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Transmission line - Metallic conductor system used to Propagation Constant – used to express the attenuation
transfer electrical energy from one point to another and the phase shift per unit length of a transmission line.
using electrical current flow.
Velocity factor – the ratio of the actual velocity of
Transverse Electromagnetic Wave (TEM) – propagates propagation of an electromagnetic wave through a given
primarily in the non-conductor (dielectric) that separates medium to the velocity of propagation though a vacuum.
the two conductors of the transmission line.
Dielectric Constant – the relative permittivity of a
Wave Velocity - the speed at which a wave travels material.
through a medium, carrying energy from one place to
Electrical Length – used extensively for transmission-line
another without permanently displacing the medium
calculations and antenna design.
itself. It depends on the properties of the medium, such
as its density, elasticity, and temperature. Five types of transmission line losses
Frequency – the rate at which the periodic wave repeats. Conductor loss - inherent unavoidable loss
Wavelength – the distance of one cycle occurring in Radiation loss - directly proportional to frequency
space. Dielectric heating loss - difference of potential
between two conductors of a metallic transmission
Single-ended or Unbalanced Transmission Lines – one line
wire is at ground potential, whereas the other wire is at Coupling loss - occurs whenever a connection is made
signal potential. to or from a transmission line or when two sections of
transmission line are connected together.
Balanced Transmission Lines – with two-wire balanced
lines, both conductors carry current; however, one Corona - a luminous discharge that occurs between
conductor carries the signal, and the other conductor is the two conductors of a transmission line when the
the return path. difference of potential between them exceeds the
breakdown voltage of a dielectric insulator.
Open-wire Transmission Line – two-wire parallel
conductors. Consists simply of two parallel wires, closely Incident wave - voltage that propagates from the source
spaced and separated by air. toward the load.

Twin-lead Transmission Line - same as open-wire Reflected wave - voltage that propagates from the load
transmission line except that the spacers between the toward the source
two conductors are replaced with a continuous solid Resonant Transmission Line - energy is alternatively
dielectric that ensures uniform spacing along the entire transferred back and forth between the magnetic and
cable. electric fields of the distributed inductance and
Twisted-wire pair Transmission Line – formed by capacitance of the line.
twisting two insulated conductors around each other. Flat or Nonresonant Transmission Line - transmission
Often stranded in units. line with no reflected power.
Shielded-cable Transmission Line – is a parallel two-wire Reflection coefficient – vector quantity that represents
transmission line consisting two copper conductors the ratio of reflected voltage to incident voltage or
separated by a solid dielectric material reflected current to incident current.
Concentric Transmission Line – often used for high data Standing waves – two travelling waves set up an
transmission rates to reduce losses and isolate interference pattern
transmission paths
Standing-wave ratio – the ratio of the maximum voltage
Characteristic Impedance - is a complex quantity that is to the minimum voltage or the maximum current to the
expressed in ohms, ideally independent of line length, minimum current of a standing wave on a transmission
and cannot be directly measured. line.
BOOK REVIEW IN COMMUNICATIONS Electronic Communications System By Wayne Tomasi

CHAPTER 14 ELECTROMAGNETIC WAVE PROPAGATION

# DEFINITIONS TERMS

Propagation of electromagnetic waves often called
1) radio-frequency (RF) propagation or simply radio Free-space
propagation.

2) Electrical energy that has escaped into free space. Electromagnetic wave

The orientation of the electric field vector in respect
3) Polarization
to the surface of the Earth.

4) Polarization remains constant Linear Polarization

Horizontal Polarization
5) Forms of Linear polarization
and Vertical Polarization

Polarization vector rotates 360◦ as the wave moves
6) one wave-length through the space and the field Circular Polarization
strength is equal at all angles of polarization.

7) Field strength varies with changes in polarization.
Elliptical Polarization

Used to show the relative direction of
8) Rays
electromagnetic wave propagation.

Formed when two points of equal phase on rays
9) Wavefront
propagated from the same source are joined
together.

A single location from which rays propagate equally
10) Point source
in all directions.

11) Invisible force field produced by a magnet, such as a Magnetic Field
conductor when current is flowing through.

Prepared By : MA. ELAINE L. CORTEZ 86
BOOK REVIEW IN COMMUNICATIONS Electronic Communications System By Wayne Tomasi

Strength of a magnetic field (H) produced around a
12)
conductor is expressed mathematically as:

Invisible force fields produced by a difference in
13) Electric fields
voltage potential between two conductors.

Electric filed strength (E) is expressed mathematically
14) 2
as:

Dielectric constant of the material separating the two
15) Permittivity
conductors.

16) The permittivity of air or free space is approximately. 8.85 x 10 -12 F/m

The rate at which energy passes through a given
17) Power density
surface area in free space.

Intensity of the electric and magnetic fields of an
18) Field intensity
electromagnetic wave propagating in free space.

