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INSERTION LOSS TESTING |
Insertion
loss refers to the loss of light, not so much in the cable assembly,
but that loss caused due to the assembly's introduction. There may
be very little light lost through the assembly itself, but the majority
of losses related to optical cable assemblies relate to how well
the fibres align with mating connectors when the assembly is introduced.
Insertion losses are measured in dB as per the formula |
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Insertion Loss = -10Log (P1/P0)
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where P0 is the initial measured power and P1 is the measured power
after the assembly under test is introduced. The following table
shows typical dB losses represented as percentage loss.
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Loss
(dB)
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Loss
(%)
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0.1
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2.3
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0.3
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6.5
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0.5
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11
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Fibrepulse
performs and records insertion loss tests on 100% of all terminated
connections as per IEC-61300-3-4 (method B). Procedure IEC-61300-3-4
(method C) is also used in some circumstances. |
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Insertion
Loss Test IEC-61300-3-4 Method B
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Insertion
Loss Test IEC-61300-3-4 Method C
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Insertion loss limits can depend on the customer's application.
Generally, an insertion loss of 0.50dB per connection is acceptable.
Fibrepulse has imposed a stricter 0.30dB max on all connector terminations.
Doing this involves a high level of control of material selection
and processes. The Diamond connector range which Fibrepulse terminate
has a maximum insertion loss of 0.10dB. This is achieved by active
core alignment.
Contributing factors of insertion loss are: |
1. Misalignment. |
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In
order for all the light to be successfully transmitted from one
fibre to another the two cores need to be perfectly aligned. With
singlemode fibres, because the core sizes are so small, a small
misalignment can have a significant effect on loss.
All the following tolerances effect alignment:
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·
Fibre diameter
· Core eccentricity
· Connector hole diameter
· Connector hole eccentricity
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| Fibrepulse
combats these factors by selecting the highest quality components,
and pre-selecting connectors for termination by tightest fit on
the fibre. The offset caused by these factors can also be improved
by optimising or tuning
after termination. This is a method of keying the connectors so
as to prevent eccentricities becoming accumulative. The Diamond
"Core-aligned"
assemblies, which Fibrepulse manufactures solves the problem by
aligning the core into the centre of the ferrule during the assembly
process. This has the effect of eliminating the effects of all the
above tolerances, and insertion losses achieved are 0.1dB max. |
2. Bending. |
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Bending
a fibre is a sure-fire way of increasing attenuation. Fibre cables
all have a minimum bend radius recommended. However, fibre connectors
are spring loaded allowing the ferrule to push back inside the
connector. This, particularly with soft buffer coatings, can cause
bending. This is bending added on to the bending already there
from threading the connector on in the first place. Fibrepulse
has a patented process for reducing this bending and thus reducing
stress on the fibre during mating. Bending inside the connector
can be a big problem if cables are used at longer wavelengths
or for DWDM. Bending can also occur throughout the cable (micro-bending).
This can be also prevented by controlling production processes.
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3. Stress. |
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If
the fibre is subjected to excess stress, fractures may result
causing light to leak into the cladding. Reducing stress applied
to the fibre is a matter of proper production procedures. Potential
sources of stress can come from the following processes:
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·
Reeling / De-reeling
· Coating removal (stripping)
· Connector insertion
· Oven cure temperature
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| These
are all areas that Fibrepulse has imposed strict process controls. |
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Castlebar
Technology Park,
Moneen, Castlebar, Co. Mayo, Ireland
Tel: +353 94 9027822 Fax: +353 94 9027811
E-Mail: info@fibrepulse.com
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