TM355 Communications Technology Block 1 PDF

Summary

This document provides an introduction to communication technology. It details various aspects of communication channels, from optical fiber and copper cables, to radio waves. The document focuses on the underlying theory of signals and modulation, explaining analogue and digital signals and their applications.

Full Transcript

TM355:
COMMUNICATIONS TECHNOLOGY
BLOCK 1

PART 1:
CHANNELS FOR COMMUNICATIONS

1

Prepared by: Dr. Naser Zaeri
Arab Open University
 OUTLINE

Introduction
Analogue and digital signals
Optical fibre

Prepared by: Dr. Naser Zaeri 2
 1. INTRODUCTION (1/6)

The simplest type of communications system consists of a
transmitter that sends a signal along a channel to a
receiver.
This first part of Block 1 is mainly concerned with the
physical channel: the properties of optical fibre and
copper cable, and the behaviour of radio waves.
Each of these transmission media has its own merits and
limitations, and this text discusses the suitability of the
various types of media for different applications.
There may be many transmitters and/or receivers, and it
is necessary to ensure that the correct sender
communicates with the correct recipient.

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 1. INTRODUCTION (2/6)

One example is a local
area network (LAN) – a
computer network
covering a relatively
small area, such as a
company site.
Another example is the
ordinary telephone
system, referred to as
the public switched
telephone network
(PSTN).
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 1. INTRODUCTION (3/6)

Figure 1.1 distinguishes between the access network
(the local exchange and its connections to the
subscribers it serves) and the core network, which is
everything beyond the local exchange.
The technical demands of the access and core
networks are rather different.
The access network may serve millions of
subscribers, each on a different site, but with only
short distances involved.
In contrast, trunk lines in the core network carry
multiple calls between two places that may be
hundreds of miles apart.

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 1. INTRODUCTION (4/6)

Different techniques have evolved to meet these
demands.
At one time, the entire system was built with copper
cables, which carry information as electrical signals.
Later the technology of optical fibres was developed, in
which messages are sent using light rays that are
constrained to follow a path within the fibre.
Optical fibre has a number of advantages over copper,
particularly over long distances, so it now predominates
in the core network, although copper still retains a key
place in the access network.
Between them, optical fibre and copper cable serve
most of the needs of the PSTN and other fixed networks.

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 1. INTRODUCTION (5/6)

Mobile communications systems require radio.
This is a form of electromagnetic radiation like light,
and can propagate through air or space in various
ways.
While the term ‘radio transmitter’ brings to mind the
tall masts for radio and television broadcasting,
smaller transmitters are everywhere: in mobile
phones, computers (to provide a WiFi connection).
Cables confine signals to a defined route, but radio
waves spread out over a wide area.

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 1. INTRODUCTION (6/6)

Radio is thus a shared medium, so many different
transmissions are competing for attention
everywhere, and a receiver has to be able to select
the right one.
The shared nature of radio leads to problems of
resource allocation.
Radio also has security implications, as signals can
easily be intercepted.

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 2. ANALOGUE AND DIGITAL SIGNALS (1/2)

The term ‘signal’ describes the form in which a
message is sent along a communications channel.
In the case of copper cable, the signal is a varying
electrical voltage.
For both optical fibre and radio, the signal is a varying
electromagnetic wave.

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 2. ANALOGUE AND DIGITAL SIGNALS (2/2)

Figure 1.2(a) illustrates part of a
speech signal as produced by
the microphone in a
telephone.
The voltage signal follows the
air vibrations and is called an
analogue signal because the
voltage is analogous to the
fluctuating air pressure.
Figure 1.2(b) represents a data
signal as might be seen on a
cable to a computer on a LAN
(such a connection between a
home PC and a router.)

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 2.1 BENEFITS OF TRANSMITTING
DIGITAL SIGNALS (1/2)
Whenever a signal is sent along a communications channel,
two things happen to it: it gets smaller (it attenuates) and it
gets distorted (the shape changes).
This is illustrated in Figure 1.3 for both an analogue signal and a
digital signal.
It is possible to compensate for attenuation by amplifying the
received signal.
With digital signals, on the other hand, we can in principle get
rid of the distortion entirely by the process of regeneration,
provided the distortion is not too great (threshold detection).
Another reason for using digital technologies in
communications is that voice, music and video can all be
handled by the same techniques as computer data if they are
first converted to a digital form.

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2.1 BENEFITS OF TRANSMITTING
DIGITAL SIGNALS (2/2)

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 2.2 CONVERTING ANALOGUE TO
DIGITAL (1/3)
Analogue-to-digital converters (ADCs) and digital-
to-analogue converters (DACs) are electronic
devices that convert between analogue and
digital in each direction.
To convert an analogue signal to digital form, it is first
sampled by measuring its value at regular intervals in
time.

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 2.2 CONVERTING ANALOGUE TO
DIGITAL (2/3)

The next step is to encode each of the
possible quantisation levels with a binary
number.
To restrict the measured values to a discrete set,
the values are quantised.
Since a binary number n bits long can take any of
2𝑛 different values, the number of quantisation
levels allowed is normally a power of two.
Thus a 4-bit number can represent 24 = 16 different levels,
and an 8-bit number can represent 28 = 256 different levels.

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 2.2 CONVERTING ANALOGUE TO
DIGITAL (3/3)
For a given range of variation, a large value of n
improves the accuracy of the conversion because
the quantisation levels are closer together;
conversely, a small n results in a smaller amount of
binary data at the expense of conversion
accuracy.
In converting an analogue signal to digital, it
appears that information has been lost in two
different ways:
a) The signal is not measured at every instant of time but only
at the sampling points.
b) An approximation has been made by rounding the
samples to the nearest quantisation level.
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 2.3 ANALYSING SIGNALS
2.3.1 SINUSOIDS (1/2)
Sinusoids are important not only because they turn up
naturally in a wide variety of situations, but also for their
mathematical simplicity.
A sinusoid is a periodic signal  repeats at regular time
intervals.
A section of a periodic signal between two consecutive
corresponding points, such as the maxima, is called a
cycle, and the duration of a cycle is the period.
The number of cycles in one second is the frequency.
The unit of frequency is the hertz (Hz), where 1 Hz = 1
cycle per second.
f=1/T
Amplitude is the maximum value of the sinusoid.

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 2.3.1 SINUSOIDS (2/2)

Another characteristic of a sinusoidal signal is its phase.
This relates to the point that the sinusoid has reached at
a particular time.
For example, at zero time the signal is zero and rising.
Shifting the signal to the right or left changes its phase.
One of the reasons that sinusoids are so significant in
communications is that they form the components of
other periodic signals.

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2.3.2 OTHER PERIODIC SIGNALS (1/4)
An important result in communications theory, due
to Joseph Fourier (1768–1830), shows that any
periodic signal may be expressed as a sum of
multiple sinusoids.
The graph on the left of Figure 1.7(a) shows a
sinusoid as it progresses in time, while the graph on
the right shows another representation of the signal:
a function of frequency.
 These are known respectively as time-domain and
frequency-domain representations.
The frequency domain is also known as the spectrum.

