Loss & Continuity Testing with MPO/
MTP Connectors
Deployments of fiber optic systems
typically MPO/MTP connectors, which have
Here we give an overview of how to tackle various issues related to testing the cabling for these systems. We mainly discuss multimode systems, however single mode
very many common practices. Typically these deployments are even if the immediate requirement
24 fibers used for 100G Ethernet can alternatively be
a choice of upgrade paths, eg to upgrade incrementally to 120G aggregate capacity by adding two extra 40G channels, or replace a 40G system
development for 400G Ethernet.
The incremental cost of installing 24 fiber 100G cabling, instead of 12 fiber 40G cabling, is actually quite modest, particularly in compar
additional cabling complexity may be a patch panel connection flexibility for future deployment options. Standards Compliance
Internationally recognised standards are now in place, which define just about everything data centre design.
Just in the area of fiber optic cabling, there are standards for fiber types (Typically multimode OM3. OM4 etc), cable types (fire retardance, bend resistance
stops, ducting etc) connectors (LC, MPO etc), labell (CWDM etc), optical safety (mandatory), and finally:
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Loss & Continuity Testing with MPO/
MTP Connectors
of fiber optic systems in data centres are now using multimode ribbon fiber an , which have some very particular installation issues.
Here we give an overview of how to tackle various issues related to testing the cabling for these systems. We mainly discuss multimode systems, however single mode ribbon fiber
are for 40G / 100G Ethernet. Cabling may be installed for 100G immediate requirement is 40G, to allow for later incremental bandwidth
24 fibers used for 100G Ethernet can alternatively be used to carry three 40G systems.
to upgrade incrementally to 120G aggregate capacity by adding two a 40G system with a single 100G channel. Standards are
hernet.
The incremental cost of installing 24 fiber 100G cabling, instead of 12 fiber 40G cabling, is actually comparison to later re-wiring and facility disruption
complexity may be a patch panel with breakout connections, which provides flexibility for future deployment options.
Internationally recognised standards are now in place, which define just about everything
Just in the area of fiber optic cabling, there are standards for fiber types (Typically multimode OM3. OM4 etc), cable types (fire retardance, bend resistance, riser cables etc), cable installation (fire stops, ducting etc) connectors (LC, MPO etc), labelling conventions, Ethernet, optical wavelengths (CWDM etc), optical safety (mandatory), and finally: cable acceptance testing.
Loss & Continuity Testing with MPO/
ribbon fiber and issues.
Here we give an overview of how to tackle various issues related to testing the cabling for these ribbon fiber systems share
abling may be installed for 100G Ethernet incremental bandwidth upgrades. The
hree 40G systems. So this allows to upgrade incrementally to 120G aggregate capacity by adding two
with a single 100G channel. Standards are in
The incremental cost of installing 24 fiber 100G cabling, instead of 12 fiber 40G cabling, is actually disruption. The major with breakout connections, which provides
Internationally recognised standards are now in place, which define just about everything to do with
Just in the area of fiber optic cabling, there are standards for fiber types (Typically multimode OM3. etc), cable installation (fire ing conventions, Ethernet, optical wavelengths
There is one aspect of the standards for
are currently a work in progress, and this is particu So at the project definition stage, it is a good idea to
test requirements, which sensibly end up as a combination of standards based mandatory requirements of the particular transmission equipment
point can reduce project cost, increase facility utilisation A Very Small Acceptable Optical Loss
The majority of LAN transmission systems using end optical loss requirements, perhaps around 1. for precision loss measuring for cable certification and procedures do not achieve a level of
specification has been achieved.
The two reasons for this tight specification
because these systems are dispersion limited, not power limited. These systems use 850 nm and 50 micron core fiber, and end to end
Inspection & Cleaning
Connector condition and cleanliness is a very major consideration problems. Absolutely essential is
supply of suitable specific cleaning material know-how to use them. The default available the fiber ends only, but extra cleaning sometimes the whole connector
Inspection and cleaning should be performed every time before a connector is mated. Cabling Disturbance
Because of the combination of very low loss requirements, connector performance, it is essential
the lowest possible level of disturbance to connections. Also, once loss testing is disturbance might require the loss testing to be repeated. This means that an unusual regime is appropriate, so that each
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the standards for fiber acceptance testing that everyone can agree on: they ess, and this is particularly true of MPO testing.
So at the project definition stage, it is a good idea to review and refine the fiber cable test requirements, which sensibly end up as a combination of standards based requirements
atory requirements of the particular transmission equipment in use. A good increase facility utilisation, and increase the useful Acceptable Optical Loss!
sion systems using MPO/MTP connectors have extremely
, perhaps around 1.5 dB. This tiny loss figure creates unique challenges for cable certification. Much of the currently available test equipment
a level of repeatability (accuracy) that gives confidence that the specification has been achieved.
tight specification are to minimise per port electronics cost, and
because these systems are dispersion limited, not power limited. These systems use 850 nm and 50 end to end length is usually limited (by dispersion) to around 300 meters.
cleanliness is a very major consideration, and is a most common cause of is a good quality microscope with an MPO/MPT specific
cleaning materials (more than one type is good), and adequate time The default available MPO cleaners tend to do a reasonable job of cleaning
cleaning materials should be available to clean alignment pins, and connector end face.
should be performed every time before a connector is mated.
