plugged into an adapter bulkhead but may not be seated and connected with its mate Worn or damaged latching mechanisms on connectors or adapters are sometimes the culprit Poor cable management Strain on a connector may cause misalignment due to becoming partially retracted broken or unplugged e Polarity Perhaps the simplest fiber cabling fault is a reversal of transmit and receive fibers This is usually easy to detect and repair But sometimes connectors are du plexed together and must be broken apart to be reversed Standards designate polarity with a labeling convention that is seldom used resulting in confusion Polarity should be designated with A and B labels or colored boots Ais for transmit and B is for receive OR red is for transmit and black is for receive Poor cable management system design or damaged cable also causes faults in fiber cabling systems Fiber has a high tensile strength but is susceptible to crushing and breaking if abused Bends Macro and microbending caused by tight cable
31. tallation If this verification testing is performed during installation you can expect that yield will increase and certification testing will go more smoothly Historically LSPM test sets require manual calculations and subjective interpretation by experienced technicians However newer instruments automatically compare power measurements to set references eliminating the time consuming loss calculations Using an LSPM set to verify end to end loss is convenient But it doesn t indicate where trouble areas are Failures can be difficult to locate and analyze Even when the loss is within a specified threshold the LSPM set doesn t provide any warning or indication of where a defect or problem may be In other words although an entire link may pass it s possible individual splices or connections within it may fail industry specifications This creates a potential problem in the future during adds moves or changes where multiple dirty connectors might be grouped together and result in a failure An Optical Time Domain Reflectometer OTDR can pinpoint locations connections displaying a high loss or reflectance Fiber under test Mandrel used only for 850 1300 nm testing Figure 1 Conducting an LSPM test 3 Hovv to Certify Optical Fiber Cabling with OLTS and LSPM Industry standards require using an LSPM or Optical Loss Test Set OLTS to certify the loss of each link meets performance standards This is referred
32. th an OTDR There are different types of OTDRs available TIA 568 0 and 150 14763 3 recommend OTDR testing as a complementary test to ensure the quality of fiber installations meets compo nent specifications The standards don t designate Pass Fail limits for this test You should consider generic cabling requirements for components and design criteria for the specific job You can use an OTDR as a single ended tester bidirectionally if desired and option ally with a receive fiber for certification testing What you need to know about OTDRs OTDRs used to be hard to operate laboratory equipment impractical for field use They were big heavy and complicated for inexpe rienced technicians to set up and operate Test results were difficult to understand This created fear and confusion Today however many new OTDRs are small light and easy to use An ordinary technician can troubleshoot like an expert but a basic understanding of how an OTDR works is still helpful e Basic operation An OTDR infers loss reflectance and location of events It sends pulses of light into a fiber and uses a sensitive photo detector to see the reflections and plot them graphically over time In order to accurately test the optical characteris tics of the fiber must be determined and set prior to testing OTDR trace The OTDR plots the reflectance and loss over time in a graphical trace of the fiber Experienced technicians can read a trace
33. the source of the ghost is so you can eliminate it Gainers Another misunderstood phenomenon on an OTDR trace is a gainer Simply put a gainer is an apparent negative loss at an event where there is a change in the optical performance This is usually due to a mismatch between the index of refraction of two spliced fibers or connection of a 50 um multimode fiber into a 62 5 um fiber This type of event will often exhibit excessive loss in the other direction OTDR built specifically for the enterprise The OptiFiber Pro OTDR is an Optical Time Domain Reflectometer that locates identifies and measures reflective and loss events in multimode and singlemode fibers Typical maximum test ranges are less than 35 km at 850nm and or 1300 nm wavelengths for multimode fiber and well below the instrument s range of 130 km for singlemode fiber which should be typi cally tested at 1310 and or 1550 nm for singlemode fiber FLLULIKE networks The tester can show the OTDR results in three formats Figure 12 Table shows a table of the events on the fiber Use this screen to quickly see measurements for all events and see the types of events on the fiber The table includes the distance to the event the loss of the event the size of the WA 1521 End i reflection from the event and the type of the 47 34 Reedin gf event To see details for an event tap the event in the table e EventMap shows a diagram of the events on the fiber th
34. to as basic or Tier 1 Certifica tion and considered the most important testing in regards to new cabling installations Tier 1 Certification is a double ended test which produces an absolute loss measurement That measurement is then compared with installation cabling standards and or chan nel application standards Fluke Networks DTX CableAnalyzer can support multimode or singlemode fiber test modules that automate most of the test and make basic or Tier 1 certification easy An OTDR can also provide loss results for the total link But this measurement is based on the reflected light energy The standards demand the basic certification be executed with an OLTS or LSPM The link loss results provided by using a light source on one end and a light meter at the opposite end are more accurate Follow these steps to perform a basic loss length certification test e Establish Pass Fail test limits e Choose a test method and set a reference e Run the test and save results e Export to LinkWare to manage and archive the test results LinkWare is Fluke Networks free cable test management software to create printed or electronic reports 1 Establish Pass Fail limits in accordance with your certification goals In this example we will establish limits for the total allowable loss based on an application standard using the Fluke Networks DTX Series tester equipped with the DTX MFM2 fiber loss test modules for multimode If you
35. trained Fluke Networks Technical Assistance Center TAC e Certified Test Technician Training CCTT classes available around the world Gold Support program comprehensive maintenance and support including priority repair with loaner annual calibration and priority TAC support with after hours and weekend coverage 8 Glossary Certification testing the process of testing the transmission performance of an installed cabling system to a specified standard requires an OLTS for Tier 1 certification and an OTDR for Tier 2 certification Channel end to end transmission medium between a transmitter and receiver dB function of a ratio of two power levels typically used to express the relation of the output power to the input power such as the gain in an amplifier or the loss in a transmission line dBm power level expressed as the logarithm of the ratio relative to one milliwatt FiberInspector Fluke Networks popular line of handheld fiber end face and bulkhead port inspection instruments ranging from tube to video microscopes Gbps gigabits per second Launch cord fiber length of fiber placed between the link under test and the OTDR to improve the OTDR s ability to grade the near end connector and any abnormalities in the first connection LED Light Emitting Diode a relatively low intensity light source Link the physical cabling for a transmission Mbps megabits per second OLTS Optical Loss
36. under test Make sure the connector on your fiber test adapter matches the fiber patch cord or the patch panel Connect TRCs to the link or channel to be tested repeat the process displayed in figure 8 Special mode controllers are available to use in place of traditional test reference cords for test specifications that require encircled flux launch conditions see Figure 9 Figure 9 Encircled Flux Mode Controller Bidirectional testing If you want to test each fiber in both directions don t forget to select that option in the setup screen see Figure 3 When the tester prompts you to make the connection to test in the second direction remember to switch the TRC at the link end DO NOT remove the TRCs from the tester connections Test Results Be sure to save results before testing Loss M gt R in the other direction or moving on to the next fiber Figure 10 shows the detailed measurements Fiber of a fiber Note that each fiber is tested at both 1300 nm wavelengths demanded by the installation standard AN n0 an Applications standards on the other hand only B50 NM oss specify performance for the wavelength of the Ne 1 Limit applications For example the 106BASE S standard salik Margin specifies the link requirements at 850 nm The name input fiber or ouput fiber in the test result Press SAVE when done screen refers to the port in the main unit to which the fiber is connect
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