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2.3.2 OTHER PERIODIC SIGNALS (2/4)

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2.3.2 OTHER PERIODIC SIGNALS (3/4)

Any signal can be represented in either the time or the
frequency domain.
A sinusoid, is shown as a single line in the frequency domain
because it represents a single frequency of a particular
strength.
Figure 1.7(b) shows a periodic signal with a different shape (or
waveform as it is sometimes called), known as a saw-tooth
wave from its appearance.
The corresponding frequency-domain representation reveals
that it is made up of the sum of sinusoids of decreasing
amplitude.
 Notice that the frequencies of these sinusoids are exact
whole-number multiples of the lowest frequency. These
higher-frequency sinusoids are called harmonics.
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2.3.2 OTHER PERIODIC SIGNALS (4/4)
The waveform in Figure 1.7(c), known as a square wave,
may be regarded as a binary signal with alternate 1s
and 0s.
In the frequency domain there are again sinusoids at
multiples of the lowest frequency, though in this case the
even multiples (or harmonics) are missing.
A consequence of this theory is that a communications
channel that can transmit, say, a 1 MHz sine wave correctly
may not be able to transmit a 1 MHz periodic signal with a
different waveform, unless it can also transmit sinusoids at 2
MHz, 3 MHz and so on.
A complete frequency-domain representation would
also include phase.
For many purposes, though, phase is less important than
frequency; it is not a consideration in allocating radio
spectrum, for example.
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2.3.3 NON-PERIODIC SIGNALS (1/2)

Non-periodic signals (also known as aperiodic
signals) also have both a time-domain and a
frequency-domain representation, but the details
are different.
 There are no longer lines at particular frequencies;
instead, the spectrum is spread out over a continuous
range of frequencies.

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2.3.3 NON-PERIODIC SIGNALS (2/2)

For example, a speech signal ranges from
around 100 Hz to a few thousand Hz (for
telephone-quality speech, a range of 300 Hz
to 3400 Hz is often assumed).
In practical communications, exactly
periodic signals are the exception.
Signals that carry real information, such as
speech, music or video, do not repeat
endlessly.

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 3. OPTICAL FIBRE (1/2)

Optical fibre can transmit large amounts of information
rapidly over long distances using light signals, and so
has become the preferred technology for trunk cable
communications and increasingly for LANs.
A basic optical-fibre link has three main components
(Figure 1.10):
a suitable source of light (not necessarily within the visible
range), controlled by input data in the form of an electrical
signal
the optical fibre itself, which carries the resulting pulses of
light to …
a detector, which converts the pattern of light and dark
back to an electrical signal.
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3. OPTICAL FIBRE (2/2)

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 3.1 ELECTROMAGNETIC RADIATION (1/6)

Electromagnetic radiation includes radio waves,
light, the radiation felt as heat, and ultraviolet
radiation from the Sun.
Light, as an electromagnetic wave, is a wave
pattern carried by interdependent electric and
magnetic fields.
In electromagnetic wave, electricity and
magnetism are in fact intimately related.
Electric fields, like magnetic fields, are invisible but
can exert forces on objects.
Strong electric fields form in thunderclouds and
break down when lightning strikes.

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 3.1 ELECTROMAGNETIC RADIATION (2/6)

Electric fields and magnetic fields can both store
and release energy.
They are also linked together by a set of
relationships known as Maxwell’s equations.
Changing electric fields generate changing
magnetic fields, and vice versa.
The effect of all of this is that disturbances in the
fields can be self-sustaining, and spread outwards
like waves in a pond.

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 3.1 ELECTROMAGNETIC RADIATION (3/6)

Figure 1.13 represents a
an electromagnetic
wave in terms of its
electric and magnetic
components.
The axis along the
direction of travel
measures distance
along the wave.
The other axes
represent the strength
of the electric and
magnetic fields at any
point along the wave.
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 3.1 ELECTROMAGNETIC RADIATION (4/6)

The electric field and magnetic field are both
sinusoidal and are at right angles to each other.
This is just a snapshot of the wave at one particular instant in
time.
The whole wave pattern moves forward at the
speed of light, which in free space (a vacuum) is
about 300 000 000 m/s = 3×108 m/s and is
conventionally denoted c.
All electromagnetic waves travel at this same
speed in free space.

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 3.1 ELECTROMAGNETIC RADIATION (5/6)

In free space, the electric field contains half the
power in an electromagnetic wave and the
magnetic field contains the other half.
As the wave moves forward, it conveys energy.
So, for example, light from the Sun can be
converted to electrical energy by solar panels.
The power generated by such a panel is simply the
energy it produces per unit time.

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 3.1 ELECTROMAGNETIC RADIATION (6/6)

Note on Energy and Power:
Power is the rate of flow of energy, and is measured in watts
(W).
Energy and power are related as follows:
energy = power × time.
Example: Suppose a 2 kW kettle takes three minutes to boil.
Three minutes is 0.05 hours, so the energy used is: 2000 W ×
0.05 h = 100 Wh or 0.1 kWh (kilowatt-hours).
However, although energy is quoted as kWh on electricity
bills, the SI unit of energy is the joule (J), where energy in
joules is the power in watts multiplied by the time in
seconds.
Repeating the kettle example using SI units gives: 2000 W × 180 s
= 360 000 J or 360 kJ.

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3.1.1 WAVELENGTH AND FREQUENCY

Electromagnetic waves are characterised by their
wavelength, the distance between two
consecutive peaks (or other corresponding points.)
Light waves have short wavelengths, measured in
nanometres (nm, 10−9 m).
Light of different wavelengths is perceived as different
colours, for example 650 nm is red and 520 nm is green.
A wave can also be described by its frequency,
where:
𝒄=𝝀×𝒇

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 3.1.2 THE ELECTROMAGNETIC
SPECTRUM
Figure 1.14 shows the complete electromagnetic
spectrum.

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 3.2 LIGHT WAVES IN OPTICAL FIBRE (1/3)

In optical fibres, light travels through highly
transparent glass along guided paths, so there are
some differences from propagation in free space.
For one thing, light travels significantly more slowly in
glass than in a vacuum (or in air).
The speed of light, 𝒗, in a medium such as glass is
found by:
𝒗 = 𝒄/𝒏
where “𝒏” is the refractive index and depends on
the material. It is around 1.5 for most optical glasses.

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 3.2 LIGHT WAVES IN OPTICAL FIBRE (2/3)

So what keeps light guided along its path in an optical
fibre?
Why does the light not just stop when it comes to the first
bend?
Optical fibres work because the refractive index is not the same
all the way across the fibre, but is higher in the central core than it
is in the cladding around the core.
Light can change direction by two processes, refraction and
reflection, which take place in lenses and mirrors respectively.
Refraction can occur when a ray of light travels from one
medium to another medium with a different refractive index.
The light continues within the second medium, but on a diverted
path (Figure 1.15a).