Because of the combination of very low loss requirements, high fiber complexity
essential that final testing and commissioning are accomplished with the lowest possible level of disturbance to connections. Also, once loss testing is
loss testing to be repeated. This means that an unusual
regime is appropriate, so that each acceptance level is completed with exceptional confidence. You that everyone can agree on: they
fiber cable acceptance requirements and the A good review at this
useful LAN lifetime.
have extremely tight end-to-dB. This tiny loss figure creates unique challenges . Much of the currently available test equipment
confidence that the tight
cost, and also because these systems are dispersion limited, not power limited. These systems use 850 nm and 50
to around 300 meters.
most common cause of MPO/MPT specific adaptor, a
, and adequate time and cleaners tend to do a reasonable job of cleaning
to clean alignment pins, and
should be performed every time before a connector is mated.
fiber complexity and modest testing and commissioning are accomplished with the lowest possible level of disturbance to connections. Also, once loss testing is done, any cabling
loss testing to be repeated. This means that an unusually strict test is completed with exceptional confidence. You
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want to avoid going back in and disturbing things. For this reason, we suggest a phased approach as being most practical.
Continuity Testing
This is the most basic test: Does light get from end to end? As a minimum, this test is easily accomplished with a VFL source and one low quality breakout cable to connect to the VFL. Continuity testing usually doesn’t need documenting. If a numbered low quality breakout cord is used each end, this could also double as a polarity test phase.
The continuity test phase is usefully accompanied by thorough cleaning and inspection of the connectors. This achieves a few objectives. Bad connectors are the main cause of installation failures. Doing this here enables the installer to identify & re-work/replace bad connectors at the earliest (lowest cost) point, avoiding later cable disturbance. It also ensures that a bad connector does not contaminate the test cords or degrade other connectors.
If the connector quality is inadequate, there may be little point proceeding further until this issue is fixed.
Simple continuity testing has one big problem: it doesn’t identify if fibers are swapped around. So for this we talk of:
Polarity Testing
Typically, the cable installation requires polarity testing, to ensure that a 1 – n array of fibers at one end of a system, is correctly mapped to a 1 – n array of fiber the other end. If the installation has a patch cable section so that connections can be split off to particular transmission equipment, niggling polarity mistakes can occur here. The polarity test needs a very high level of confidence, since if not 100% correct, there is no chance of a working outcome, and there could be a great deal of wasted work to find the swapped fibers. This will probably want a basic level of documenting, sufficient to record which fibers were tested, and the general array direction.
Labelling
You now have your system physically in place and light going to and fro in the right combinations. This is the perfect time to double-check and rectify all associated labelling, otherwise the next phase of loss testing could result in incorrect re-assembly due to discovered faults.
Up to this point, the work has required a very methodical approach, however has otherwise been quite straightforward.
Loss Testing Accuracy & Confidence Issues
People use the terms repeatability, accuracy, reproducibility or uncertainty somewhat
interchangeably. For loss testing in particular, there is little practical difference between them all, so we will use the term “uncertainty”. The real issue is what uncertainty happens when repeatedly measuring one item with different items of test equipment or test cords.
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Quoted uncertainty values always imply a ± value, whether specifically mentioned or not. For example, a quoted uncertainty of 0.1dB is the same as ±0.1dB, usually with a 95% confidence level. As mentioned, the acceptable maximum loss figure may only be 1.5 dB. If the test uncertainty is say 0.3 dB, then measured losses from 1.2 – 1.8 dB are marginal, and the maximum test value for guaranteed operation is 1.2 dB. So every small improvement in uncertainty, yields a usefully larger allowable measured loss level, which will reduce installation cost. This easily explains the previous care on planning test cords, doing cleaning etc. In practice, repeatability / accuracy is optimised by a number of factors:
1. Use of low loss “Elite” test cords, and ensuring they are in top condition. 2. Use of an Encircled Flux compliant test source, followed by a mandrel wrap.
3. Use of very accurate loss test equipment, remembering that you are working on the limits of achievable loss test accuracy. For typical 850 nm testing, do not use an InGaAs power meter detector, since it is too wavelength sensitive and so reduces practical accuracy. The light source must also be highly repeatable and stable when the connected test cord is moved around.
4. Rigorous inspection and cleaning every time a connector is mated. 5. Performing test cord verification at the start of the job.
6. Use of appropriate data recording systems, since there will be plenty of test data. Test Cords
A major loss test consideration is the test cord loss performance. As can be seen from the table, “Elite” MPO / MTP cords are available with per connector / fiber loss of below 0.35 dB. Otherwise “standard” cords are clearly inadequate for testing. Here are the USConnec specifications for these connectors, and also shows why it is so undesirable to disturb the cabling after testing.
