CNS Concepts PDF

Summary

This document discusses the CNS (Communication, Navigation, and Surveillance) concepts, focusing on communication principles in air navigation systems. It covers radio wave propagation, radio communication systems, and radio navigation systems used in aerial navigation. The document is a training material, likely for aviation professionals.

Full Transcript

AIS
INDUCTION

CNS CONCEPTS
Revision 1 Jan 2024

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Introduction
Communication, Navigation and Surveillance (CNS) concept is an ICAO ideology
conceived by the ICAO Future Air Navigation Systems (FANS) committee, adopted by
the World-wide CNS/ATM Systems Implementation Conference (Rio de Janeiro, 1998)
and recommended for approval by the ICAO Assembly. This approval was granted by the
ICAO 32 session of 1998 as resolution A32-12.
The concept addresses the engineering aspect of Air Navigation both in equipment to be
used for effective aerial navigation operations and the personnel involved in their
implementation currently referred to as Air Traffic Safety Electronics Personnel (ATSEP).
The CNS systems are the main functions that form the infrastructure for Air Traffic
Management (ATM) and are essential for ensuring that an ICAO State’s air traffic is safe
and efficient.
CNS systems can only provide maximum benefits through enhanced ATM, it is important
for the State to have a robust Aeronautical Information Management (AIM) system. The
AIM unit in an ANSP is responsible for the collection and dissemination of information on
the serviceability and availability of airspace operation facilities. The message
dissemination is usually through radio communication. It is important that AIM personnel
understand the principles of operation of radio systems.
The CNS concept in this subject will focus on the CNS systems used for Aerial Navigation
and not CNS operation personnel. This is guided by ICAO Annex 10 (Aeronautical
Telecommunication) Volumes 1 to 5.

The objective of the subject is to provide the participants with Skills Knowledge and
Attitudes (SKAs) to enable them appreciate communication principles in ANS
applications. The areas of interest will include:
1. Principles of operation of radio communication systems in Air Navigation
operations
2. The application of radio communication systems in Air Navigation operations

The topics to be covered include:
1.
Radio wave propagation
2.
Radio communication systems
3.
Radio Navigation systems

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 4.
Radio surveillance systems

Note:
ICAO ANNEX 10 VOL VI, which deals with Communication Systems and Procedures
Relating to Remotely Piloted Aircraft Systems is not covered in this area.

COMMUNICATION PRINCIPLES

Communication is the back bone of Air Navigation without which the safety of an air space
cannot be assured.
Communication is the conveyance of intelligence from one point to another. In
communication principles, the originator of the intelligence is called a “source” while the
recipient is called a sink. The other definitions of communication include:
 Communication is the process of exchanging messages or information between
two or more parties.

Organizations are heavily dependent on information to meet organizational needs.
Effective communication plays a key role in fulfilling these needs and contributes
significantly to organizational success.
The Importance of Effective communication is crucial for the success of individuals as
well as organizations. This is true within the individual organization itself as well as how
that organization communicates with other organizations within its sphere of contact,
influence and competition. Communication is a complex two-way process, involving the
encoding, translation and decoding of messages.
Effective communication requires the communicator to translate their messages in a way
that is specifically designed for their intended audience. Creating and delivering an
effective message requires a basic understanding of the communication process.
Aviation requires clear and unambiguous communication of a message in a way that can
be clearly understood by the recipient. Communication process, involves the following
phases:

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  Sender
 Message
 Channel
 Receiver

The most important thing to remember is that in communication, the message that is
intended to be communicated is likely to be misunderstood. The sender apart from
carefully preparing and presenting their message must stay alert for any signs that their
audience are mis-interpreting their message. It is up to the presenter, to continually check
that their message has been received, understood, correctly interpreted and filed by the
receiver. Communication can take place in many forms, these include:
 Verbal communication
 Non- verbal communication
 Written communication
 Telecommunication (usually by use of radio signals)

The components of communication listed above can be grouped into three namely:
 The transmitter- sender or originator of intelligence
 The media – Speech, paper, radio wave, body
 Receiver- recipient of the intelligence

The most common form of Communication used in Air Navigation is radio communication.
In radio communication, the media connecting the transmitter and the receiver is through
radio waves.
Radio waves are a type of electromagnetic radiation with the longest wavelength in the
electromagnetic spectrum. They are typically found within the frequencies of 300
gigahertz (GHZ)) and below.

Electromagnetic Waves

Electromagnetic waves are also known as EM waves. Electromagnetic radiations are
produced when an electric field comes in contact with a magnetic field. The electric and
magnetic fields generated will be oscillating perpendicular to one another and to their
direction of motion. Electric field is produced whenever there is a charged particle. A
force is exerted by this electric field on other charged particles. Positive charges

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accelerate in the direction of the field and negative charges accelerate in a direction
opposite to the direction of the field.

The Magnetic field is produced when there is a moving charged particle. A force is exerted
by this magnetic field on other moving particles. The force on these charges is always
perpendicular to the direction of their velocity and therefore only changes the direction of
the velocity, not the speed.

The electromagnetic field is produced by an accelerating charged particle. The
electromagnetic waves are therefore electric and magnetic fields travelling through free
space with the speed of light c. An accelerating charged particle occurs when the charged
particle oscillates about an equilibrium position. If the frequency of oscillation of the
charged particle is f, then it produces an electromagnetic wave with frequency f. The
wavelength λ of this wave is given by λ = c/f. Electromagnetic waves transfer energy
through space. Electromagnetic waves can be represented diagrammatically by a
sinusoidal function.

The Electromagnetic waves are shown by a sinusoidal graph as above. It consists of time-
varying electric and magnetic fields which are perpendicular to each other and are also
perpendicular to the direction of propagation of the waves. Electromagnetic waves are
transverse in nature. The highest point of the wave is known as the crest while the lowest
point is known as a trough. In vacuum, the waves travel at a constant velocity of 3 x 10 8
m.s-1. Electromagnetic waves are related to visible light. They are classified into different
types based on their wavelength. The classification is referred to as the electromagnetic
spectrum.

Electromagnetic Spectrum

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The electromagnetic spectrum is a range of frequencies, wavelengths and photon
energies covering frequencies from below 1 hertz to above 10 25 Hz. These frequencies
correspond to wavelengths which are a few kilometres to a fraction of the size of an atomic
nucleus in the spectrum of electromagnetic waves. The electromagnetic spectrum
consists of a span of all electromagnetic radiation which further contains many subranges,
which are commonly referred to as portions. The entire range (electromagnetic spectrum)
is given by:

1. Radio waves- have longest wavelengths
2. Infrared radiation- next to visible light
3. Visible light
4. Ultra-violet radiation,
5. X-rays
6. Gamma rays and
7. Cosmic rays – shortest wavelengths, high frequencies and very high energy

Type of Radiation Frequency Range (Hz) Wavelength Range
Gamma-rays 1020 – 1024 < 10-12 m
X-rays 1017 – 1020 1 nm – 1 pm
Ultraviolet 10 – 10
15 17
400 nm – 1 nm
Visible 4 x 1014 – 7.5 x 1014 750 nm – 400 nm
Near-infrared 1 x 10 – 4 x10
14 14
2.5 μm – 750 nm
Infrared 1013 – 1014 25 μm – 2.5 μm
Microwaves 3 x 1011 – 1013 1 mm – 25 μm
11
Radio waves < 3 x 10 > 1 mm

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Radio waves are said to be the electromagnetic waves with the lowest frequencies (upto
below 3Hz) but longest wavelengths (above 10,000 Km)

Radio waves are also categorized into divisions referred to as radio frequency bands.
Electromagnetic waves in this frequency range are widely used in modern technology,
particularly in telecommunication (communication over a distance by means of cable,
telegraph, telephone, or broadcasting).
Radio waves can be generated artificially using electronic devices called transmitters.
The process of generation and transmission of radio waves is, however, strictly regulated
by national laws, coordinated by an international body called the International
Telecommunication Union (ITU). This strict regulation is aimed at preventing interference
between different users,

The International Telecommunication Union is a specialized agency of the United Nations
responsible for many matters related to information and communication technologies. The
body is responsible for:

 Allocation of global radio spectrum and satellite orbits

 Development of technical standards that ensure networks and technologies
seamlessly interconnect,

 Improvement of access to ICTs

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The frequency boundaries of the radio spectrum are a matter of convention in physics
and are somewhat arbitrary. Since radio waves are the lowest frequency category of
electromagnetic waves, there is no lower limit to the frequency of radio waves.

Radio waves are defined by the ITU as: "electromagnetic waves of frequencies arbitrarily
lower than 3000 GHz, propagated in space without artificial guide". At the high frequency
end the radio spectrum is bounded by the infrared band.

The boundary between radio waves and infrared waves is defined at different frequencies
in different scientific fields. Example the terahertz band, from 300 gigahertz to 3 terahertz:

 Can be considered either as microwaves or infrared.

 It is the highest band categorized as radio waves by the ITU

 Spectroscopic scientists consider these frequencies part of the:

 Far- infrared

 Mid- infrared bands.

A radio band is a small frequency band (a contiguous section of the range of the radio
spectrum) in which channels are usually used or set aside for the same purpose. For
example, broadcasting, mobile radio, or navigation devices, will be allocated in non-
overlapping ranges of frequencies. ITU has a band plan which dictates how each of these
bands is to be used and shared. The plan aims at avoiding interference and to setting
protocol for the compatibility of transmitters and receivers.