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 3.2 LIGHT WAVES IN OPTICAL FIBRE (3/3)

However, if light is directed from one medium towards another
with a lower refractive index, and it hits the boundary at a
sufficiently small angle, it is not refracted but reflected back into
the first medium.
This process is known as total internal reflection (Figure 1.15b).
Thus in an optical fibre, provided the light enters the fibre from
the right direction (not too large an angle from the axis of the
fibre), it will continue all the way along the fibre, relying on total
internal reflection to keep it on course.

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 3.3 TYPES OF FIBRE (1/4)

The diameter of the core is a key feature of an optical
fibre.
the larger the diameter of the fibre, the more light it will let
through.
A large-diameter fibre also has some practical
advantages: aligning fibres to join them together
becomes easier.
However, when it comes to transmitting data over
distances at high data rates, it turns out that a large
diameter is not necessarily the best.
A fibre with a core diameter that is large in comparison
with the wavelength is known as a multimode fibre
because light can travel along it in a variety of ways.
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 3.3 TYPES OF FIBRE (2/4)

Commonly, the diameter of the core for a multimode
fibre is 50 μm, much larger than the wavelengths
typically used (which are in the order of 1.5 μm).
The cladding diameter is 125 μm.
From Fig. 1.16, some paths that the light can take are more
direct than others, meaning two rays of light that set off at the
same time may not reach the other end of the fibre exactly
simultaneously.
A fibre (as the one shown in Fig. 1.16) where the refractive
index changes abruptly between core and cladding is called
a step-index fibre.

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 3.3 TYPES OF FIBRE (3/4)

Another variant of the multimode fibre is called a
graded-index fibre (Fig. 1.17)  the refractive index
varies smoothly from a maximum in the centre of the
core to a minimum within the cladding.
This means waves that take slightly longer paths travel
slightly faster, and so different waves setting off at the
same time arrive nearly simultaneously at the other end
of the fibre.

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 3.3 TYPES OF FIBRE (4/4)

If the core diameter of a step-index fibre is reduced,
there are fewer ways or modes in which the wave can
propagate.
There comes a point where only one mode can
propagate, and signals all travel along the same path.
This happens when the core is a few wavelengths in
diameter – typically 10 μm.
This type of fibre is called a single-mode fibre, and it
provides the best performance over long distances in a
number of respects.
For this reason, single-mode fibre is preferred over
multimode types for long-haul communications.
The cladding diameter is typically 125 μm, the same as
for multimode fibre.
Prepared by: Dr. Naser Zaeri 40
 TM355:
COMMUNICATIONS TECHNOLOGY
BLOCK 1

PART 1 (CONT.):
CHANNELS FOR COMMUNICATIONS

1

Prepared By: Dr. Naser Zaeri
Arab Open University
 OUTLINE

3.4: limitations of optical fibre
3.5: Components of an optical-fibre link
4. Copper cable
5. radio
6. Analogue modulation

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 3.4 LIMITATIONS OF OPTICAL FIBRE
3.4.1 ATTENUATION AND DECIBELS (1/4)
Modern optical fibres are extremely transparent and so
can carry optical signals long distances.
However, some of the energy supplied by the source is
eventually absorbed by the fibre as the signal passes
along it.
The process by which the signal gradually loses power as it
travels along a transmission medium is called attenuation.
Manufacturers of optical fibres specify how much a fibre
attenuates in terms of so much attenuation in decibels
(dB) per kilometre length.
The decibel is a logarithmic measure of the ratio between
two powers.

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 3.4.1 ATTENUATION AND DECIBELS (2/4)

More specifically, Power loss (or gain) in decibels (dB) is given by:
𝑃2
𝑃 = 10𝑙𝑜𝑔10
𝑃1
Where 𝑃1 is the transmitted power and 𝑃2 is the received power.
Note:
The two powers to be compared may represent a loss, as in fibre
attenuation, or a gain, as when a signal is amplified.
0 dB, meaning ‘no loss’.
increasing a power by 3 dB doubles the power
attenuating a power by 3 dB halves the power.

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 3.4.1 ATTENUATION AND DECIBELS (3/4)

Example: Suppose a fibre-optic link consists of three
sections. Half the power is lost in the first section,
another half of the remaining power is lost in the
second section, and 95% of the remaining power is
lost in the third section. Find the total power loss in dB
at the end of the third section.
Sol.: The total fraction remaining is:
0.5 × 0.5 × 0.05 = 0.0125
𝑃2 0.0125𝑃1
 In dB: 𝑃 = 10𝑙𝑜𝑔10 = 10𝑙𝑜𝑔10 = -19 dB.
𝑃1 𝑃1

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 3.4.1 ATTENUATION AND DECIBELS (4/4)

Although multimode fibre has a higher figure for attenuation, it
is generally preferred for short-distance applications because
of lower component costs and greater ease of use than single-
mode fibre.

6
 3.4.2 PULSE SPREADING (1/3)

As well as attenuation, various effects distort signals
in optical fibres by smearing out sharp transitions
between light and dark sections of the signal.
This limits the data rate that can be obtained over a
length of fibre, because parts of the signal start to
merge into each other.
As with attenuation, the effects are cumulative 
the longer the fibre, the worse it gets.
Figure 1.21 illustrates the problem:
The signal transmitted is called a pulse, so the effect is
known as pulse spreading.

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 3.4.2 PULSE SPREADING (2/3)

One reason for
pulse spreading in
multimode fibres:
different path
lengths result in
different timings
for the trip
through the fibre
 This is called
multimode
distortion (Fig.
1.22) and is the
main cause of
pulse spreading in
multimode fibres.
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 3.4.2 PULSE SPREADING (3/3)

Although this effect is eliminated in single-mode
fibres, other mechanisms can still cause pulse
spreading:
Dispersion, or ‘chromatic dispersion’, is caused by
light of different wavelengths travelling at
different speeds.
Polarisation mode distortion affects single-mode
fibres and is caused by another variation in the
speed of light: the speed varies with the
orientation of the light wave in the fibre.

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 3.5 COMPONENTS OF AN OPTICAL-FIBRE LINK
3.5.1 OPTICAL TRANSMITTERS AND DETECTORS (1/3)

Optical transmitter: converts input data in the form
of an electrical signal into a light signal that is sent
along the fibre.
There are two main types, both semiconductor
devices: the light-emitting diode (LED) and the laser
diode
LEDs for optical transmitters are similar in principle to the
LEDs seen in displays and as indication lights in consumer
goods. However, rather than emitting visible light, they emit
in the infrared region of the spectrum, where optical fibres
are most transparent.
Laser diodes are also found in CD, DVD and Blu-ray drives,
where they read and write data from the disc.