MM MT Elite® Multimode MT Ferrule Standard Multimode MT Ferrule SM MT Elite® Single-mode MT Ferrule Standard Single-mode MT Ferrule Insertion Loss 0.1 dB Typical (All
Fibers) 0.35 dB Maximum (Single Fiber) 0.20 dB Typical (All Fibers) 0.60 dB Maximum (Single Fiber) 0.10 dB Typical (All Fibers) 0.35 dB Maximum (Single Fiber) 0.25 dB Typical (All Fibers) 0.75 dB Maximum (Single Fiber) Optical Return Loss > 20 dB > 20 dB > 60 dB (8° Angle Polish) > 60 dB (8° Angle Polish)
Testing will probably need a combination of straight MPO-MPO test cords, and breakout cords. Also ensure that connector pin polarities are correct, since trying to swap these pins in the field is not viable. A few tested through-connects is also helpful.
Spare test cords will be required, in case some get degraded or damaged.
The typical application environment uses a mix of LC and multi fiber connectors. So naturally one might assume that LC – MPO breakout test cords are an obvious choice. However SC – MPO
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breakout cords are typically more robust, easier to handle, and offer slightly improved optical performance. However, SC-LC connections give inferior performance.
Number the cords and label each end A/B.
Test cords require Performance Verification before each use. This performance verification test is quite specific, and failure to do this preliminary test may invalidate all the following test results. The basic objective of the performance test is to ensure that the loss of the cords meets the basic accuracy requirements. However, there is a sting in this tail as follows:
• The test standards require a loss of eg 0.1 dB or better for multimode fiber • The “elite” average loss meets this specification
• However the actual “per fiber maximum” loss does not.
We hope the standards folk will resolve this in due course. One potential way around this is that if the actual loss of each connection is recorded for each fiber during this test, then this loss can be used to compensate the following test results and improve accuracy. However in practice, this is excessively hard to implement, so the practical policy is to only use “good” cords.
The Test Cord Verification Test is quite simple: test each test cord connector using two reference cords, and the loss of the connection must be within the allowed limit. In the case of MPO connectors, this will take a bit longer due to the number of fibers.
What Test Uncertainty can I expect?
This is a much discussed issue. Without going into any great detail, there are a few obvious pointers: The test cord performance test using “Elite” connectors could have losses of from 0 – 0.35 dB per connector, giving a per mated connector uncertainty of ±0.18 dB, This means that any overall test uncertainty must be at least ±0.18 dB, and is likely to be larger once other factors as included. However once the test cords are plugged into presumably lower grade cords, the loss there could possibly jump to 0 – 0.75 dB, giving a minimum per mated connector uncertainty of ±0.38 dB. These are simple deductions based on connector specifications, and calculated uncertainty including all factors could only get worse.
Alternatively, if suitable experiments are performed with the actual equipment and test cords, it may be possible to demonstrate a lower level of uncertainty, however this is specific to a particular item of test equipment, and particular test cords, and so has limited viability.
General Loss Test equipment Choices
There are three broad choices to make, which will depend on the scale of expected work:
1. Use a basic source and meter. This is excessively fiddly to perform, and so prone to error, since both instruments need moving for each fiber to be tested, so it’s only sensible for a very small project.
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2. Use a basic source and special MPO compatible meter, so that only the source needs moving for each fiber. For a modest equipment cost, this greatly simplifies testing. This also works for any fiber type, wavelength, or number of fibers per connector, or MPO pin configuration, so it has excellent flexibility, and the same equipment can be used for other work. A good choice for many mid-size projects, or cabling contractors.
3. A special MPO test set, However these usually only work at 850 nm and 12 fibers, so they are both expensive and inflexible, and so are useful for a specific large project. They are not so useful for testing breakout cables. Many such units on the market today also have InGaAs detectors, which significantly degrade their test accuracy at 850 nm. They have limited MPO pin configuration compatibility, which may limit referencing options.
Whatever test equipment is selected will need some good reporting software. It may be a project requirement that it’s impossible to modify the test results, to prevent tampering.
Procedure
Loss testing using solution 2 will generally proceed as follows (remembering to inspect and clean on each insertion):
1. Begin by verifying the test cords. Once these are proven to be adequate:
2. Reference the source and meter using a breakout cable and the desired number of reference cords.
3. Set up the MPO power meter at the far end of the test system
4. Start with the light source at “fiber 1” on the breakout cable , take the loss reading
5. Move the light source only to the next fiber on the breakout cord, and take the loss reading 6. Etc
7. Go back to fiber 1 and note the reading (is within limits compared to the 1st time) We found that using a Kingfisher light source KI2803 with power meter KI2600XL-Ge5, and this technique, the repeatability was determined by the test cords. Ease of testing and speed were both good, since only the source needed moving for each fiber.
Loss testing using solution 1 will differ in that the power meter will need to be moved for each fiber. This coordinated shuffle greatly slows down the test process, and is error prone.