Pursuant to convention, the ITU divides the radio spectrum into 12 bands (as shown in
the table below), each beginning at a wavelength which is a power of ten (10 n) metres,
with corresponding frequency of 3×108−n hertz, and each covering a decade of frequency
or wavelength. Each of these bands has a traditional name (example “Tremendously Low
Frequency (TLF)”- used for frequencies from 1- 3 Hz though not defined by ITU).

Band Name Abbreviation ITU Frequency Wavelength
Number
Extremely ELF 1 3- 30 Hz 100,000- 10,000
Low Km
Frequency

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 Super Low SLF 2 30- 300 Hz 10,000- 1,000 Km
Frequency
Ultra Low ULF 3 300- 3,000 HZ 1,000 – 100 Km
Frequency
Very Low VLF 4 3- 30 KHz 100 – 10 Km
Frequency
Low LF 5 30 – 300 KHz 10 – 1 Km
Frequency
Medium MF 6 300 – 3,000 KHz 1,000 – 100m
Frequency
High HF 7 3- 30 MHz 100 – 10 m
Frequency
Very High VHF 8 30 – 300 MHz 10 – 1m
Frequency
Ultra High UHF 9 300 – 3,000 MHz 100 – 10 cm
Frequency
Super High SHF 10 3 – 30 GHz 10- 1cm
Frequency
Extremely EHF 11 30 – 300 GHz 10 – 1mm
High
Frequency
Tremendously THF 12 300 – 3,000 GHz 1- 0,1mm
High
Frequency
(Terahertz)
The wavelength of a radio wave (any electromagnetic wave) is inversely proportional to
its frequency because its velocity is constant. At 300 GHz, the corresponding
wavelength is 1mm, which is shorter than the diameter of a grain of rice. At 30 Hz the
corresponding wavelength is ~10,000 kilometers (6,200 miles), which is longer than the
radius of the Earth.

Like all electromagnetic waves, radio waves in a vacuum travel at the speed of light. On
the Earth's atmosphere, however, they travel at a slightly slower speed due to change in
media. Radio waves are generated by charged particles undergoing acceleration, such
as time-varying electric currents. Naturally occurring radio waves are emitted by:

 Lightening

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  Astronomic objects – example stars

 Black body radiation- emitted by warm objects

Radio Propagation

Radio waves travelling through a media which is not a vacuum will experience changes
in its propagation depending on the characteristics of the media.

Radio waves will experience the following when travelling through a media that is not a
vacuum:

 Reflection,

 Refraction

 Absorption

 Diffraction

 Polarization.

Radio Wave Reflection

Reflection in waves is the phenomenon where a wave encounters a boundary or interface
and is turned back into its original medium. Unlike wave refraction, which involves a
change in direction and medium, reflection keeps the wave in the same medium but
reverses its direction. When a wave encounters an obstacle or a boundary, part or all of
the wave can be reflected, depending on various factors like the angle of incidence and
the properties of the reflecting surface.

The law of reflection states that the angle of incidence is equal to the angle of reflection:

θ1=θ2

Both angles are measured relative to the normal line, which is the imaginary line
perpendicular to the boundary at the point where the wave hits. If a wave hits a boundary
head-on, it will be reflected back along the same path.

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Radio Wave Refraction

Refraction in waves refers to the bending or change in direction of a wave as it passes
from one medium into another. This bending occurs because the speed of the wave varies
in different media, causing the wave to alter its course.

When a wave encounters a change in medium, its speed and wavelength can change,
while its frequency remains constant. The change in speed leads to a change in the
wave’s direction, causing it to bend.

When working with light waves and optics, we often refer to Snell’s Law.

This is the mathematical formulation for wave refraction:

n1sinθ1= n2sinθ2

n1 and n2 are the indices of refraction for the first and second mediums, respectively

θ1 and θ2 are the angles of incidence and refraction, also respectively

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The index of refraction is a dimensionless number that describes how fast light travels
through a material. The higher the index, the slower the speed of light in that medium.

For example, the index of refraction of air is approximately 1, while for water, it’s about
1.33. Light travels slower in water than in air.

Radio Wave Absorption

Radio wave absorption is the transfer of energy from a wave to a medium. The medium
can be a solid, liquid, or gas. The absorption of electromagnetic radiation (radio waves)
is how matter (typically electrons bound in atoms) takes up a photon’s energy — and so
transforms electromagnetic energy into internal energy of the absorber (for example,
thermal energy)

A notable effect of the absorption of electromagnetic radiation is attenuation of the
radiation; attenuation is the gradual reduction of the intensity of light waves as they
propagate through the medium.

The main effect of absorption of radio waves by materials is to heat them, similarly to the
infrared waves radiated by sources of heat such as a space heater or wood fire.

Radio Wave Diffraction

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Diffraction is the tendency of a wave emitted from a finite source or passing through a
finite aperture to spread out as it propagates. It can also be explained as the interference
or bending of waves around the corners of an obstacle or through an aperture into the
region of geometrical shadow of the obstacle/aperture.
The diffracting object or aperture effectively becomes a secondary source of the
propagating wave.
Diffraction results from the interference of an infinite number of waves emitted by a
continuous distribution of source points.

Huygens’ principle postulates that every point on a wave front of light can be considered
to be a secondary source of spherical wavelets. These wavelets propagate outward with
the characteristic speed of the wave. The wavelets emitted by all points on the wave front
interfere with each other to produce the traveling wave.
This principle is also true for electromagnetic waves. In the propagation of light, the term
“any wave front” can be replaced by “a collection of sources distributed uniformly over the
wave front, radiating in phase”.

An example of radio wave diffraction is observed in radio communication in hilly areas

Radio Wave Polarization

Polarization is a property of transverse waves which specifies the geometrical orientation
of the oscillations. In a transverse wave, the direction of the oscillation is perpendicular
to the direction of motion of the wave.

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Example of a polarized transverse wave is vibrations traveling along a taut string like a
guitar string. The vibrations can be in the vertical direction, horizontal direction or at an
angle perpendicular to the string depending on how the string is plucked.

Longitudinal waves, like sound waves, in liquid or gas do not exhibit the same effect as
the displacement of the particles in the oscillation is always in the direction of propagation-
they do not exhibit polarization. Radio waves are transverse and therefore exhibit
polarization.

Example of Polarized Radio Wave

A "vertically polarized" radio wave of wavelength λ has its:

 Electric field vector E (red) oscillating in the vertical direction.

 The magnetic field B (or H) is always at right angles to it (blue),

 Both are perpendicular to the direction of propagation (z).

One can test whether sunglasses are polarized by looking through two pairs, with one
perpendicular to the other. If both are polarized, all light will be blocked.

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Note:

The properties listed above are very important in radio communication as they determine
the type of systems to be used and their limitations.

Radio waves have different propagation characteristics in the Earth's atmosphere
including:

 Long waves can diffract around obstacles like mountains and follow the contour
of the earth while

 Shorter waves can reflect off the ionosphere and return to earth beyond the
horizon.

Radio Wave Propagation in the Earth’s Atmosphere

Electromagnetic waves (radio waves) when propagating through the Earth’s atmosphere
will exhibit certain characteristics due to the condition of the environment they are passing
through. The environment can have the following:

 charged particles of matter,

 Water particles (humid)

 Solid body (mountains, hills, tall buildings)

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The conditions listed above will affect the wave differently depending on their wavelength.
The study of radio propagation. Practical radio systems mainly use three different
techniques of radio propagation to communicate namely:

1. Line of sight
2. Ground waves
3. Skywaves

Line of Sight Wave Propagation

This is a characteristic of electromagnetic radiation in which waves can only travel in a
direct visual path from the source to the receiver. Electromagnetic transmission includes
light emissions traveling in a straight line. The rays or waves may be:

 Interfered with by the atmosphere
 Obstructed by materials eg, buildings
 Prevented from travelling over the horizon

Radio waves of frequencies above 30 MHz (VHF and higher) any obstruction between
the transmitting antenna (transmitter) and the receiving antenna (receiver) will block the
signal, just like the light that the eye may sense.

The ability to visually see a transmitting antenna (disregarding the limitations of the eye's
resolution) roughly corresponds to the ability to receive a radio signal from it, the
propagation characteristic at these frequencies is called "line-of-sight".

The farthest possible point of propagation is referred to as the "radio horizon".

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Ground Wave Propagation

Ground waves are radio waves propagating parallel to and adjacent to the surface of the
Earth, following the curvature of the Earth beyond the visible horizon. This type of
radiation is known as:

 Norton surface wave
 Norton ground wave,

Ground waves in radio propagation are not confined to the surface. The normal line-of-
sight distance to the horizon is about 80 to 100 kilometers (50 to 60 miles) at best, for an
antenna on a tall tower. Signals at medium or low frequency are observed to travel several
hundred miles beyond the horizon, up to several thousand kilometers in some cases.

This attachment to the ground effect is called ground wave, as opposed to direct wave
or sky wave. This effect does not occur for signals in the VHF or UHF frequencies, which
typically propagate only about 100 km (60 miles) to the horizon.

Ground propagation works because lower-frequency waves are more strongly diffracted
around obstacles due to their long wavelengths. This allows them to repeatedly bend
downward to follow the Earth’s curvature

Ground waves propagate in vertical polarization, with their magnetic field horizontal and
electric field vertical. Conductivity of the surface affects the propagation of ground waves,
with more conductive surfaces such as sea water providing better propagation. Since the

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ground is not a perfect electrical conductor, ground waves are attenuated as they follow
the earth's surface.

