Fiber Optics PDF

Summary

This presentation details fiber optics, their use in aircraft digital computer systems, and the advantages over copper cabling. It also covers propagation, and attenuation.

Full Transcript

Aircraft Digital
Computer Systems
 FIBRE OPTICS
Fiber optics (optical fibers) are long, thin
strands of very pure glass about the
diameter of a human hair. They are
arranged in bundles called optical cables
and used to transmit light signals over long
distances.
FIBRE OPTICS
 FIBRE OPTICS
Optical fibres have been widely used as a
transmission medium for ground-based
long-haul data communications and in local
area networks (LANs) for many years; they
are now being introduced into the latest
passenger aircraft to satisfy the need for
wideband networked avionic and cabin
entertainment systems.
 FIBRE OPTICS
By virtue of their light weight, compact size
and exceptionally wide bandwidth, optical
fibres are ideally suited for use as a
replacement for conventional copper
network cabling. The technology is,
however, relatively new in the civil aircraft
industry and brings with it a whole new set
of problems and challenges for those
involved with aircraft operation and
maintenance.
 FIBRE OPTICS
Bandwidth describes the maximum data
transfer rate of a network or Internet
connection. It measures how much data can
be sent over a specific connection in a given
amount of time. For example, a gigabit
Ethernet connection has a bandwidth of
1,000 Mbps (125 megabytes per second).
FIBRE OPTICS
FIBRE OPTICS
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ADVANTAGES AND DISADVANTAGES
Optical fibres offer some very significant
advantages over conventional copper
cables. These include:
optical fibres are lightweight and of small
physical
size;
exceptionally wide bandwidth and very
high data
rates can be supported;
relative freedom from electromagnetic
interference;
 FIBRE OPTICS
ADVANTAGES AND DISADVANTAGES
Optical fibres offer some very significant
advantages over conventional copper
cables. These include:
relatively low values of attenuation within
the
medium;
high reliability coupled with long
operational
life;
electrical isolation and freedom from
earth/
 FIBRE OPTICS
ADVANTAGES AND DISADVANTAGES
The reduction in weight that results from
the use of fibre optical cabling can yield
significant fuel savings. Copper cabling is
typically five times heavier than polymer
optical fibre cabling and 15 times heavier
than silica optical fibre. On a large, latest-
generation aircraft with sophisticated
avionics, the total saving in weight can be
as much as 1,300 kg.
 FIBRE OPTICS
ADVANTAGES AND DISADVANTAGES
There are very few disadvantages of optical
fibres.
They include:
industry resistance to the introduction of
new technology;
need for a high degree of precision when
fitting cables and connectors;
concerns about the mechanical strength of
fibres and the need to ensure that cable
bends have a sufficiently large radius to
minimise losses and the possibility of
 FIBRE OPTICS
PROPAGATION IN OPTICAL FIBRES
Essentially, an optical fibre consists of a
cylindrical silica glass core surrounded by
further glass cladding. The fibre acts as a
channel (or waveguide) along which an
electromagnetic wave can pass with very
little loss.
 FIBRE OPTICS
PROPAGATION IN OPTICAL FIBRES
Fibre-optics are governed by the
fundamental laws of reflection and
refraction. For example, when a light wave
passes from a medium of higher refractive
index to one of lower refractive index, the
wave is bent towards the normal.
Conversely, when travelling from a medium
of lower refractive index to one of higher
refractive index, the wave will be bent away
from the normal.
FIBRE OPTICS
 FIBRE OPTICS
PROPAGATION IN OPTICAL FIBRES
Reflection involves a change in direction of
waves when they bounce off a
barrier. Refraction of waves involves a
change in the direction of waves as they
pass from one medium to
another. Refraction, or the bending of the
path of the waves, is accompanied by a
change in speed and wavelength of the
waves.
 FIBRE OPTICS
PROPAGATION IN OPTICAL FIBRES
The light in a fibre-optic travels through the
core by constantly bouncing from the
cladding, a principle called total internal
reflection. Because the cladding does not
absorb any light from the core, the light
wave can travel great distances.
 FIBRE OPTICS
PROPAGATION IN OPTICAL FIBRES
 FIBRE OPTICS
PROPAGATION IN OPTICAL FIBRES

Total internal reflection, courtesy
of www.wikipedia.com
 FIBRE OPTICS
PROPAGATION IN OPTICAL FIBRES
Optical fibres are manufactured by drawing
silica glass from the molten state and they
are thus of cylindrical construction. The
more dense medium (the core) is
surrounded by the less dense medium (the
cladding). Provided the angle of incidence of
the input wave is larger than the critical
angle, the light wave will propagate inside
the core by means of a series of total
internal reflections.
 FIBRE OPTICS
PROPAGATION IN OPTICAL FIBRES

Silica Glass
 FIBRE OPTICS
PROPAGATION IN OPTICAL FIBRES
Any light wave which travels along the core
and meets the cladding at the critical angle
of incidence will be totally internally
reflected. Therefore light wave is
propagated along the fiber core by a series
of total internal reflections.
 FIBRE OPTICS
Attenuation
The loss within an optical fibre arises from a
number of causes, including: absorption,
scattering in the core (due to non-
homogeneity of the refractive index),
scattering at the core/cladding boundary,
and losses due to radiation at bends in the
fibre.
FIBRE OPTICS
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Attenuation
Whereas the attenuation coefficient of an
optical fibre is largely dependent upon the
quality and consistency of the glass used for
the core and cladding, the attenuation of all
optical fibres varies widely with wavelength.
 FIBRE OPTICS
Attenuation
Monomode fibres are now a common
feature of ground-based high-speed data
communication systems and manufacturing
techniques have been developed that
ensure consistent and reliable products with
low attenuation and wide operational
bandwidths.
 FIBRE OPTICS
Attenuation
However, since monomode fibres are
significantly smaller in diameter than their
multimode predecessors, a consistent and
reliable means of cutting, surface
preparation, alignment and interconnection
is essential, and for this reason slower
multimode fibres are still prevalent in
current aircraft designs.
 FIBRE OPTICS

