Communication Technology Lecture Notes 2024-2025 PDF

Summary

These lecture notes cover fundamental concepts in communication technology for the 2024-2025 Fall semester. Topics include communication systems, components, data vs signal, and different types of communication channels. The notes are based on a presentation series.

Full Transcript

Fall Semester

2024-
2025

IT438
Communication Technology
Kamal Hamza, PhD Acknowledgement: This presentation contains
some figures and text from Data Communications
and Networks book by W. Stallings
Introduction
Communication – Basic process of
exchanging information from one
location (source) to destination
(receiving end).

Refers to the process of sending,
receiving and processing of
information/signal/input from one
point to another point.

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Communication Systems
Components
Any communication system consists of three basic
blocks:
Transmitter
Receiver
Communication Channel
Source Transmitter Channel Receiver Recipient

A transmitter prepares the data (information) to be
transmitted in the appropriate format in order to be
transmitted over the communication channel.
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Communication System Components
(cont.)

Transmitt
er

Receiver

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Communication System Components (cont.)

Information Source

Generates the message(s). Examples are voice, pictures, computer

key board, etc..

If the message is not electrical, a transducer is used to convert it

into an electrical signal.

Source can be analog or digital.
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Communication System Components
(cont.)
Source encoder/decoder

The source encoder maps the signal produced by the source into a digital
form.
The mapping is done so as to remove redundancy in the output signal
and also to represent the original signal as efficiency as possible (using as
few bits as possible).
The mapping must be such that an inverse operation (source decoding)
can be easily done.
If the message is a voice signal, the source encoder would convert the
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analog voice signal into a digital form (binary data) and compress it (e.g.,
Communication System Components
(cont.)
Channel encoder/decoder
Maps the input digital signal into another digital signal in such a
way that the noise will be minimized.
When transmitting binary data, the channel encoder could add
extra bits (redundancy) that help detect and correct errors.
Focus on Error detection and correction to ensure reliable
transmission over noisy channels.

Modulator
Modulation provides for efficient transmission of the signal over
channel.
Most modulation schemes impress the information on either the
amplitude, phase or frequency of a sinusoid.

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Examples of Guided Comm.
Channels

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8
Examples of Unguided Comm.
Channels

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9
Why Different Types of Comm.
Systems?
There are several factors that give rise to the need for
different types of communication systems:
The nature of the communication channel (undersea
communication requires optical fiber cables)
The nature of the application (mobile applications needs
wireless systems)
Required level of quality (performance and quality of the
received signal)
Cost IT438 Communication Technology 9
Problems that Face Comm.
Systems
Any communication system can be subject to three main
sources of problems:
Noise: undesired effect from the communication environment.
Usually, it is not under our control (your system has to deal
with it).
Interference: due to superposition of two or more signals.
May result from bad design of communication systems
(interference of voice channels in telephone systems, for
example)
Jamming: intentional interference that aims at destroying the
IT438 Communication Technology
quality of the transmitted signal to prevent transmission. 10
Problems that Face Comm. Systems
(cont.)

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Problems that Face Comm. Systems
(cont.)

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Data versus Signal
Differentiate between two terms: data (information) and
signal.
Data (information): are generated by the application and
need to be transmitted to some receiver.
Signal: is the representation of the data in the
communication system.
Data are generated from the source (application) and signals
are generated from the transmitter of the communication
system we build.
Speaking in a microphone: data (information) is what I say,
whereas signal is what moves insideIT438the wire of the
Communication Technology 13
microphone (electricity).
Types of Data and Signal
Depending on the application nature, we have four possible
combinations of data and signals:
Analog Data, Analog Signal: Traditional telephone system.
Analog Data, Digital Signal: Voice over IP (VoIP), digital music streaming.
Digital Data, Analog Signal: Modems (used in early internet connections), Optical networks.
Digital Data, Digital Signal: Ethernet, Wi-Fi, modern computer networks.

Since any communication system deals with signals, we
first need to understand the nature and types of signals.

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Signal Representation in the Time
Domain
Viewed as a function of time, an electromagnetic signal can
be either continuous or discrete.
A continuous signal is one in which the signal intensity varies in a
smooth fashion over time.

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Signal Representation in the Time
Domain (cont.)
A discrete signal is one in which the signal intensity maintains a
constant level for some period of time and then changes to
another constant level.

Discrete Signal

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Signal Representation in the Time
Domain (cont.)
Smoothly rises and falls,

Sine Wave following a continuous curve.
used to represent analog
signals in communication
systems.

Quickly switches between high

Square Wave and low values, creating sharp,
rectangular steps.
used in digital systems to
represent binary data (0s and
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1s).
Signal Representation in the Time
Domain
A sine wave is a fundamental mathematical function that
describes
a smooth, periodic oscillation. Key Features of a Sine Wave:
Amplitude (A):
This is the peak value (height) of the wave, representing the
maximum displacement of the wave from its central position.
Higher amplitude means a stronger or louder.
Frequency (f):
Frequency refers to how many cycles (complete waves) occur per
second, measured in Hertz (Hz). A higher frequency means the
wave oscillates faster.
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Signal Representation in the Time
Domain
Period (T):
The period is the time it takes to complete one full cycle of the
wave. It is the inverse of frequency (T = 1/f). A shorter period
means a higher frequency.
Phase (φ):
Phase refers to the horizontal shift of the wave. If two sine
waves have different phases, one wave may start at a different
point in its cycle compared to the other. Phase differences are
crucial in signal modulation and communication.

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Signal Representation in the Time
Domain (cont.) Sine Wave

Amplitude, Frequency, Phase

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Signal Representation in the Time
Domain (cont.) Sine Wave (cont.)

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