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 3.5.1 OPTICAL TRANSMITTERS AND
DETECTORS (2/3)
LEDs are inexpensive compared to laser diodes and so are
used in some multimode fibre systems.
However, they have a number of disadvantages: they are
lower in power and emit over a range of wavelengths,
leading to dispersion.
LEDs emit a relatively broad cone of radiation, whereas a laser
diode emits a strongly aligned beam.
Laser diode is much more efficient at transferring its energy to
the fibre.
The data rate that can be obtained from the transmitter
depends on how fast the beam can be modulated. Again,
the laser diode has an advantage over the LED in the speed
at which it can switch.

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 3.5.1 OPTICAL TRANSMITTERS AND
DETECTORS (3/3)

At the other end of the fibre, a detector
converts the light signal back into an
electrical signal.
The type of detector commonly used is
called a photodiode.
It provides a current output that varies with
the intensity of the light it receives.

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 3.5.2 OPTICAL AMPLIFIERS (1/3)

Optical fibres attenuate markedly over long distances.
For example, the best-case attenuation in Table 1.1 is 0.35 dB
km−1, which over a 300 km link would amount to 105 dB, a
huge drop in power.
One way of increasing the range of an optical-fibre link
is to use a repeater or regenerator.
These are devices that counteract the effects of
attenuation by restoring an optical signal to its original
form.
The optical signal is converted back to an electrical
signal, which is then processed electronically and
retransmitted optically.

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 3.5.2 OPTICAL AMPLIFIERS (2/3)

Repeaters and regenerators are distinguished by
the extent of the processing that is carried out, the
term ‘repeater’ tending to include simpler devices
than ‘regenerator’.
A repeater amplifies the signal to bring it back to its
original amplitude, but at the same time it may also
amplify any noise that is mixed with the signal.
A regenerator does further processing, so that the
degraded received pulse would be reshaped and
retimed as well as being restored to its original
amplitude.
Thus the regenerated pulse is a copy of the original
transmitted pulse with any noise removed, provided the
signal has not deteriorated too far.
14
 3.5.2 OPTICAL AMPLIFIERS (3/3)
In principle, any distance can be covered using a chain of
regenerators, but there are some practical disadvantages: these
devices have to be powered and maintained, and many of
them may be needed to cover long distances.
This is a particular problem for international cables, which often
run under the ocean, making power provision and maintenance
very difficult.
Optical amplifiers have been developed as a better solution for
long-haul links.
They amplify the optical signal directly, without converting it back
to an electrical signal.
The idea: allows energy to be ‘pumped’ into the atoms of a material
and then released later when ‘stimulated’ by radiation, thus creating
more radiation of the same wavelength.

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 4. COPPER CABLE

The sender and receiver in most
communications systems operate with
electrical signals
Copper cable is a simple solution because it
does not involve any conversions to other
types of energy (light or radio waves).

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 4.1 TRANSMISSION IN CABLES (1/2)
Figure 1.26 shows a general type of circuit in which a power
source sends power to a load.
The source and load might be a battery and bulb in a torch,
or the house mains supply and a toaster, or (in the case of
communications) a transmitter and receiver.
Voltage is the force that sends the current around the circuit.
It is measured in volts (V).
Batteries may be 1.5 V, 9 V and so on, and in the UK electricity is
supplied to houses at a nominal 230 V.
Current represents the movement of electrons and is
measured in amperes or amps (A).

17
4.1 TRANSMISSION IN CABLES (2/2)

Communications signals with high frequencies or
data rates involve effects in cables that are not
apparent in other circuits, such as house wiring.
At the high frequencies and data rates used in
communications, the speed of a signal in a copper
cable depends on the construction of the cable.
A typical figure is 2 ×108 m/s, which is comparable
to the speed of signals in optical fibres.

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4.1.1 MAGNETIC AND ELECTRIC FIELDS (1/2)

A conductor carrying current has both magnetic
and electric fields associated with it.
A magnetic field encircles a conductor carrying an
electric current.
The field may be strong enough to exert appreciable
forces on ferrous objects, particularly when the field is
concentrated as it is in an electric motor.
Conductors also have associated electric fields.
In high-voltage lines, the electric field ionises the
intervening atmosphere and creates a spark.

Prepared By: Dr. Naser Zaeri 19
4.1.1 MAGNETIC AND ELECTRIC FIELDS (2/2)

The low voltages and currents used in computer
networks and phones generate tiny fields in
comparison to these examples.
Signal propagation in cables can in fact be
regarded as another type of electromagnetic
wave.
Because of the wave nature of signals in cables,
effects such as reflection are possible, whereby
some of the signal moves back along the cable.

Prepared By: Dr. Naser Zaeri 20
4.1.2 CROSSTALK AND RADIATION

Commonly, copper cables carrying different signals run
alongside each other for convenience – they may, for
example, share a conduit along a street.
Many cables have multiple pairs of conductors rather
than just one, so that several independent signals can
be carried.
There is a potential problem, though, in that the electric
and/or magnetic fields associated with one pair of
conductors may couple with the conductors next to
them to some extent, so that a weak version of the signal
is transferred to the other conductor pair.
This is called crosstalk and can be minimised by
appropriate design of the cable.
Prepared By: Dr. Naser Zaeri 21
4.2 ATTENUATION AND DISTORTION IN
CABLES (1/2)
All ordinary conductors have a property called
resistance: electrons do not flow along conductors
entirely freely, but are subject to frequent collisions.
This results in loss of electrical energy, which is
converted to heat.
Resistance is particularly important in power
distribution, where it must be kept as low as possible
to avoid wasting energy, but it also affects
communications systems that use copper cables.
The two conductors in a pair are kept apart by a
non-conducting material, usually plastic, known as
an insulator or dielectric.
Prepared By: Dr. Naser Zaeri 22
4.2 ATTENUATION AND DISTORTION IN
CABLES (2/2)
Resistance and leakage both increase in proportion to
the length of the cable, so they need to be taken into
account particularly over long-distance links.
At high frequencies or high data rates, the material
separating the conductors can have an effect in
increasing the attenuation over and above that
observed at low frequencies.
This is because a small part of the energy in the
electromagnetic fields is wasted as heat in a process
known as dielectric loss.
Distortion can also occur in cables when signals of
different frequencies travel at different speeds (just as in
optical fibre.)
Prepared By: Dr. Naser Zaeri 23
 4.3 TYPES OF CABLE (1/2)

Figure 1.28 illustrates two of the many types of cable that are
used for transmitting digital data and other high-frequency
signals: unshielded twisted pair (UTP) and coaxial cable.
In a UTP cable, a pair of conductors is twisted together along
its length.
The effect of the twisting is that any interference entering the
cable will affect both conductors equally, and can be
cancelled out by using a receiver that is sensitive only to the
difference in voltage between the two conductors.

Prepared By: Dr. Naser Zaeri 24
 4.3 TYPES OF CABLE (2/2)

So the twisting gives some protection against
crosstalk.
In coaxial cable, the two conductors take the form
of a centre conductor with a conducting shield
around it.
An advantage of this construction is that the
electric and magnetic fields are confined within the
shield.
This gives the cable good immunity to interference
and minimises losses due to radiation.
A common use of coaxial cable is for connection to TV
antennas.