Comparison of multimode and monomode
fibres
FIBRE OPTICS
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DISPERSION AND BANDWIDTH

A simple one-way fibre-optic data link
 FIBRE OPTICS
PRACTICAL OPTICAL NETWORKS
The Boeing 777 was the first commercial
aircraft to enter production with an optical
fibre-based LAN for onboard data
communications. The system was originally
developed in the 1980s and it comprised an
avionics local area network (AVLAN) fitted in
the flight deck and electrical equipment
bay, together with a cabin local area
network (CABLAN) fitted in the roof of the
passenger cabin.
 FIBRE OPTICS
PRACTICAL OPTICAL NETWORKS
These two fibre-optic networks conform to
the ARINC 636 standard, which was adapted
for avionics from the fibre distributed
interface (FDDI) in order to provide a
network capable of supporting data rates of
up to 100 Mbps.
 FIBRE OPTICS
Fibre-optic cable construction
The construction of a typical fibre-optic
cable:
five optical fibres and two filler strands;
separator tape;
aramid yarn strength member;
an outer jacket.
 FIBRE OPTICS
Fibre-optic cable construction

A typical fibre-optic cable
 FIBRE OPTICS
Fibre-optic cable construction
 FIBRE OPTICS
The cable has an overall diameter of about
0.2 inches and the individual optical fibre
strands have a diameter of 140 μm
(approximately 0.0055 inches). A protective
buffer covers each fibre and protects it
during manufacture, and increases
mechanical strength and diameter in order
to make handling and assembly easier. The
buffers are coded in order to identify the
fibres using colours (blue, red, green, yellow
and white).
 FIBRE OPTICS
The filler strands are made from polyester
and are approximately 0.035 inches in
diameter. A polyester separator tape covers
the group of five fibres and two filler
strands. This tape is manufactured from low
friction polyester and it serves to make the
cable more flexible.
 FIBRE OPTICS
A layer of woven aramid (or Kevlar) yarn
provides added mechanical strength and
protection for the cable assembly. The outer
thermoplastic jacket (usually purple in
colour) is fitted to prevent moisture ingress
and also to provide insulation.
 FIBRE OPTICS
Fibre-optic connectors
The essential requirements for connectors
used with optical fibres are that they should
be:
reliable
robust
precise and repeatable (even after
numerous mating
operations)
suitable for installation without specialist
tooling
low loss
FIBRE OPTICS

A typical fibre-optic connector
arrangement
 FIBRE OPTICS
Fibre-optic connectors
While the loss exhibited by a connector may
be quoted in absolute terms, it is often
specified in terms of an equivalent length of
optical fibre. If, for example, six connectors
are used on a cable run and each connector
has a loss of 0.5 dB, the total connector loss
will be 3 dB. This is equivalent to several
kilometres of low-loss fibre!
 FIBRE OPTICS
Fibre-optic connectors
A typical fibre-optic cable connector
arrangement is comprised of:
alignment keys and grooves
guide pins and cavities
coloured alignment bands
three start threads.
 FIBRE OPTICS
Fibre-optic connectors
Each connector has alignment keys on the
plug and matching alignment grooves on
the receptacle. These are used to accurately
align the connector optical components; the
guide pins in the plug fit into cavities in the
receptacle when the plug and receptacle
connect. In order to ensure that the
connector is not over-tightened (which may
cause damage to the fibres) the pins of the
plug are designed to provide a buffer stop
against the bottom of the cavities in the
 FIBRE OPTICS
Fibre-optic connectors
The plug and receptacle have ceramic
contacts that are designed to make physical
contact when properly connected (the light
signal passes through the holes in the end
of the ceramic contacts when they are in
direct physical contact with each other).
 FIBRE OPTICS
Fibre-optic connectors
The coupling nut on the plug barrel has a
yellow band, while the receptacle barrel has
a red and a yellow band. A correct
connection is made when the red band on
the receptacle is at least 50 per cent
covered by the coupling nut. This position
indicates an effective connection in which
the optical fibres in the plug are aligned
end-to-end with the fibre in the receptacle.
 FIBRE OPTICS
Fibre-optic connectors
Three start threads on the plug and
receptacle ensure a straight start when they
join. The recessed receptacle components
prevent damage from the plug if it strikes
the receptacle at an angle. The plug and
receptacle are automatically sealed in order
to prevent the ingress of moisture and dust.
 FIBRE OPTICS
KEY POINT
Care must be taken when assembling
optical fibre connectors, both in terms of the
correct alignment of the plugs and
receptacles and cleanliness of the contact
area (this is essential to ensure low loss and
efficient coupling). Before attempting to
examine the face or ceramic contacts of a
connector arrangement it is essential to
disconnect the cable from the equipment at
both ends. The light from the optical fibre is
invisible and can be intense enough to