The wave fronts initially are vertical, but the ground, acting as a lossy dielectric, causes
the wave to tilt forward as it travels. This directs some of the energy into the earth where
it is dissipated so that the signal decreases exponentially.

Sky Wave Propagation

Sky wave propagation is a type of radio wave communication in which the
electromagnetic wave propagates due to the reflection mechanism of the ionospheric
layer of the atmosphere. It occurs as a result of radio wave propagation through the
Earth’s ionosphere and this is why it is also known as inonospheric wave propagation.
The radio frequencies within which sky wave propagation is dominant is between 3 MHz
to 30 Mhz

Electromagnetic waves in the range of 3 to 30 MHz get reflected by the ionosphere.
Signals with frequency beyond 30 MHz despite undergoing reflection are able to
penetrate the ionosphere making the phenomenon less noticeable within such ranges.

It allows the propagation of electromagnetic waves of higher frequency from one end to
another at a larger distance than ground wave propagation. And it does so by reflections
of the wave from the ionosphere. This phenomenon is sometimes referred to as
ionospheric wave propagation.

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Sky wave propagation takes place because of the composition of the ionosphere. The
ionosphere is composed of 4 different layers with each layer consisting of a different
number of atoms. The outmost layer has the lowest number of atoms while the innermost
layer of the ionosphere is highly dense.

The reason behind this is that the atmosphere of earth is denser towards its surface and
becomes rarer on proceeding upwards. The sun emits powerful cosmic rays. The cosmic
rays penetrate go through the outer surface to the inner surface of the atmosphere without
much interaction. This occurs because there are less number of neutral atoms in the
outermost layer.

The inner layer is slightly denser than the outer one so here interaction between cosmic
rays and atoms takes place. The interaction between cosmic rays and the atoms
increases tremendously in the E layer of the ionosphere, as this layer has a greater
number of atoms.

The intensity of the cosmic rays reduces as they penetrate to lower levels inside the
earth’s atmosphere making it possible for only few cosmic rays to interact with the
innermost layer of the ionosphere (the densest layer)

The interaction between the cosmic rays and atoms present in the ionospheric layers
makes electrons be emitted from the valence shell of the atom (ionization takes place).
This interaction is higher in the middle layers of the atmosphere, therefore, ionization will
be higher in that layer. The layer thus holds the maximum number of charged particles.

The result of this phenomena is that whenever an electromagnetic signal is transmitted
from the ground, it suffers reflection from the ionospheric layer and comes back to the
surface of the Earth.

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The characteristics above determine the type of radio system that would be suitable for a
particular operation. An example of such a case is when the sky wave propagation
phenomena is used to cover long distance.

 At medium wave and short wave wavelengths, radio waves reflect off conductive
layers of charged particles (ions). Radio waves directed at an angle into the sky can
return to Earth beyond the horizon.
 Use of multiple skips will provide multiple skips communication
 Multiple skips communication will enable communication in intercontinental distances
to be achieved,

Skywave propagation is variable and dependent on atmospheric conditions; it is most
reliable at night and in the winter.
Radio waves are more widely used for communication than other electromagnetic waves
mainly as a result of: their desirable propagation properties, stemming from their large
wavelength. These include:

 They have the ability to pass through the atmosphere in any weather, foliage,
 They have the ability to pass through most building materials,
 By diffraction longer wavelengths can bend around obstructions,

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  Unlike other electromagnetic waves they tend to be scattered rather than absorbed
by objects larger than their wavelength.

In Air Navigation, radio waves are used for several important operations, the most
important operations are:

1. Radio communication

2. Radio Navigation

3. Radio Surveillance

RADIO COMMUNICATION IN AIR NAVIGATION OPERATIONS

A radio communication system (communication, navigation or surveillance) is composed
of three (3) important components; namely:

1. The transmitter – information source
2. The media – the information path (Radio waves in radio communication)
3. The receiver – the consumer of the information or information sink

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The Components of a Radio Transmitter

Radio transmitter components include:

 The signal source- human being in voice communication
 The signal encoder- makes the signal adapted specifically for the intended
recipient
 Transducer- microphone in voice communication
 Modulator- Mixer of the signal produced by the transducer and the required
transmission frequency
 Amplifier- To provide correct signal strength
 Transmission aerial- radiates the signal into space

Radio Receiver Components will include:

 The receiving aerial
 The signal demodulator- to remove the mixed signal from the information signal
 A signal filter- to remove unwanted signals (noise) introduced during signal
propagation in space
 Signal amplifier- to increase signal intensity for interpretation

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  Signal decoder- to convert the signal to a form which can be understood by the
recipient
 Signal transducer- to convert the signal to a form that can be understood by the
recipient (loudspeaker converting electrical signal to sound signals)
 The signal sink- the human being in the case of voice communication.

In Air Navigation, voice communication is one of the most commonly used forms of
communication between:

 Air traffic controllers and pilots
 Units

The most common systems used are radio transceivers.

Radio Transceivers

A transceiver is an electronic device which is a combination of a radio transmitter (origin
of “TRANS”) and a receiver (origin of “CEIVER”). In radio communication, such a system
can both transmit and receive radio waves. These two related functions are often
combined in a single device to reduce manufacturing costs.

The term is also used for other devices which can both transmit and receive through a
communication channel like:

 Optical transceivers which transmit and receive light in optical fiber systems
 Bus transceivers which transmit and receive digital data in computer data buses

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Communication transceivers are found in two (2) forms; namely:

1. Half duplex
2. Full duplex

Half Duplex Transceiver

The communication can only take place in one (1) direction at a time. It is said that in this
type of communication, only one thing on that channel -- node -- can "talk" or transmit
information at a time. Once one node has finished transmitting its data, another node can
start transmitting data.

In half duplex communication, if multiple nodes try to talk at the same time, a collision will
occur on the network, resulting in transmission errors or data loss. Half-duplex networks
require a mechanism to avoid data collisions.

Example of a half- duplex transceivers is a standard walkie-talkie. The walkie-talkie can
either transmit or receive communication. There is a communication procedure that
speakers use to tell listeners they are done transmitting the current piece of information.
For example, on a walkie-talkie, a user would say "over" when done talking or say "over
and out" when getting off the line for a substantial amount of time.

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Full Duplex Transceiver

Full-duplex communication is a type of communication where both the transmission and
reception of data can be done simultaneously. It is widely used in modern communication
systems, including wireless networks, satellite communication, and radio communication.

Full-Duplex communication can be achieved in two ways; namely:

 By using a single physical communication channel for both directions
simultaneously
 By using two distinct physical channels, one for each direction (dual- simplex
communication).

Full-duplex communication is a powerful technology that can greatly improve the
efficiency and throughput of communication systems. The benefits of full-duplex
communication make it a valuable technology for a wide range of applications.

Wireless technologies like Bluetooth, Wi-Fi and cellular networks use a single physical
channel for communication in both directions simultaneously. In these types of full-duplex
systems, communication in both directions simultaneously is achieved by using two
techniques; namely:

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  Time division duplexing (TDD)
 Frequency division duplexing (FDD),

Time Division Duplexing (TDD)

The same frequency band is used for both transmitting and receiving, but the time is
divided into two parts. During the first part, one party can transmit data while the other
party listens, and during the second part, the roles are reversed.

This technique is commonly used in wireless networks such as Wi-Fi and Bluetooth.

Frequency Division Duplexing (FDD)

Two separate frequency bands are used for transmitting and receiving data. The
transmitting and receiving frequencies are usually separated by a specific frequency band
to prevent interference. This technique is commonly used in cellular networks such as 4 th
Generation Long Term Evolution (4 G LTE) networks.

Radio transceivers are commonly used in Air Navigation operations at the control tower
to relay important airspace information between Air Traffic Controllers and Pilots.

Air Navigation Service Providers (ANSP) use other communication systems apart from
radio communication systems to enable inter-unit or administrative communication. The
systems used are usually land based. These include:

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  Landline Telephones
 Intercoms

Land Line Telephones

A telephone is a telecommunication device that permits two or more users to conduct a
conversation when they are too far apart to be easily heard directly. A telephone converts
sound, typically and most efficiently the human voice, into electronic signals that are
transmitted via cables and other communication channels to another telephone which
reproduces the sound to the receiving user.

The term is derived from Greek (tēle, far) and (phōnē, voice), together meaning distant
voice

The essential elements of a telephone are:

 Microphone (transmitter) to speak into
 Earphone (receiver) which reproduces the voice at a distant location.

The receiver and transmitter are usually built into a handset which is held up to the ear
and mouth during conversation.

The transmitter converts the sound waves to electrical signals which are sent through the
telecommunication system (cable) to the receiving telephone, which converts the signals
into audible sound in the receiver or sometimes a loudspeaker.

Telephones permit transmission in both directions simultaneously. Most telephones also
contain an alerting feature, such as a ringer or a visual indicator, to announce an incoming
telephone call. Telephone calls are initiated most commonly with a keypad or dial, affixed
to the telephone, to enter a telephone number

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Intercoms in Air Navigation Operations

An intercom, also called an intercommunication device, inter-communicator, or
interphone, is a stand-alone voice communications system for use within a building, small
collection of buildings or portably within a small coverage area which functions
independently of the public telephone network.

Intercoms are:

 Generally mounted permanently in buildings and vehicles, but can also be
detachable and portable.
 Can incorporate connections to:
 Public address loudspeaker systems
 walkie- talkies
 Telephones
 Other intercom systems.
 Incorporate control of devices such as signal lights and door latches.