Mathematically power density is expressed as:
19) P = €H W/m2

The characteristic impedance of a
lossless transmission medium is equal to the square 1/2
20) Zs = (µo 0)
root of the ratio of its magnetic permeability to its
electric permittivity.

Point source that radiates power at a constant rate
21) Isotropic radiator
uniformly in all directions.

Power density is inversely proportional to the square of
22) Inverse Square Law
the distance from the source.

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BOOK REVIEW IN COMMUNICATIONS Electronic Communications System By Wayne Tomasi

23) Propagation medium. Isotropic medium

Waves propagate through free space, they spread
24) Attenuation
out, resulting in a reduction in power density.

25) Reduction of Power. Absorption Loss

Reduction in power density with distance is equivalent
26) Wave attenuation
to a power loss.

27) Spherical spreading of the wave. Space attenuation

28) One with uniform properties throughout. Homogeneous medium

Absorption coefficient varies considerably with
29) location, thus creating a difficult problem for radio Inhomogeneous medium
systems engineers.

Refraction, Reflection,
30) Optical properties of Radio Waves.
Diffraction and
Interference

31) Bending of the radio wave path. Refraction

Square root of the dielectric constant and is
32) Refractive index; n = (k)
expressed in:

(k) Equivalent dielectric constant relative to free
33)
space (vacuum). K = (1- 81N/f2)1/2

Boundary between two media with different densities.
34) Plane

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BOOK REVIEW IN COMMUNICATIONS Electronic Communications System By Wayne Tomasi

Imaginary line drawn perpendicular to the interface
35) Normal
at the point of incidence.

Angle formed between the incident wave and the
36) Angle of Incidence
normal.

Angle formed between the refracted wave and the
37) Angle of Refraction
normal.

Ratio of velocity of propagation of a light ray in free
38) space to the velocity of propagation of a light ray in Refractive Index
a given material.

Perpendicular to the direction of propagation
39) Density gradient
(parallel to the waveform)

40) To cast or turn back. Reflect

Ratio of the reflected to the incident voltage
42) Reflection Coefficient
intensities.

Portion of the total incident power that is not Power transmission
43)
reflected. coefficient

44) Fraction of power that penetrates medium 2. Absorption coefficient

Incident wave front strikes an irregular surface, it is
45) Diffuse reflection
randomly scattered in many directions.

Specular (mirrorlike)
46) Reflection from a perfectly smooth surface.
reflection

47) Semirough surfaces
Surfaces that fall between smooth and irregular.

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BOOK REVIEW IN COMMUNICATIONS Electronic Communications System By Wayne Tomasi

Semirough surface will reflect as if it were a smooth
surface whenever the cosine of the angle of Rayleigh criterion
48) incidence is greater than λ/8d, where d is the depth
of the surface irregularity and λ is the wavelength of Cos θi > λ/8d
the incident wave.

Modulation or redistribution of energy within a
49) wavefront when it passes near the edge of an Diffraction
opaque object.

Diffraction occurs around the edge of the obstacle,
51) Shadow zone
which allows secondary waves to “sneak” around the
corner of the obstacle.

States that the total voltage
54) intensity at a given point in space is the sum of the Linear Superposition
individual wave vectors.

Electromagnetic waves travelling within Earth’s
52) Terrestial waves
atmosphere.

Communications between two or more points on Terrestial radio
53)
Earth. communications

54) Used for high-frequency applications. Sky waves

Earth –guided electromagnetic wave that travels
55) Surface wave
over the surface of earth.

Relative
Surface
Conductivity
Seawater Good
Flat, loamy soil Fair
Relative Conductivity of Earth Surfaces Large bodies of
56) Fair
freshwater
Rocky terrain Poor
Desert Poor
Jungle Unusable

Prepared By : MA. ELAINE L. CORTEZ 90
BOOK REVIEW IN COMMUNICATIONS Electronic Communications System By Wayne Tomasi

1. Ground waves require
a relatively transmission
power.
2. Ground waves are
limited to very low, low,
and medium frequencies.
57) Disadvantages of surface waves.
3. Requiring large
antennas.
4. Ground losses vary
considerably with surface
material and
composition.

1. Given enough transmit
power, ground waves
can be used to
communicate between
any two locations in the
58) Advantages of ground wave propagation. world.

2. Ground waves are
relatively unaffected by
changing atmospheric
conditions.

Travel essentially in a straight line between the
59) Direct waves
transmit and receive antennas.

Line-of-Sight (LOS)
60) Space wave propagation with direct waves.
transmission

The curvature of Earth presents a horizon to space
61) Radio Horizon
wave propagation.

Occurs when the density of the lower atmosphere is
62) such that electromagnetic waves are trapped Duct propagation
between it and Earth’s surface.