Prepared By: Dr. Naser Zaeri 25
 5. RADIO

Radio waves are another form of electromagnetic
radiation but at a much lower frequency than light or
infrared, 300 GHz often being regarded as the upper
limit.
Their electric and magnetic fields are generated directly
from electrical signals in structures known as antennas, or
sometimes aerials.
A receiving antenna converts a radio signal back to an
electrical signal.
An antenna simply consists of one or more conductors,
and is effective at launching (or receiving) a radio wave
at a particular frequency or band of frequencies by
virtue of its physical shape and dimensions.
An antenna that is effective at transmitting at a given
frequency is also effective at receiving at the same
frequency.
Prepared By: Dr. Naser Zaeri 26
5.1 BANDWIDTH AND RECEPTION (1/3)

The amount of spectrum occupied by a signal is
called the bandwidth.
The bandwidth is equal to the difference between
the highest and lowest frequencies, 𝒇𝟐 − 𝒇𝟏.
The larger the bandwidth, the more information the
signal can convey.
The centre frequency of this transmission, halfway
between 𝒇𝟏 and 𝒇𝟐.
In many modulation schemes, the centre frequency
is the same as the frequency of the unmodulated
signal.
Prepared By: Dr. Naser Zaeri 27
5.1 BANDWIDTH AND RECEPTION (2/3)

Prepared By: Dr. Naser Zaeri 28
5.1 BANDWIDTH AND RECEPTION (3/3)

Figure 1.30 shows what the response of an ideal
receiver would look like, with the response of a
typical practical receiver by way of comparison.
The range of frequencies that the receiver responds
best to is called the passband:
Extends from a lower cut-off frequency to a higher cut-off
frequency.
The cut-off frequencies are the points where the
signal strength in volts has fallen to 0.707 of the
maximum (a voltage drop of this magnitude
corresponds to a drop in power of 3 dB).

Prepared By: Dr. Naser Zaeri 29
5.2 SOME PROPERTIES OF RADIO WAVES
5.2.1 THE INVERSE SQUARE LAW
The inverse square law describes the reduction in power with
distance from the transmitter, due to spreading.
Figure 1.31 represents a wave moving outwards from a
transmitter, which is assumed here to radiate equally well in all
directions – isotropically.
A receiver that is n times as far from the transmitter will receive
𝟏
of the power.
𝒏𝟐

30
 5.2.2 REFLECTION (1/2)

Radio waves can be both reflected by specular reflection
(from smooth, flat surfaces) and scattered.
Radio waves are reflected by many surfaces, including the
ground, buildings and vehicles.
They are particularly well reflected by metal surfaces, for
example in satellite dishes.

Prepared By: Dr. Naser Zaeri 31
 5.2.2 REFLECTION (2/2)

Scattering occurs when reflecting objects or
features are small compared to the wavelength.
Radio waves can be scattered by a variety of
objects, ranging from small dust particles to meteors
high in the atmosphere.
Scattering by intervening objects or particles can
result in a loss of useful energy between the
transmitter and receiver, reducing the received
signal.

Prepared By: Dr. Naser Zaeri 32
 5.2.4 ABSORPTION

Radio waves can be absorbed by the medium they
travel through.
The attenuation due to absorption is measured in
decibels per metre or kilometre.
The loss due to absorption is separate from, and
additional to, any power loss due to spreading as
accounted for by the inverse square law.
Absorption is dependent on frequency, and this is
one of the reasons why certain frequency bands
are preferred for different radio applications.

Prepared By: Dr. Naser Zaeri 33
 5.2.5 DIFFRACTION

Diffraction: is the
spreading or bending of
an electromagnetic
wave when it passes
through a gap or
encounters a sharp
corner.
Diffraction is very
dependent on the
dimensions of a gap or
the sharpness of an
edge.
Prepared By: Dr. Naser Zaeri 34
 5.4 PROPAGATION
5.4.4 PROPAGATION MODELS
Propagation: at low frequencies, long-distance
transmission depends on the state of the
ionosphere, while multipath propagation causes
fading at high frequencies.
Propagation in terrestrial environments is complex,
and so computer models have been developed to
help with prediction.
The inverse fourth-power law is often invoked as a
first approximation for propagation at VHF and
above in typical terrestrial environments.
With the inverse fourth-power law the received
power decreases in proportion to 1 𝑑4.

Prepared By: Dr. Naser Zaeri 35
 6. ANALOGUE MODULATION
In communications, the types of signal that can be transmitted
over a channel are often very different from the original
message signal.
Radio waves at the frequencies found in sound are not easy to
transmit and receive, and do not propagate well.
A transmitter that converts a sound signal directly to a radio
wave, while possible, is of limited use anyway; if there was more
than one of them, they would effectively talk over each other.
The idea of using different frequencies from the original message is not
confined to radio, but also applies to other media such as cable, in
the process known as modulation, the message signal is converted to
a suitable form for transmission
Modulation is usually a matter of varying one or more properties of the
sine wave in a way that represents the information to be conveyed.

Prepared By: Dr. Naser Zaeri 36
6.1 AMPLITUDE MODULATION (1/4)

In amplitude modulation (AM) the amplitude of the
carrier waveform is altered in proportion to the
information signal, referred to as the modulating
signal.
The term envelope is used to describe the varying
strength, or shape, of the modulating signal
After modulation, the carrier’s amplitude takes on the
envelope of the modulating signal.
The modulated signal is created by multiplying the
modulating signal and the carrier signal together.
Done using a device known as a mixer.
A mixer is used to shift power at one frequency to power at
another frequency.

Prepared By: Dr. Naser Zaeri 37
6.1 AMPLITUDE MODULATION (2/4)
The carrier waveform is usually generated using a local oscillator,
which is an electronic circuit that produces a periodic electronic
signal – in this case a sine wave with frequency 𝑓𝑐.
Advantage of AM is its simplicity.
Disadvantage of AM signal is highly susceptible to noise.

38
6.1 AMPLITUDE MODULATION (3/4)

Mathematically: if the carrier waveform is
represented by 𝑣𝑐 𝑡 = 𝑣𝑐 cos(𝜔𝑐 𝑡), and the
information or modulating signal is also represented
by a sinusoid, 𝑣𝑚 𝑡 = 𝑣𝑚 cos(𝜔𝑚 𝑡), then

𝑣𝐴𝑀 𝑡 = 𝑣𝑚 cos(𝜔𝑚 𝑡) x 𝑣𝑐 cos(𝜔𝑐 𝑡)
𝑣𝑚 𝑣𝑐
= cos 𝜔𝑐 + 𝜔𝑚 𝑡 + cos 𝜔𝑐 − 𝜔𝑚 𝑡
2

 The modulated signal comprises two components,
known as the upper sideband, at (𝜔𝑐 + 𝜔𝑚 ), and the
lower sideband, at (𝜔𝑐 - 𝜔𝑚 ).
Prepared By: Dr. Naser Zaeri 39
6.1 AMPLITUDE MODULATION (4/4)

Bandwidth of the modulated signal, 𝐵𝐴𝑀 , is twice
that of the original information signal, 𝐵𝑚
 𝐵𝐴𝑀 = 2𝐵𝑚.