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Signal Transmission Methods

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The method used for information transfer can be analog or digital. In analog
communication, the modulating wave is continuous just as the carrier wave. The type of
modulation can be:

 Amplitude Modulation (AM)- the carrier signal amplitude is varied by the
information signal
 Frequency Modulation (FM)- the carrier signal frequency is varied by the
information signal
 Phase Modulation (PM)- the carrier signal phase is varied by the information
signal.

The other method of signal transmission is digital with the end communication type being
referred to as Digital communication.

Digital Communication

The term digital communication is made from two words; namely:

 Digital
 Communication.

The term “Digital” refers to the discrete time-varying signal and “Communication” refers
to the exchange of information between two or more sources. Digital Communication can
therefore be said to be the exchange of information between two or more sources by
means of discrete time varying signals.

The data transmission using analog methods for long-distance communication suffers
from distortion, delays, interferences, and other losses.

The interferences above come about because of the nature of the signals in the
atmosphere. The interferences are usually positive and continuous. The effects can
therefore be mitigated against if an inverted discrete time varying signal is used.

Digitization and sampling of signals using different techniques help in making the
transmission process more efficient, clear and accurate.

Diagrammatical representation of Analog and Digital signals

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Digital Communication System

The sequence of events in the signal processing is as follows:

 The input signal is first applied to the input transducer
 The input transducer converts the signal into electrical form for the source encoder
 The source encoder converts the continuous signal to discrete time varying signal
(required number of bits) for the channel encoder

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  The channel encoder removes any errors by adding the redundant bits to the input
digital data for the modulator
 The modulator mixes the signal with the carrier signal for transmission through the
radio channel
 The transmitted signal passes through the communication channel to reach the
receiver
 The demodulator retrieves the message signal from the carrier for the channel
decoder
 The channel decoder and source decoder convert the digital signal to its original
format for the output transducer
 The output transducer converts the digital signal into its original form of
transmission.

The output signal is a digital signal with no interference, noise, and error and is suitable
for the user to capture.

In Air Navigation, one application of digital data communication is in the Controller Pilot
Data Link Communication (CPDLC)

Controller Pilot Data Link Communications (CPDLC) is a means of communication
between controller and pilot, using data link for ATC communications. (ICAO Doc 4444:
PANS-ATM).
It is a two-way data-link system by which controllers can transmit non- urgent strategic
messages to an aircraft as an alternative to voice communications. The message is
displayed on a flight deck visual display.
It enables a number of data link services (DLS) that provide for the exchange of
communication management and clearance/information/request messages which
correspond to voice phraseology employed by air traffic control procedures.
 The controllers are provided with the capability to issue ATC clearances
 The pilots are provided with the capability to respond to messages

RADIO NAVIGATION

Navigation is a field of study that focuses on the process of monitoring and controlling the
movement of a body from one place to another. The field of navigation includes four
general categories; namely:

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  Land navigation (movement of humans, motor vehicles)
 Marine navigation (movement of vehicles (boats, ships) in water)
 Aeronautic navigation (movement of aircrafts)
 Space navigation (movement of space crafts)

The term can also be used when referring to the art used for the specialized knowledge
used by navigators (a person inside a vehicle responsible for its navigation) to perform
navigation tasks. All navigational techniques involve locating the navigator's
position compared to known locations or patterns.

Navigators measure distance on the globe in degrees. The Navigator must be conversant
with the bearings of the positions to be navigated, this involves understanding of
the latitude and longitude of the initial and terminal points.

 Latitude is a north-south position measured from Earth's Equator
 Longitude is an east-west position measured from the prime meridian.

The earliest navigation methods involved observing landmarks or watching the direction
of the sun and stars. The current navigation methods are by radio. Radio navigation is
similar to celestial navigation, except it replaces objects in the sky with radio waves being
broadcast. The navigator can tune into a radio station and use an antenna to find the
direction of the broadcasting radio antenna. Position can be determined by measuring the
time it takes to receive radio signals from the stations of known locations on the ground
or aboard satellites. This is the method vastly used in Air Navigation.

Radio navigation is the application of radio waves to determine a position of an object on
the Earth. The object can be a vessel or an obstruction.

The basic principles are based on measurements from/to electric beacons. A radio
beacon being a device that marks a fixed location and allows direction finding equipment
to find relative bearing. In radio beacons, this is done using electromagnetic waves in the
radio wave band.

The beacons transmit a continuous or periodic radio signal with limited information (for
example, its identification or location) on a specified radio frequency. The information is
used by the receiver (vehicle) to determine the beacon location/ position from its position.
The navigator (pilot in case of aircraft) can then move the vehicle towards or away from
the beacon.

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In air transport, several equipment are used as radio beacons. They are collectively called
Radio Navigation Aids (NAVAIDs). They are specified in ICAO Annex 10 Vol.1-
Aeronautical Telecommunication- Radio Navigation Aids.

The equipment used include:

 Non- Directional Beacon (NDB)
 Very high frequency Omni- Range transmitter (VOR)
 Conventional (CVOR)
 Doppler (DVOR)
 Distance Measuring Equipment (DME)
 Instrument Landing System (ILS)
 Microwave Landing System (MLS)
 Automatic Direction Finder (ADF)
 Marker beacons
 Global Navigation Satellite Systems with relevant augmentation namely:
 Airborne Based Augmentation (ABAS)
 Ground Based Augmentation (GBAS)
 Space Based Augmentation (SBAS)
 GNSS Receiver for Atmospheric Sounding (GRAS)

Non- Directional Beacon (NDB)

A non- directional beacon (NDB) sometimes called Non- Directional Radio Beacon is a
radio beacon without inherent directional information.

ICAO Annex 10 Vol.1 standardizes the use of NDBs in Aviation specifying that they be
operated on a frequency between 190 kHz and 1750 kHz. They are to be identified by a
one, two, or three-letter Morse code referred to as a callsign. In some countries like
Canada, privately owned NDB identifiers consist of one letter and one number.

The radio waves being emitted by NDBs, as per the ICAO regulations, are within the Low
frequency (LF) and Medium Frequency (MF) radio frequency bands. Signals in this
frequency band propagate as ground waves, following the curvature of the Earth. This
makes it possible to receive them at much greater distances at lower altitudes.

NDB signals are affected more by atmospheric conditions, mountainous terrain, coastal
refraction and electrical storms, particularly at long range.

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There are four types of non-directional beacons in the aeronautical navigation service:

 En route NDBs, used to mark airways
 Approach NDBs
 Localizer beacons
 Locator beacons
The last two types are used in conjunction with an instrument landing system (ILS).

NDB Operation

NDB navigation consists of two parts;

 The ground NDB transmitter
 The automatic Direction Finder (ADF)

The ground transmitter sends an omnidirectional signal out. The signal is in Morse code
usually providing the identity of the beacon, example Tango Hotel (TH).

Diagram of NDB ground transmitter

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The information is received in the aircraft processed by the Automatic Direction Finder
(ADF) inside the aircraft.

The processed information is displayed to the pilot to indicate the aircraft position relative
to an NDB station.

The pilot can use the information to “ home” to a station or track a course from the station.

The NDB transmits a continuous carrier wave that can be received by any aircraft
equipped with ADF. The NDB frequency and identification information is published by
states in the aeronautical chart. The Morse Codes are used to identify NDB stations while
the normal commercial broadcast stations are identified by the station’s announcer.

ADF equipment determines the direction or bearing to the NDB station relative to the
aircraft by using a combination of directional and non-directional antennae to sense the
direction in which the combined signal is strongest.

This bearing may be displayed on a relative bearing indicator (RBI). The display looks
like a compass card with a needle superimposed. The card is fixed with the 0-degree
position corresponding to the centre line of the aircraft.

In order to track toward an NDB (with no wind), the aircraft is flown so that the needle
points to the 0- degree position. The aircraft will then fly directly to the NDB. Similarly, the
aircraft will track directly away from the NDB if the needle is maintained on the 180-

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degree mark. With a crosswind, the needle must be maintained to the left or right of the
0 or 180 position by an amount corresponding to the drift due to the crosswind. Aircraft
heading +/- ADF needle degrees off nose or tail = Bearing to or from NDB station.

Plotting fixes in this manner allow crews to determine their position.

NDBs have long been used by aircraft navigators, and previously mariners, to help obtain
a fix of their geographic location on the surface of the Earth. Fixes are computed by
extending lines through known navigational reference points until they intersect. For
visual reference points, the angles of these lines can be determined by compass, the
bearings of NDB radio signals are found using radio direction finder (RDF) equipment.

NDB systems have disadvantages that make them not very suitable for air navigation
hence recommendation for their removal. The disadvantages affect their accuracy
especially at long distances, they include effects due to:

 Atmospheric conditions
 Mountainous terrain
 Coastal refraction
 Electrical storms
 Cone of confusion

Note:

A great advance in the RDF technique was introduced in the form of phase comparisons
of a signal as measured on two or more small antennas, or a single highly directional
solenoid (electromagnetic formed by a helical coil of a conducting wire like copper wire.)

These receivers were smaller, more accurate, and simpler to operate. Combined with the
introduction of the transistor and integrated circuits RDF systems were so reduced in size
and complexity that they once again became quite common during the 1960s, and were

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known by the new name Automatic Direction Finder (ADF). This led to their operation with
simple radio beacons – the non- directional beacons.

