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This calculator can be used with any glass type, to
measure any wavelength loss. FYI ..typical borosilicate
glass has an averaged Loss Per Inch attenuation of .002%
for visible light. We also recommend using a Oractical
Initial Efficiency percentage of 60%.
TRANSMISSION LOSS
There are no industry standards for measuring light transmission
of a completed fiber optic part.
The amount of transmitted light is influenced by many factors. Typical
variables are the types of glass used, the purity of each glass, the
quality of the fused interface between the core and the clad, the
quality of the end finishing and assembly of the part.
Consequently, the customer and the vendor should work together to
define the requirements and the process used to inspect the parts.
Fiberoptics Technology has been working this way for over 25 years;
continuously developing new methods of qualification based on the
application. Upon request, we will furnish a transmission curve for
each part shipped to validate efficiency.
Be aware of exaggerated claims for light transmission and use the
following facts to make an informed decision:
SINGLE FIBER LOSSES
If you could focus all transmitted light directly on the core of
the fiber, a single, perfectly polished fiber starts with a theoretical
transmission efficiency of about 92%. Fresnel losses account
for 4% at each end.
WHAT ARE FRESNEL LOSSES?
Light striking the input surface of the fiber will be reflected,
rather than continuing through the fiber, even though the incidence
angle is within the acceptance angle of the fiber. This phenomena
is caused by a difference in refractive indices (light traveling
in air with one refractive index, meets the core glass surface, with
a different refractive index).
In addition, because light is typically focused on the surface area
of the entire fiber, we should also account for cladding losses.
What are Cladding Losses?
Two separate glass types and qualities
are used to manufacture fiber. Core glass is designed to transmit
light, while the cladding glass,
made to have a different refractive index, is designed to keep the
light ray from leaving the fiber once it enters. Cladding glass is
not designed to transmit light, so it has a very high attenuation
rate. Cladding glass makes up about 15-17% of the total cross sectional
area of a fiber.
Very few industrial fiber optic applications use a single fiber.
Most customers require a component made from a "Bundle"
of fibers in a specific configuration. This bundle also
has characteristics which contribute to losses.
What are bundle losses?
As glass fibers are actually cylinders, when they are grouped together
to form a bundle, a space is created between cylinders. Known as
interstitial spacing, this wasted area accounts for 9-11% of the
total bundle area.
Therefore, a perfectly constructed fiber bundle (no skew, perfectly
packed and polished) starts with a transmission efficiency
of about 64-68%% (8% fresnel loss, 15-17% cladding loss,
9-11% interstitial spacing loss. When you add in manufacturing
process, the maximum practical transmission efficiency
is about 60%. To use this calculator, you have the freedom
to type in a new efficiency value if you desire.
The best way to determine efficiency is to test the actual part.
If you need accurate information, let us know the size and length
of the bundle you are considering. We'll evaluate performance and
supply a curve.
There are no industry standards for measuring light
transmission of a completed fiber optic part. Consequently,
the customer and the vendor should work together to
define the requirements and the process used to inspect
the parts.
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