Prepared By: Dr. Naser Zaeri 40
6.2 FREQUENCY MODULATION (1/3)

In frequency modulation (FM) the frequency of
the carrier waveform is altered in proportion to
the envelope of the modulating signal, so the
amplitude and the phase remain the same.
The modulated signal is usually created using a
voltage-controlled oscillator (VCO).
This is an electronic circuit that takes a voltage signal
as an input and produces a periodic electronic signal
– in this case a sine wave – as an output.

Prepared By: Dr. Naser Zaeri 41
6.2 FREQUENCY MODULATION (2/3)

Prepared By: Dr. Naser Zaeri 42
6.2 FREQUENCY MODULATION (3/3)

The frequency deviation, Δf: defined as the
maximum deviation of the FM-modulated
frequency from the carrier frequency.
The modulation index, β: ratio of the frequency
deviation to the highest frequency component in
the modulating signal (modulating frequency), 𝑓𝑚 :
∆𝑓
𝛽=
𝑓𝑚
Bandwidth of frequency modulated signal is:
𝐵𝐹𝑀 = 2 ∆𝑓 + 𝑓𝑚 = 2(1 + 𝛽)𝑓𝑚

Prepared By: Dr. Naser Zaeri 43
 6.3 PHASE MODULATION

In the third analogue modulation technique,
phase modulation (PM), the phase of the
carrier waveform is altered in proportion to
the amplitude of the modulating signal.

Prepared By: Dr. Naser Zaeri 44
 TM355:
COMMUNICATIONS TECHNOLOGY
BLOCK 1

PART 2:
AN INTRODUCTION TO THE
THEORY OF SIGNALS
1

Prepared By: Dr. Naser Zaeri
Arab Open University
 OUTLINE

Introduction
Time and frequency domains
Digital modulation
Quadrature modulation schemes

Prepared By: Dr. Naser Zaeri 2
 1. INTRODUCTION

In this part of Block 1:
We focus is on the underlying theory
behind signals and modulation.
We understand the time and frequency
domains and why these are important.

Prepared By: Dr. Naser Zaeri 3
2. TIME AND FREQUENCY DOMAINS
2.1 TIME-DOMAIN REPRESENTATION OF SINE WAVES [1/3]

Basic radio waves, called carrier waves, are
sinusoidal.
Time-domain representation of a signal: how the
strength of the signal varies over time.
Mathematically represented by:
𝑣 𝑡 = 𝐴 sin 2𝜋𝑓𝑡 + 𝜑 = 𝐴 sin(𝜔𝑡 + 𝜑)
A is the amplitude (or maximum value) measured in volts (V)
f is frequency measured in hertz (Hz).
T is time period (measures in second), where f=1/T.
ω is the angular frequency = 2𝜋f, measured in radians per
second (rad/s).
𝝋 is the relative phase, measured in radians or degrees.

Prepared By: Dr. Naser Zaeri 4
2.1 TIME-DOMAIN REPRESENTATION OF
SINE WAVES [2/3]
Note: the relative phase 𝝋, is the phase of the signal
where it:
describes the position of the waveform relative to time at 0
seconds.
describes where in the cycle of the waveform it begins its
first cycle.
It can be negative or positive in value, with a negative
value representing a delay and a positive value an
advance in time.
Measured in either degrees (°) or radians (rad), and 360° or
2𝜋 rad is equivalent to a shift in a sinusoidal waveform
through a complete period.
If 𝜑 = +𝜋/2, this would result in a shift of the waveform to the
left by a quarter of a cycle  cosine wave: 𝑣 𝑡 = 𝐴 co𝑠(𝜔𝑡)
Prepared By: Dr. Naser Zaeri 5
2.1 TIME-DOMAIN REPRESENTATION OF
SINE WAVES [3/3]
Sine waves and
cosine waves are
the same shape
but, they start at
different points in
the cycle 
phase shift
between them.
Both are referred
to as sinusoids
and both are
used to represent
electromagnetic
waveforms.
Prepared By: Dr. Naser Zaeri 6
2.2 FREQUENCY-DOMAIN REPRESENTATION OF SINE
WAVES [1/2]

A sinusoid waveform can be plotted in terms of its
frequency.
The frequency-domain representation is often much
more useful than the time-domain representation when
it comes to designing communications systems and
understanding how they work.

Prepared By: Dr. Naser Zaeri 7
2.2 FREQUENCY-DOMAIN REPRESENTATION OF SINE
WAVES [2/2]

The phase component of the waveform can be
illustrated similarly, in a separate diagram with
frequency as the x-axis.
These two diagrams together give the sinusoid’s
complete frequency-domain representation – also
called the spectrum.
Often the plot of amplitude against frequency that provides
the interesting information phase diagram is frequently
omitted.

Prepared By: Dr. Naser Zaeri 8
 2.3 PERIODIC SIGNALS AND THE
FOURIER SERIES [1/6]
The spectrum, with a distinct frequency component
represented by a single line or spike at frequency 𝒇, is the
simplest example of a discrete spectrum.
All periodic signals have a discrete spectrum  spectrum can
be represented by a line or series of lines (or spikes) at specific
frequencies.
Periodic signals that are not simple sinusoids have spectra that
contain multiple spikes.
This is because, all periodic signals can be represented as a
sum of sinusoidal components – that is, a series of different sine
or cosine waves – and each spike represents one of these
components.
Each frequency component of a periodic signal is a multiple,
known as a harmonic, of the fundamental frequency 𝒇.
This series of components is the Fourier series of a signal.
9
 2.3 PERIODIC SIGNALS AND THE
FOURIER SERIES [2/6]
In general terms, a Fourier series looks like the
following equation:
𝒗(𝒕) = 𝑨𝟎 + 𝑨𝟏 cos(𝝎𝒕 + 𝝋𝟏 ) + 𝑨𝟐 cos(𝟐𝝎𝒕 + 𝝋𝟐 ) + 𝑨𝟑 cos(𝟑𝝎𝒕 + 𝝋𝟑 )
+ … + 𝑨𝒏 cos(𝒏𝝎𝒕 + 𝝋𝒏 )
The frequency of each component is a multiple of
the fundamental frequency: 𝜔, 2𝜔, 3𝜔….
The first term, 𝑨𝟎 , represents a component at zero frequency.

Prepared By: Dr. Naser Zaeri 10
 2.3 PERIODIC SIGNALS AND THE
FOURIER SERIES [3/6]
For example, a periodic square waveform can be
represented by the following Fourier series:

Prepared By: Dr. Naser Zaeri 11
 2.3 PERIODIC SIGNALS AND THE
FOURIER SERIES [4/6]
Figure 2.9(a) shows
the original square
waveform (with V=1),
Figures 2.9(b) to (e)
show the four
sinusoidal
components that
were represented as
spikes in Figure 2.8.