NDBs can follow the curvature of earth, hence the much greater range than the line of
sight systems. They can be categorized as long range or short range depending on their
power.

The formula to determine the compass heading to an NDB station (in a no wind situation)
is to take the relative bearing between the aircraft and the station, and add the magnetic
heading of the aircraft; if the total is greater than 360 degrees, then 360 must be
subtracted. This gives the magnetic bearing that must be flown: (RB + MH) mod 360 =
MB.

When tracking to or from an NDB, it is also usual that the aircraft track on a specific
bearing. To do this it is necessary to correlate the RBI reading with the compass heading.
Having determined the drift, the aircraft must be flown so that the compass heading is the
required bearing adjusted for drift at the same time as the RBI reading is 0 or 180 adjusted
for drift. An NDB may also be used to locate a position along the aircraft's current track
(such as a radial path from a second NDB or a VOR). When the needle reaches an RBI
reading corresponding to the required bearing, then the aircraft is at the position.

Very high frequency Omni- Ranging (VOR) System

VHF Omnidirectional Radio Ranging (VOR) is an aircraft navigation system operating in
the VHF band. The system is composed of a ground transmitting station and a receiver
inside an aircraft (receiving station)

It is a short-range radio navigation aid that produces an infinite number of bearings that
may be visualized as lines radiating from the beacon.

The phase of the variable signal lags that of the reference signal by an amount equal to
the azimuth angle around the beacon. The number of bearings is limited to 360, one
degree apart; a radial is identified by its magnetic bearing from the VOR.

VORs transmitter broadcast a VHF radio composite signal. The composite signal
includes:

 VOR station's Morse Code identifier (and sometimes a voice identifier)

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  Data – used by airborne receiving equipment to derive the magnetic bearing from
the station to the aircraft.

The station’s Morse code identifier is three letter identifier. VOR signals have a range of
about 200 miles making it possible for an aircraft to receive multiple VOR signals. Pilots
must identify a VOR they need before navigating to it to ensure the proper navigation aid
is selected. In some cases, a voice signal is broadcast with the station name. This should
contain recorded advisories. There are about 3,000 VOR stations worldwide

VOR was first introduced in the 1950s as a development from Visual-Aural Range (VAR)
systems.
The basic principle of VOR is the same as that of a lighthouse, to provide a rotating signal
such that a bearing from the station can be derived. VOR achieves this by transmitting a
pair of 30Hz rotating signals, one FM and one AM and the airborne receiver will compare
the phase angle of the two signals radiated from the beacon to get the bearing(‘radial’).
One signal radiates Omni-directionally so that its phase is equal in all directions; this
signal is referred to as the ‘Reference’ signal. The second signal, called the ‘Variable’
signal, radiates from a directional array. The phase of the variable signal received at the
aircraft is dependent upon the radial on which the receiver lies with respect to Magnetic
North. The aircraft receives the two 30Hz signals, demodulates them and simply
compares their phase difference to derive the bearing from the station.
A VOR receiver, regardless of the technology behind, receives two sine signals repeating
30 times per second: Reference and variable signals, and determines the bearing by
solely measuring the difference between their phases.

From a carrier standpoint, only amplitude modulation is used, but to minimize a possible
influence of one signal onto the other, the VOR station uses a subcarrier, which frequency
is low (9,960 Hz) but significantly distant from 30 Hz.

 One phase value is conveyed by normally modulating the carrier in amplitude,
 The other by modulating the subcarrier in frequency
 The subcarrier then modulates the carrier in amplitude.

Two antenna systems are used:

 The carrier and the reference are send on one or more omnidirectional antenna(s)
and all receivers see the same reference phase at the same time.

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 The variable signal is sent apart to appear different for receivers at different bearings.
The type of antenna used depends on the type of VOR system.
The variable signal is not created by actual modulation of the carrier, but by synthetic
sidebands.
This variation can be achieved mechanically or electrically.
There are two (2) VOR systems, namely:
 Conventional VOR (CVOR)
 Doppler VOR (DVOR)

Conventional VOR (CVOR)

C-VOR and D-VOR differ by how the variable phase is made different for receivers at
different bearings. The method relies on amplitude for a conventional VOR and on
frequency for a Doppler VOR. In the CVOR, the signals being radiated are mechanically
rotated.

Early generations used a rotating dipole antenna to broadcast the variable signal. These
were replaced by static antennas or slots on a cylinder. The mechanical signal rotation
was accomplished through a physically rotating device.

There are several types of conventional VORs using either rotating or static antennas.
What they have in common is:

 They are relatively compact.
 Bearing is determined from a HF signal rotating 30 rounds per second.
 They are very sensitive to multipath interference created by reflection on nearby
obstacles, and must be located at isolated places. They are often used for airway
beaconing.
There is a ground component and an airborne component.

Diagram of the ground component

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The Aircraft equipment includes:

 A VOR antenna
 A VOR frequency selector
 A cockpit instrument to display the course information, this can be:
o A Course Deviation Indicator (CDI)
o A Horizontal Situation Indicator (HIS)

The VOR equipment operate on radio frequency band 108.0 – 117.95 MHz. Their power
output should be enough to provide coverage within their assigned operational service
volume.

Doppler Very High Frequency Omni- Ranging (DVOR) system

The DVOR works on the principle of Doppler effect and was developed to mitigate against
the atmospheric problems experienced in CVOR operations.

The Doppler effect, or Doppler shift, describes the changes in frequency of any kind of
sound or light wave produced by a moving source with respect to an observer. Waves
emitted by an object traveling toward an observer get compressed — prompting a higher
frequency — as the source approaches the observer. In contrast, waves emitted by a
source traveling away from an observer get stretched out- prompting a lower frequency.

This VOR consists in an array of about 50 fixed Alford loop antennas located on a 14 m
circle. Two opposite antennas are activated at a time, and are electronically switched so
the active antennas seem to be moving along the circle at 30 rounds per second.

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A 110 MHz source moving between -1,300 and +1,300 m/s creates a Doppler shift
between -480 Hz and +480 Hz. This value, consecutive to the selection of the appropriate
array diameter, is the same than the 480 Hz FM swing of the C-VOR, making the D-VOR
compatible.

Ground- Transmitter Operation

The 30 Hz reference AM modulates the carrier which is sent in all directions by an antenna
at the center of the circular array.

The actual perceived Doppler shift depends on the direction of the displacement relatively
to the receiver:

 Maximum when "side" antennas are activated,
 Null when "front" and "rear" antennas are activated.

The receivers see a frequency variation repeating 30 times per second, and starting at a
time varying with their own bearing.

The shift can be used as the variable signal.

The repeating Doppler shift being undistinguishable from frequency modulation, the
variable signal must be conveyed in FM.

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 Each active antenna of the array transmits a pure frequency corresponding to a
sideband of the subcarrier: f-9.96 kHz and f+9.96 kHz, f being the VOR carrier
frequency. When associated with the carrier sent from the central antenna, these
sidebands represent a carrier AM modulated by the 9.96 kHz signal.
 When antennas radiating their pure frequency are given their angular velocity of 30
rps by the scan, a cyclic Doppler shift between -480 Hz and +480 Hz is automatically
added.

There are also several types of Doppler VORs, single or double sideband. The following
are the general characteristics of DVORs:

 They require a large 14 m diameter circular array of antennas.
 Bearing is determined from the Doppler effect created by scanning the array
at 1,300 m/s.
 They are less efficient, inactive antennas from the array absorb a significant
part of the signal emitted from the active antennas, reducing the effective
range.

They are less sensitive to multipath, and are easier to install at airfields

Both types of VOR (and their different subtypes) are required by ICAO to produce a
bearing with a ±2° tolerance.

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 The D-VOR is better in this aspect because it’s easier to produce an accurate Doppler
shift than to form a precise pattern with space modulation.

The VOR Receiver

The signals transmitted from ground station are received by the aircraft's VOR antenna,
which is usually located on the tail.

The received signal is transfers it to the receiver in the cockpit for processing.

The aircraft's VOR receiver compares the difference between the VOR's variable and
reference phase, and determines the aircraft's bearing from the station. This bearing is
the radial that the aircraft is currently on.

Note:

1. Both types have the same tolerances from an ICAO requirements

2. The transmitting elements must be accurate to 2°.

3. Most stations are able to transmit a signal with an accuracy better than 0.5°.

4. A perfectly sited VOR could deliver this precision to the receivers.

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Advantages of using VOR

The advantages of using VOR systems for air navigation include:

1. Accuracy- VOR provides pilots with highly accurate and reliable navigation
information
2. Continuous Operation- VOR operates continuously. This makes it a dependable
navigation systems regardless of weather conditions
3. Long- Range Coverage- VOR provides long- range coverage, making it ideal for
cross- country flights
4. Reliability- VOR systems are highly accurate and reliable, particularly when
compared to NDBs (Non- Directional Beacons)

DISTANCE MEASUREMENT EQUIPMENT

Distance measuring equipment (DME) is a radio navigation equipment that measures the
slant range (distance) between an aircraft and a ground station. It does this by timing the
propagation delay of radio signals between transmission and reception.
An airplane's DME interrogator uses frequencies from 1025 to 1150 MHz. DME
transponders transmit on a channel in the 962 to 1213 MHz range and receive on a
corresponding channel between 1025 and 1150 MHz. The band is divided into 126
channels for interrogation and 126 channels for reply. The interrogation and reply
frequencies always differ by 63 MHz. The spacing of all channels is 1 MHz with a signal
spectrum width of 100 kHz.

Principle of operation

An interrogator (airborne equipment) initiates an exchange by transmitting a pulse pair,
on an assigned 'channel', to the transponder ground station. The channel assignment
specifies the carrier frequency and the spacing between the pulses.
The transponder (ground station) replies by:
 Transmitting a pulse pair on a set frequency
 The frequency is offset from the interrogation frequency by 63 MHz
 The frequency has a specified separation of 150 interrogation pulse-pairs per
second.

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The communication has a time delay (typically 50 microseconds).
The DME receiver in the aircraft searches for reply pulse-pairs (X-mode = 12-
microsecond spacing) with the correct interval and reply pattern to its original interrogation
pattern.
The aircraft interrogator locks on to the DME ground station once it recognizes a particular
reply pulse sequence has the same spacing as the original interrogation sequence. Once
the receiver is locked on, it has a narrower window in which to look for the echoes and
can retain lock.
Note:
 DME facilities identify themselves with a 1,350 Hz Morse Code three letter
identity.
 DME collocated with a VOR or ILS, will have the same identity code as the parent
facility
 DME identity is 1,350 Hz to differentiate itself from
 The 1,020 Hz tone of the VOR or the ILS localizer.
Diagram of DME ground equipment

Airborne DME Equipment

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Note:

1. DME-equipped airplane uses the equipment to determine and display its distance
from a land-based transponder
2. The ground stations are typically collocated with VORs
3. A low-power DME can be collocated with an ILS or MLS where it provides an
accurate distance to touchdown, similar to that otherwise provided by ILS marker
beacons

A newer role for DMEs is DME/DME area navigation (RNAV). The accuracy of DME is
generally superior relative to VOR. Navigation using two DMEs (using
trilateration/distance) permits operations that navigating with VOR/DME (using
azimuth/distance) does not.

Advantages of DME

Advantage of DME include:

 Offers a reliable method for aircrafts to measure distance from ground stations.
 Relatively simple to implement
 Provides direct distance information.
INSTRUMENT LANDING SYSTEM (ILS)
The instrument landing system (ILS) is a precision radio navigation system that provides
short-range guidance to aircraft to allow them approach a runway at night or in bad
weather. In its original form, it allows an aircraft to approach until it is 200 feet (61 m) over
the ground, within a 1⁄2 mile (800 m) of the runway. At that point the runway should be
visible to the pilot; if it is not, they perform a missed approach.

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Aircrafts being able to be brought this close to the runway dramatically increases the
range of weather conditions in which a safe landing can be made. This condition has been
improved by other versions of the system, or "categories", reducing the minimum
distances further.
ILS uses two directional radio signals in its operation on ground namely:
 The localizer
 The Glide Slope
The two (2) transmitters are collocated with marker beacons or DME to provide distance
from touch down
ILS Localizer
A localizer (LOC, or LLZ) is an antenna array located beyond the departure end of the
runway. It generally consists of several pairs of directional antennas. They operate at 108
to 112 MHz radio frequency band. The purpose of the localizer in ILS operations is to
provide horizontal guidance.

Localizer operation

The localizer provides lateral guidance to the runway centerline. The localizer antenna is
normally placed centrally at the far end of the runway and consists of multiple antennas
in an array. The system relies on the variation of the modulation of two signals across the
entire width of the beam pattern.

The system relies on the use of sidebands, secondary frequencies that are created when
two different signals are mixed.

ILS starts by mixing two modulating signals to the carrier, one at 90 Hz and another at
150.This combined signal, known as the CSB for "carrier and sidebands", is sent out
evenly from an antenna array. The CSB is also sent into a circuit that suppresses the
original carrier, leaving only the four sideband signals. This signal, known as SBO for
"sidebands only", is also sent to the antenna array.

Each individual antenna has a particular phase shift and power level applied only to the
SBO signal such that the resulting signal is retarded 90 degrees on the left side of the
runway and advanced 90 degrees on the right. Additionally, the 150 Hz signal is inverted
on one side of the extract the original amplitude-modulated 90 and 150 Hz signals. These
are then averaged to produce two direct signal providing the centre line.

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Diagram of localizer array

Glide Slope

Instrument landing system glide slope (GS), is a system of vertical guidance embodied in
the instrument landing system which indicates the vertical deviation of the aircraft from its
optimum path of descent.

A glide slope antenna is sited on a tower which is offset approximately 250 to 650' to one
side of the runway centerline and approximately 750 to 1250' beyond the approach end
of the runway, adjacent to the runway touchdown zone. It transmits in the 328 to 336 MHZ
radio frequency band- Ultra High Frequency (UHF).

Operation of Glide Slope

The glideslope works in the same general fashion as the localizer and uses the same
encoding, but is normally transmitted to produce a centerline at an angle of 3 degrees
above horizontal. The signal is amplitude modulated with 90 and 150 Hz audio tones and
transmitted on a carrier signal. The centre of the glide slope signal is arranged to define
a glide path of approximately 3° above horizontal (ground level).

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The localizer (LOC) and glide slope (G/S) carrier frequencies are paired so that the
navigation radio automatically tunes the G/S frequency which corresponds to the selected
LOC frequency. The LOC signal is in the 110 MHz range while the G/S signal is in the
330 MHz range

Diagram of a Glide Slope Equipment

The ILS Airborne Receiver

The airborne system can detect and process the signals coming from the ground. The
signals provide a position fix which enables the aircraft to navigate to the runway threshold
and at the runway centre line.

The glide path scale is located to the right of the attitude sphere. On aircraft which have
a mechanical gyro compass are both the localizer and glide path indicated as a vertical
and a horizontal arrow in the compass as well. They are essentially read in the same way.

Diagram of the ILS Airborne System

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In the air, pilots attempt to man oeuvre the aircraft to keep the indicators centered while
they approach the runway to the decision height. Marker beacons can be placed on the
path to provide distance information as the approach proceeds. The beacons indicate
how far the aircraft is from runway threshold. The marker beacons include:
 Outer Marker (OM)- 7 Nautical miles with blue blinking light in the cockpit
 Middle Marker (MM)- 0.8 Nautical miles with amber blinking light in the cockpit
 Inner Marker (IM)- 200 feet with white blinking light in the cockpit
Marker beacons are being replaced by distance measuring equipment (DME).
Advantages of ILS in air navigation
The ILS can give both horizontal and vertical guidance to a runway. It can be made so
precise that pilots can use the system to land at an airport without even seeing the
runway.
ILS approach is considered a precision approach because it can provide both lateral and
vertical guidance.
MICROWAVE LANDING SYSTEM (MLS)
The microwave landing system (MLS) is an all-weather, precision radio guidance system.
The system was intended to be installed at large airports to assist aircraft in landing,
including 'blind landings'.
MLS enables an approaching aircraft to determine when it is aligned with the destination
runway and on the correct glide path for a safe landing. MLS was intended to replace or
supplement the instrument landing system (ILS).

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Principles of Operations
MLS employs 5 GHz transmitters at the landing place. The transmitters operate on the
passive electronically scanned arrays to send scanning beams towards approaching
aircraft. The aircraft that enters the scanned volume uses a special receiver that
calculates its position by measuring the arrival times of the beams.
A passive electronically scanned array (PESA), also known as passive phased array, is
an antenna in which the beam of radio waves can be electronically steered to point in
different directions (that is, a phased array antenna), in which all the antenna elements
are connected to a single transmitter and/or receiver.

MLS has a number of operational advantages over ILS, including:
 A wider selection of channels to avoid interference with nearby installations
 Excellent performance in all weather
 A small "footprint" at the airports- occupies less space in the airport
 A wide vertical and horizontal "capture" angles- allows approaches from wider
areas around the airport.
 The antennas did not have to be placed at a specific location at the airport, and
could "offset" their signals electronically.

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Some MLS systems became operational in the 1990s, the widespread deployment
envisioned by some aviation agencies never became a reality. There were two (2) main
reasons for difficulty in implementation, namely:

 Economic- while technically superior to ILS, MLS did not offer sufficiently greater
capabilities to justify adding MLS receivers to aircraft equipage;

 Potentially superior third system(GPS) -based systems, notably WAAS- allowed
the expectation of a similar level of positioning with following advantages:

 No equipment needed at the airport.

GPS/WAAS dramatically lowers an airport's cost of implementing precision landing
approaches, which is particularly important at small airports.

The radio navigation systems (Navigation aids (NAVAIDs)) are very important in air
navigation for operating through an airspace. The ground systems are generally being
replaced by satellite based systems namely Global Navigation Satellite Systems (GNSS).

SURVEILLANCE SYSTEMS IN AIR NAVIGATION

The concept of surveillance in air navigation is to have a sensor (or a network of sensors)
that detects aircraft, calculates their position, obtains other data (such as identification,
level, etc.) and then presents it to the controller on a situation display.

The main applications of surveillance in air navigation is in Area control and Approach
control. It is also used in the tower or in uncontrolled airspace where Advisory Service,
Flight Information Service or Alerting Service are provided.

The surveillance chain includes:
 Surveillance sensors (PSR, SSR)
 Data processing system
 Situation display system
The most common sensors used today are:
1. Radar Sensors
 Primary Surveillance Radar (PSR)
 Secondary Surveillance Radar (SSR)
 Mode ‘S’ Radars
2. Multilateration

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RADAR Sensors

Radar is an acronym for Radio Detecting And Ranging. It was initially developed and
introduced during the Second World War. It implies the use of radio signals to detect an
object and determine its distance (range) from the detector.