12
 2.3 PERIODIC SIGNALS AND THE
FOURIER SERIES [5/6]
Figure 2.10(a) shows the result
of adding the first two
sinusoidal components (Figures
2.9b + c).
This is a much closer
approximation to the original
square wave than part (b) on
its own.
Adding the third and fourth
sinusoids brings the result
closer still to the original, as
seen in Figure 2.10(b) and (c)
respectively.
An infinite number of
components is needed to
reconstruct the square wave
exactly.
13
 2.3 PERIODIC SIGNALS AND THE
FOURIER SERIES [6/6]

Although a square wave theoretically has
an infinite bandwidth (because in theory the
series of high-frequency components
continues indefinitely), the energy in the
components decreases with increasing
frequency.
This means that if only the first few
components are used, not much information
in the reconstruction of the original signal is
lost.
Prepared By: Dr. Naser Zaeri 14
 3. DIGITAL MODULATION [1/4]

Digital modulation has many advantages
over analogue modulation:
Has a greater immunity to noise and other types
of interference.
Enables techniques to be used such as error
control coding, which enables the performance
to be improved,
Encryption for securing transmissions.

Prepared By: Dr. Naser Zaeri 15
 3. DIGITAL MODULATION [2/4]
The three basic digital
modulation schemes
are:
amplitude-shift keying
(ASK)
frequency-shift keying
(FSK)
phase-shift keying (PSK).
The term ‘keying’
originates from the
keys used to generate
early telegraphy
messages.
16
 3. DIGITAL MODULATION [3/4]

There are a number of variants of each of these
schemes that have been developed to overcome
the challenges each one faces and in response to
the need for higher data rates.
One that is of particular interest, and is widely used
in today’s systems, combines elements of PSK and
ASK and is called quadrature amplitude modulation
(QAM).
Popular because they are more spectrally efficient
than other schemes.
Can achieve higher data rates without requiring more
spectrum.

Prepared By: Dr. Naser Zaeri 17
 3. DIGITAL MODULATION [4/4]

There are many factors to take into account when
comparing digital modulation schemes and deciding
which one is most suitable for a specific application:
bandwidth efficient
power efficient
performs well in multipath fading channels
cost effective and simple to implement.
Unfortunately there isn’t one scheme that satisfies them
all.
There are trade-offs to be made:
Before a modulation scheme is chosen for a particular
application, it is important to consider the most important
requirement.
Prepared By: Dr. Naser Zaeri 18
3.1 THE FREQUENCY DOMAIN AND NON-PERIODIC
SIGNALS [1/4]

We saw how the Fourier series can be used to
represent a periodic signal and consequently
illustrate the spectra of such signals.
The Fourier transform is used to give the frequency-
domain representation of non-periodic signals.
Whereas periodic signals have spectra comprising
discrete frequency components, non-periodic
signals have spectra comprising a continuous
spectrum, which means a continuous distribution of
frequency components.

Prepared By: Dr. Naser Zaeri 19
3.1 THE FREQUENCY DOMAIN AND NON-PERIODIC
SIGNALS [2/4]

Continuous spectra are often described using the terms
spectral nulls, main lobe and side lobes.
 The spectral nulls are where the spectral curve crosses
the x-axis – that is, where the spectral energy is zero.
The first pair of spectral nulls in this example occur at -1/𝜏
and 1/ 𝜏.

Prepared By: Dr. Naser Zaeri 20
3.1 THE FREQUENCY DOMAIN AND NON-PERIODIC
SIGNALS [3/4]

The main lobe is the large area in the middle, bounded
by the first pair of spectral nulls, and is the range of
frequencies that contain most of the signal’s energy.
The side lobes are what look like ripples that occur on
either side of the main lobe with much smaller
amplitudes.
As the pulse waveforms get narrower, the spacing
between the first pair of spectral nulls gets larger.
That is, the narrower a pulse, the broader its spectrum.
For example, if a pulse has duration 10 ms, most of the spectral
energy lies within a 200 Hz range. If a pulse has a much shorter
duration, say 10 ns, most of the spectral energy lies within a 200
MHz range.
Prepared By: Dr. Naser Zaeri 21
 3.1 THE FREQUENCY DOMAIN AND NON-PERIODIC
SIGNALS [4/4]

This relationship shows
why, if everything else
remains the same, as
data rates increase (i.e.
more data is
transmitted per
second, which means
a shorter pulse
duration) a larger
bandwidth is needed.

22
 3.2 AMPLITUDE-SHIFT KEYING (ASK) [1/4]

ASK is a special case of AM, so it is the amplitude of
the carrier signal that is modified.
The simplest version of this is also called on–off
keying (OOK).
Suffers from problems:
synchronisation
the receiver have difficulty establishing exactly how
many bits have been received
might potentially think that the transmission has ended
(while it is not!).

Prepared By: Dr. Naser Zaeri 23
 3.2 AMPLITUDE-SHIFT KEYING (ASK) [2/4]

Other versions of ASK
use different (non-
zero) amplitudes to
represent 1 and 0 also
exist.
Bandwidth of an ASK
signal is generally
approximated by BASK
= 2B, where B is the
bandwidth of the
modulating signal.

24
 3.2 AMPLITUDE-SHIFT KEYING (ASK) [3/4]

Representation in
time domain: the
modulated signal
would look like a
segment of a
sinusoid – that is, a
short burst of a
sinusoid.

Prepared By: Dr. Naser Zaeri 25
 3.2 AMPLITUDE-SHIFT KEYING (ASK) [4/4]

In frequency
domain, the
resulting spectrum
is a function of the
spectra of the
original two signals.
In this case, it is the
original spectrum
of the pulse but
shifted to a centre
frequency, 𝑓𝑐.

Prepared By: Dr. Naser Zaeri 26
3.3 FREQUENCY-SHIFT KEYING (FSK)

FSK is a type of frequency modulation, so it is the
frequency of the carrier signal that is modified.
The bandwidth of an FSK-modulated signal:
BFSK = 2(Δf + B), where Δf is the separation of the
two frequencies used:

Prepared By: Dr. Naser Zaeri 27
 3.4 PHASE-SHIFT KEYING (PSK)
PSK is the most widely used in one form or another.
There are many variations of PSK.
In BPSK (Binary Phase-Shift Keying), 0 and 1 are represented by
segments of sinusoids that differ in their phase.
At the demodulator, distinguishing between the two segments
is easier if their phases differ by as much as possible, so they
are invariably separated by half a cycle (equivalent to 𝜋
radians or 180°).
A BPSK-modulated signal is almost as simple to produce as an
ASK signal, but with the added advantage that it is less
susceptible to additive noise.
Bandwidth: BPSK = 2B.