In air navigation, Radar refers to electronic equipment that detect the presence of objects
by using reflected electromagnetic energy. Electromagnetic energy (radio waves) travels
through a vacuum (air is approximated to be a vacuum) at a constant speed, at
approximately the speed of light, 300000 km/s. This constant speed allows the
determination of the distance between the reflecting objects and the radar site by
measuring the running time of the transmitted pulses.

Under certain conditions, a radar system can measure the direction, altitude, distance,
course, and speed of these objects.

The frequency of electromagnetic energy used for radar remains unaffected by darkness
and also enters fog and clouds. This allows radar systems to determine the position of
aircraft, ships, or other obstacles that are invisible to the naked eye due to distance,
darkness, or weather.

In air navigation, radars are classified into:

 Primary Surveillance Radars (PSR)
 Secondary Surveillance Radars (SSR)

 Conventional (CSSR)
 Monopulse (MSSR)

 Mode ‘S’ radars

Primary Surveillance Radars (PSR) in Air Navigation (PSR)

A primary surveillance radar is an equipment that emits radio wave pulses and detects
aircraft based on the echoes received. The system utilizes the reflection property of radio
waves. It works on the same principle as an echo.

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The system is defined as “A surveillance radar system which uses reflected radio signals
(ICAO Doc 4444 PANS-ATM)
Similarly, in its most basic form, the electromagnetic energy radiated by a radar system
strikes a reflective object (called a target) and is echoed back to a receiver.
The system uses radio waves in the L- Band (microwave range) above 1,000 MHz.

Components of a PSR
The major components of a primary radar system are:
 The transmitter
 The Antenna
 The Duplexer
 The receiver
 The signal processor
 The signal display

Transmitter

 Creates the radio waves to be sent out
 Modulates it to form the pulse train identical with the station carrier frequency
 Releases the pulses through a path called a waveguide to the antenna

Antenna

 Radiates the radar pulse from the transmitter into the air
 Collects (Receives) the reflected signal from the air back to the wave-guide.

Duplexer

 This is a switch that on the transmission/ reception path (attached to the
waveguide)
 Alternately connects the transmitter or receiver to the antenna.
 Its protects the receiver from the high power output of the transmitter.

Receiver

 Receives the reflected signal

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  Amplifies the signal (signal received is very weak)
 Demodulates the signal (removes the carrier signal)
 Provides video signals for processing/display

Signal Processor

 Converts the received data (signals) to information that can be understood by a
user (Air Traffic Controller)

Indicator

The primary function of the indicator is to provide an easily understandable visual display
of the ranges and bearings of radar targets from which echoes are received.The electrical
power for all the components is provided by a dedicated power supply which can also
provide enough power for the cooling system.

Diagram of a PSR Antenna

PSR Operation

The system operation is based on the echolocation principle. The radars are placed in a
slanting position and made to rotate 360 degrees at the speed of 5-12 rpm. They send
out electromagnetic signals (radio waves) as they rotate.

Upon reaching the aircraft or any other radio reflective object, the signal is reflected and
returned to the radar scanner for reception and processing.

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The system is able to calculate the distance of the reflecting object and also the bearing
from the station North alignment. Primary Radar calculates the position of aircraft using
the following measurements,
1. the distance is calculated based on wave transmitted and received time.
2. the angle is calculated based on the radar antenna direction
3. the radial velocity is calculated is based Doppler effect algorithm
Primary radars are said to be non- cooperative as they do not need an air borne
equipment to operate- they detect any radio reflective material in the coverage area and
display them in the ATC monitor.
The advantages of the primary radar include:

 No on-board equipment in the aircraft is necessary for detecting the target
 Can be used to monitor the movement of vehicles on the ground.

The disadvantages include:

 Lack of positive identification
 Lack of altitude identification
 High power requirement
 Reception from any radio reflective surface (clutter)
 Can be affected by blind speed operations
 Can be affected by ducting (anomalous propagation)

Secondary Surveillance Radar (SSR) in Air Navigation

Secondary surveillance radar (SSR) is a radar system used in air traffic control (ATC) that
relies on targets equipped with a radar transponder that reply its interrogation signals.
The system is composed of an interrogating equipment on ground and a responding
equipment (transponder) in the aircraft. Secondary radar was developed during the
Second World War to differentiate between friendly aircraft and ships hence the term
Identification Friend or Foe (IFF).
ICAO defines SSR as “A surveillance radar system which uses transmitters/receivers
(interrogators) and transponders” (ICAO Doc 4444 PANS-ATM)
The purpose of SSR is to improve the ability to detect and identify aircraft while
automatically providing the Flight level (pressure altitude) of an aircraft.

The components of an SSR system are:

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  SSR ground station (interrogator)/receiver
 SSR ground data processor
 SSR display
 SSR airborne receiver/transmitter (transponder)
 SSR airborne data processor
 SSR airborne data display

The SSR systems in Air Navigation are of two (2) types namely:

 Conventional SSR (CSSR)
 Mono-pulse SSR (MSSR)

The two differ in their operation method.

Operation of Conventional SSR (CSSR)

SSR ground station (interrogator) transmits interrogation pulses on 1030 MHz. The
transmission is continuous as the antenna rotates.

Diagram of SSR ground antenna

The pulses transmitted ask questions to be responded to by the airborne system based
on the question asked namely:

 Identity

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  Altitude
 Any special message

The interrogation pulses differ depending on the pulse width between pulses P1 and
P3The different interrogation types are called interrogation modes. A third pulse P2 is
found in the civil 3/A and mode C to cater for side lobe suppression (elimination of
unwanted interrogations).

SSR mode pulses

Note:

The ground antenna is highly directional but cannot be designed without side lobes.
Aircraft could also detect interrogations coming from these side lobes and reply
appropriately. The replies cannot be differentiated from the intended replies from the main
beam and can give rise to a false aircraft indication at an erroneous bearing. To overcome
this problem, the ground antenna is provided with a second, mainly omni-directional,
beam with a gain which exceeds that of the side lobes but not that of the main beam. A
third pulse, P2, is transmitted from this second beam 2 µs after P1. An aircraft detecting
P2 stronger than P1 (therefore in the side lobe and at the incorrect main lobe bearing),
does not reply.

CSSR interrogation modes

SSR Mode P1- P3 pulse spacing Application

1 3us Identity (military)

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 2 5us Identity (military)

3/A 8us Identity (military/civil)

B 17us Identity

C 21us Altitude

D 25us Undefined

S 3.5us Multipurpose

The aircraft equipment (transponder) will receive the interrogation pulses, process and
respond as appropriate. A mode-A interrogation (one used in air navigation for identity)
will elicits a 12-pulse reply, indicating an identity number associated with that aircraft.

The 12 data pulses are bracketed by two framing pulses, F1 and F2. The X pulse is not
used.

A mode -C interrogation produces an 11-pulse response (pulse D1 is not used), indicating
aircraft altitude as indicated by its altimeter in 100-foot increments.

Note:

 Mode B gave a similar response to mode A and was at one time used in Australia.
 Mode D has never been used operationally.

This reply is provided through a frequency of 1090 MHz providing aircraft information.
The reply is displayed as a tagged icon on the controller's radar screen at the measured
bearing and range.

An aircraft without an operating transponder still may be observed by primary radar, but
would be displayed to the controller without the benefit of SSR derived data. It is typically
a requirement to have a working transponder in order to fly in controlled air space and
many aircraft have a back-up transponder to ensure that condition is met.

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The ground interrogator can be mounted on the same site with a primary radar.

Diagram of an SSR Antenna collocated with a PSR Antenna

Typically, two Mode A interrogations are followed by a Mode C interrogation. The reason
for using Mode A more frequently is that the identity of the aircraft (the SSR code) is of
greater importance to the controller.

The level (altitude) received from the transponder is always in respect to standard
pressure (1013.25 hPa, 29.92" Hg) regardless of the altimeter setting selected by the
pilot. This is a mitigation against human error. As a result, when the controller observes
that two aircraft are separated by 1000 feet, it means that this separation exists regardless
of the altimeter settings of the two aircraft.
Advantages of SSR operation.
 Requires much less power to achieve the desired range, in comparison to PSR.
 The transmitted signal only needs to reach the aircraft, while the PSR needs
to emit a signal strong enough to reach the aircraft and travel back to the
antenna.
 The information provided is not limited to range and bearing from the antenna but
also includes additional data based on the transponder mode of operation (A, C or
S).

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  Targets are easier to distinguish due to the different SSR codes.
 SSR is immune to clutter as it uses different frequencies for interrogation (1030
MHz) and replies (1090 MHz).

Disadvantages of SSR operations
 The SSR relies on the onboard equipment to discover aircraft.
 In case of transponder failure, the SSR will receive no reply and will
therefore not discover the target.
 This is mitigated by combining the SSR with a PSR.
 If proper signal processing is used, it is possible to continue to track an
aircraft (and preserve correlation) even if the transponder has failed
completely provided that reliable primary data is received.
 Note that in this case level information will be less reliable and more
frequent pilot reports will be necessary.
 Sometimes two replies are received at the same time (if the slant range and the
bearings of the aircraft the same).
 This phenomenon is called "garbling" and may result either in:
o The "detection" of a false (non-existing) aircraft
o In a target not being detected
o This is considered a false target by the radar
 A phenomenon called FRUIT also occurs in SSR operations.
 FRUIT (False Replies Unsynchronized In Time or False Replies
Unsynchronized to Interrogator Transmissions).
 This happens when the radar receives a reply from a transponder that has
been interrogated by another radar.
 SSRs operate on the same frequencies, it is not possible to detect that the
reply is related to another radar's transmission. Moreover, as the time of the
interrogation is not known, the range calculation will most likely be wrong.
 A false target may appear on the situational display.
 If another (valid) transponder reply is received at the same time, garbling
could occur.
 SSRs are vulnerable to antenna shadowing

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  The onboard antenna is shadowed by the aircraft fuselage, e.g. due to the
bank angle).
 This is mitigated by placing more than one antenna (usually two - one on
top of the aircraft and one at the bottom).
Garbling and FRUIT are aggravated by the need of "classic" SSRs to use several
interrogations for proper azimuth determination and can be mitigated by:
o Using an MSSR (Mono pulse Secondary Surveillance Radar).

Mono Pulse Secondary Surveillance Radar (MSSR) System

Mono pulse secondary surveillance radar (MSSR) is an advanced radar that uses a
different beam pattern that provides more accurate azimuth determination. As a result,
fewer interrogations are required to determine the azimuth. It uses additional encoding of
the radio signal to provide accurate directional information. The name refers to its ability
to extract range direction from a single pulse. Monopulse systems have been classified
as:
 Phase comparison monopulse
 Amplitude monopulse

MSSR Principal of Operation

The system is intended to operate with just a single reply from an aircraft, a system known
as monopulse. It relies heavenly on the main or “sum” beam of the SSR antenna to get
the required information.To produce the sum beam the signal is distributed horizontally
across the antenna aperture.

 The antenna feed system is divided into two equal halves (sum and difference)
 The two parts summed again to produce the original sum beam.
 The two halves are also subtracted to produce a difference output.

A signal arriving exactly normal, or boresight, to the antenna will produce a maximum
output in the sum beam but a zero signal in the difference beam. A signal arriving away

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from the boresight will produce a less signal in the sum beam and non-zero signal in the
difference beam.

The angle of arrival of the signal can be determined by measuring the ratio of the signals
between the sum and difference beams. The ambiguity about boresight can be resolved
as there is a 180° phase change in the difference signal either side of boresight.

Bearing measurements can be made on a single pulse, hence monopulse, but accuracy
can be improved by averaging measurements made on several or all of the pulses
received in a reply from an aircraft.

Diagram of a Monopulse Beam

The system was developed to overcome two (2) common problems with conventional
systems namely:
 Garbling- when several aircrafts are in close proximity making the transponder
replies overlap
 FRUIT- Replies being received by interrogators who have not sent interrogation
pulses.
These problems are resolved by analysing the received signals using a computer and by
transmitting from the radar at a much reduced rate (about one tenth of the previously
used rate). As a result, Garbling and Fruit are reduced by about 90% while directional
accuracy is tripled compared to conventional SSR.
The improved accuracy of MSSR allows radar separation minima to be reduced by about
one half - to 3 nm if the aircraft is within 40 nm of the antenna and 5 nm if more than 40nm
from the radar antenna.

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Mode S Radars

Mode S is a Secondary Surveillance Radar process that allows selective interrogation of
aircraft according to the unique 24-bit address assigned to each aircraft. Recent
developments have enhanced the value of Mode S by introducing Mode S EHS
(Enhanced Surveillance).

Mode S operates on the principle that interrogations are directed to a specific aircraft
using that aircraft's unique address. This results in a single reply with aircraft range
determined by the time taken to receive the reply and monopulse providing an accurate
bearing measurement. In order to interrogate an aircraft its address must be known. To
meet this requirement, the ground interrogator also broadcasts All-Call interrogations,
which are in two forms

A mode S interrogation comprises two 0.8 µs wide pulses, which are interpreted by a
mode A & C transponder as coming from an antenna sidelobe and therefore a reply is not
required. The following long P6 pulse is phase modulated with the first phase reversal,
after 1.25 µs, synchronising the transponder's phase detector. Subsequent phase
reversals indicate a data bit of 1, with no phase reversal indicating a bit of value 0. This
form of modulation provides some resistance to corruption by a chance overlapping pulse
from another ground interrogator. The interrogation may be short with P6 = 16.125 µs,
mainly used to obtain a position update, or long, P6 = 30.25 µs, if an additional 56 data
bits are included. The final 24 bits contain both the parity and address of the aircraft.

On receiving an interrogation, an aircraft will decode the data and calculate the parity. If
the remainder is not the address of the aircraft, then either the interrogation was not
intended for it or it was corrupted. In either case it will not reply. If the ground station was
expecting a reply and did not receive one, then it will re-interrogate.

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The aircraft reply consists of a preamble of four pulses spaced so that they cannot be
erroneously formed from overlapping mode A or C replies. The remaining pulses contain
data using pulse position amplitude modulation.

 Each 1 µs interval is divided into two parts.
 When a 0.5 µs pulse occupies the first half and there is no pulse in the second half
then a binary 1 is indicated.
 When there no pulse in the first half and 0.5 µs pulse occupies the second half
then a binary 0 is indicated.
 The data is transmitted twice, the second time in inverted form.

This format is very resistant to error due to a garbling reply from another aircraft.

The reply also has parity and address in the final 24 bits. The ground station tracks the
aircraft and uses the predicted position to indicate the range and bearing of the aircraft
so it can interrogate again and get an update of its position.

If it is expecting a reply and if it receives one, then it checks the remainder from the parity
check against the address of the expected aircraft. If it is not the same then either it is the
wrong aircraft and a re-interrogation is necessary, or the reply has been corrupted by
interference by being garbled by another reply.

The parity system has the power to correct errors as long as they do not exceed 24 µs,
which embraces the duration of a mode A or C reply, the most expected source of
interference in the early days of Mode S.

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The pulses in the reply have:

 Individual monopulse angle measurements available,
 Signal strength measurements

This can indicate bits that are inconsistent with the majority of the other bits, thereby
indicating possible corruption. A test is made by inverting the state of some or all of these
bits (a 0 changed to a 1 or vice versa) and if the parity check now succeeds the changes
are made permanent and the reply accepted. If it fails then a re-interrogation is required

Mode S- All Call Operation

In one form, the Mode A/C/S All-Call looks like a conventional Mode A or C interrogation
at first and a transponder will start the reply process on receipt of pulse P3.

Mode S transponder will abort this procedure upon the detection of pulse P4, and instead
respond with a short Mode S reply containing its 24- bit address.

This form of All-Call interrogation is now not much used as it will continue to obtain replies
from aircraft already known and give rise to unnecessary interference.

The alternative form of All-Call uses short Mode S interrogation with a 16.125 µs data
block.

This can include an indication of the interrogator transmitting the All-Call with the request
that if the aircraft has already replied to this interrogator then do not reply again as aircraft
is already known and a reply unnecessary.

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The Mode S interrogation can take three forms as indicated below

Name Form Use

Surveillance Short Position update

Comm-A Long Contains 56 data bits

Up to 16 long interrogations strung together to transmit up to 1280
Comm-C Long
bits

The Mode S reply can take three forms as indicated below

Name Form Use

Surveillance Short Position update

Comm-B Long Contains 56 data bits

Up to 16 long interrogations strung together to transmit up to 1280
Comm-D Long
bits

Advantages of Mode S Operation

The following are the advantages of Mode S operation to air navigation in a state:

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  Improved situation awareness
 A clearer air situation picture, enhanced tracking and access to pertinent
information direct from the aircraft enables the controller to benefit from
quicker and more accurate recognition of airborne events.
 Progressive reduction of R/T workload per flight.
 There is scope for R/T usage between controller and individual flight under
service to be reduced following the progressive introduction of Mode S
Enhanced Surveillance.
 This applies in particular to the requirement for SSR code verification
procedures and also where system enhancements and/or the display of
downlink aircraft parameters obviate the need for certain voice
communication exchanges
 Safety enhancement.
 Access by controllers to aircraft intent DAPs, such as selected
altitude enables:
o Cross-checking of climb/descent instructions
o Helps the early identification of potential level bust incidents.
 Increased target capacity.
 Mode S radars are able to process many more aircraft tracks
(approximately double the number) than conventional MSSR installations.
 The 24 bits in each case is combined aircraft address and parity

Multilatration (MLAT) Surveillance Operations in Air Navigation
MLAT is a surveillance application that accurately establishes the position of
transmissions, matches any identity data (octal code, aircraft address or flight
identification) that is part of the transmission and sends it to the ATM system.
It is a proven technology that has been in use for many decades in both navigation and
surveillance applications. It is based on a methodology known as Time Difference of
Arrival (TDOA) which can be utilized in one of two ways:
 The signal from a mobile unit is measured at a number of known, fixed locations
 The signals from a number of fixed locations are measured by a mobile receiver
The TDOA of the signals at the receiver(s) allows the position of the mobile entity to be
determined.
An MLAT system consists of the following components:

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  A transmitting subsystem that includes interrogation message generation and
transmission function;
 A receiving antenna array subsystem that receives the transmissions from the
target and timestamps receipt at each antenna
 A central processor that calculates and outputs the MLAT

Note:
 Interrogation transmitter ensures regularity of responses from the target aircraft
 The target aircraft must have a subsystem that will respond to an interrogation
(transponder)
In response to an interrogation signal from one of the MLat sensors, the vehicle or aircraft
transponder will transmit a reply that will be received and processed by all of the MLat
sites. The variance of TDOA at the various ground sites will allow accurate determination
of th