28
3.5 POWER EFFICIENCY AND BIT ERROR
RATES [1/2]
With respect to noise and interference, power
efficiency is concerned with what signal power
levels a transmitter needs to operate at in order to
ensure that the number of bits received in error is at
an acceptable level.
Bit error rate (BER) is defined as the number of bits
received in error divided by the number of bits
transmitted; therefore a low BER is desirable.
Different schemes result in different BERs, and
plotting these against the ratio of signal power to
noise power is a useful indicator of their power
efficiency.
Prepared By: Dr. Naser Zaeri 29
 3.5 POWER EFFICIENCY AND BIT ERROR
RATES [2/2]
For example, take a bit
error rate of 1 error in
10,000,000 bits transmitted
–which is equivalent to a
BER of 10−7.
If this can be achieved at
a lower transmitting power
by one scheme than a
second, then the first
would be deemed to be
more power efficient.
PSK requires less signal
power to achieve the
same BER performance as
FSK and ASK, meaning that
PSK is the most power
efficient.
Prepared By: Dr. Naser Zaeri 30
 4. QUADRATURE MODULATION
SCHEMES
Driven by the need for higher data rates, multiple
variations of the three basic digital modulation
schemes have been developed.
Here, we are concerned with higher-order
modulation methods that use an increased number
of carrier states to achieve higher data rates.
We look at how elements of PSK and ASK can be
combined to enable non-binary schemes to be
used, which can achieve higher data rates without
requiring more spectrum.

Prepared By: Dr. Naser Zaeri 31
 4.1 SYMBOLS AND BAUD [1/3]

The different carrier states are what are known as symbols.
If there are more than two possible carrier states – that is, more
than two symbols available – then it is possible for each
symbol to represent more than one bit.
In Figure 2.23 there are four possible amplitude levels.
 it is possible to associate each symbol uniquely with a 2-bit
binary number  four possible 2-bit binary numbers: 11, 10, 01
and 00.

Prepared By: Dr. Naser Zaeri 32
 4.1 SYMBOLS AND BAUD [2/3]

If the number of bits that can be represented by a
symbol, n, and the number of available symbols, M,
then: 𝑀 = 2𝑛.
Data rates: the number of bits transmitted per
second.
Sometimes the symbol rate is also used in
communication systems
The term baud refers to the number of symbols per
second, where one baud is one symbol per second.

Prepared By: Dr. Naser Zaeri 33
 4.1 SYMBOLS AND BAUD [3/3]

Increasing the number of bits a symbol can
represent means that higher data rates can be
achieved.
The two most widely used digital modulation
schemes in wireless communications systems are:
Quadrature Phase-Shift Keying (QPSK)
Quadrature Amplitude Modulation (QAM).
Higher-order PSK and ASK are used in quadrature
modulation methods.
Quadrature techniques are used in WiFi, digital
television, 3G and 4G mobile telecommunications.

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4.2 QUADRATURE PHASE-SHIFT KEYING
(QPSK) [1/8]
BPSK uses segments of two
sinusoidal waves that differ
in phase by a half-cycle (𝜋
radians or 180°) to
represent its two symbols.
Instead of thinking of Figure
2.24(b) as a phase-shifted
version of Figure 2.24(a),
we can think of it now as
having an amplitude of −1
relative to Figure 2.24(a).

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4.2 QUADRATURE PHASE-SHIFT KEYING
(QPSK) [2/8]
The essence of quadrature modulation methods is
the application of complementary pairs of
amplitudes to two simultaneous sinusoidal waves
differing in phase by one-quarter of a cycle.
It is customary to refer to one of these waves as the
I wave, or in-phase wave or component, and the
other as the Q wave, or quadrature wave or
component.
Remember: a sine wave and a cosine wave
happen to be a quarter of a cycle apart  I wave
can also be thought of as a sine wave and the Q
wave as a cosine wave.

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4.2 QUADRATURE PHASE-SHIFT KEYING
(QPSK) [3/8]
The preservation of the quadrature relationship between the I
and Q waves, despite the inversion of either or both of the
waves, means that both waves can be modulated using BPSK
and the quadrature relationship between them is preserved.
 This is the basis of QPSK.

37
4.2 QUADRATURE PHASE-SHIFT KEYING
(QPSK) [4/8]
Another way of describing the I and Q waves is that
they are orthogonal to each other.
Orthogonality is an important concept in
communications systems.
‘Orthogonal’ in the context of two orthogonal lines, in
which it means they are ‘at right angles’ or perpendicular
to each other.
It can also mean ‘statistically independent’ or
uncorrelated’.
If two signals are orthogonal: when they are
transmitted simultaneously, one can be completely
recovered at the receiver without any interference
from the second, and vice versa.
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4.2 QUADRATURE PHASE-SHIFT KEYING
(QPSK) [5/8]
Signal constellation diagram: the points on the
diagram represent the different symbols that the
carrier can assume.
For BPSK: there is no quadrature wave and the two
symbols are simply represented as two points on the
I-axis (x-axis) at +1 and −1.

39
4.2 QUADRATURE PHASE-SHIFT KEYING
(QPSK) [6/8]
Signal constellation diagram for QPSK: can be thought of as
two BPSK waveforms in quadrature.
 two symbols on the I-axis and two on the Q-axis.
QPSK can achieve twice the data rate of a comparable BPSK
scheme for a given bandwidth
 Makes QPSK such an attractive option.

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4.2 QUADRATURE PHASE-SHIFT KEYING
(QPSK) [7/8]
Figure 2.30 shows a different, but equally valid,
representation.
This constellation diagram looks like the original one
in Figure 2.29, but rotated through 𝜋/4 radians or
45°.

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4.2 QUADRATURE PHASE-SHIFT KEYING
(QPSK) [8/8]
Constellation diagrams are useful for representing
the symbols of a modulation scheme.
As the number of symbols increases, the scheme
becomes more bandwidth efficient
 the more symbols there are on the constellation
diagram, the more data bits are transmitted per
symbol  higher data rates for a given bandwidth.
However, as the constellation becomes more
densely packed with symbols, the distance
separating the points becomes smaller.
 can have negative effects on performance.
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 4.3 QUADRATURE AMPLITUDE
MODULATION (QAM) [1/2]
In considering how to increase
the number of available
symbols further than QPSK can
provide, there are two options:
The first possibility: the amplitude of
the modulated signal remains fixed
but the number of different phases
the carrier wave can take
continues to increase.
This is the principle applied in M-PSK
schemes or PSK of the order M,
where M is the number of possible
symbols.

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 4.3 QUADRATURE AMPLITUDE
MODULATION (QAM) [2/2]
The second possibility: is to combine
QPSK with ASK techniques and
introduce more amplitude levels as
well as phases.
This is the principle of quadrature
amplitude modulation (QAM).
Schemes of this kind are referred to as
M-QAM or QAM of the order M.
16-QAM is much more widely used in
practice than 16-PSK, along with
higher-order schemes such as 64-
QAM, 128-QAM and 256-QAM.
This is because it performs better in
noisy channels.
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