Lowest layer of the ionosphere and is located
63) D Layer
approximately between 30 miles and 60 miles (50 km
to 100 km) above Earth’s surface.
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BOOK REVIEW IN COMMUNICATIONS Electronic Communications System By Wayne Tomasi

Located approximately between 60 miles and 85
64) E Layer
miles (100 km to 140 km) above Earth’s surface.

65) The upper portion of the E layer. Sporadic E layer

Made up of two layers, F 1 and F 2 layers.
66) F Layer

Highest frequency that can be propagated directly
67) upward and still be returned to Earth by the Critical frequency
ionosphere.

Maximum vertical angle at which it can be
68) propagated and still be refracted back by the Critical Angle
ionosphere.

A measurement technique used to determine the
69) Ionospheric Sounding
critical frequency.

Height above the Earth’s surface from which a
70) Virtual Height
refracted wave appears to have been reflected.

Highest frequency that can be used for sky wave
Maximum Usable
71) propagation between two specific points on Earth’s
Frequency (MUF)
surface.

MUF = critical
72)
Secant law. frequency/cosθi

Operating at a frequency of 85% of the MUF provides Optimum Working
73)
more reliable communications. Frequency (OWF)

Minimum distance from a transmit antenna that a sky
74) Skip distance
wave at a given frequency will be returned to Earth.

Prepared By : MA. ELAINE L. CORTEZ 92
BOOK REVIEW IN COMMUNICATIONS Electronic Communications System By Wayne Tomasi

The area between where the surface waves are
75) completely dissipated and the point where the first Quiet, or skip, zone
sky wave returns to Earth.

Formed by the ionosphere is raised, allowing sky
76) waves to travel higher before being returned to Ceiling
Earth.

77) Define as the loss incurred by an electromagnetic Free-space path loss
waves as it propagates in a straight line through a
vacuum with no absorption or reflection of energy
from nearby objects.

78) Occurs simply because of the inverse square law. Spreading loss

79) Variation in signal loss. Fading

80) To accommodate temporary fading, an additional Fade margin
loss is added to the normal path loss Fm = 30 logD + 10log
(6ABf) – 10log (1-R) – 70

Prepared By : MA. ELAINE L. CORTEZ 93
BOOK REVIEW IN COMMUNICATIONS Electronic Communications System By Wayne Tomasi

CHAPTER 12 METALLIC CABLE TRANSMISSION MEDIA

# DEFINITIONS TERMS

Provides a conduit in which electromagnetic signals Guided Transmission
1)
are contained. Media

Unguided Transmission
2) Emitted then radiated through air or a vacuum.
Media

Used to propagate electromagnetic signals between Cable Transmission
3)
two locations in a communications system. Medium

Most common means of interconnecting devices in Cable Transmission
4)
local area networks. Systems

Metallic conductor system used to transfer electrical
5) energy from one point to another using electrical Transmission line
current flow.

longitudinal and
6) Two basic kinds of waves.
transverse

7) The rate at which the periodic wave repeats. Frequency

Currents that flow in opposite directions in a
8) Metallic circuit currents
balanced wire pair.

9) Currents that flow in the same direction. Longitudinal currents

10) Cancellation of common mode signals. Common mode rejection

One wire is at the ground potential, whereas the Single-ended or
11)
other is at signal potential. unbalanced

A circuit device used to connect a balanced
12) transmission line to an unbalanced load. balun

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BOOK REVIEW IN COMMUNICATIONS Electronic Communications System By Wayne Tomasi

Most common metallic cables used to interconnect Parallel-conductor
14) data communications systems and computer transmission lines and
networks. coaxial transmission lines.

Formed by twisting two insulated conductors around
15) Twisted-pair
each other.

Unshielded twisted pair
16) Types of twisted pair.
and Shielded twisted pair

Coupling that takes place when a transmitted signal
17) is coupled into the received signal at the same end Near-end crosstalk
of the cable.

Pair 1: blue/white stripe
and blue
Pair 2: orange/white
Standard color code specified by the EIA for CAT-5 stripe and orange
18)
cable. Pair 3: green/white strip[e
and green
Pair 4: brown/white stripe
and brown

19) Woven into a mesh. Braid

Name given to the area between the ceiling and the
root in a single-story building or between the ceiling
20) Plenum
and the floor of the next higher level in a multi-story
building.

Used for high data transmission rates to reduce losses
21) Coaxial
and isolate transmission path.

Refers to the woven stranded mesh that surrounds
22) Shielding
some types of coaxial cables.

One layer of foil insulation and one layer of braided
23) shielding. Dual shielded

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BOOK REVIEW IN COMMUNICATIONS Electronic Communications System By Wayne Tomasi

Rigid air-filled; solid
24) Types of coaxial cables.
flexible

26) Uniformly distributed throughout the length of the line. Distributed parameters

27) Transmission characteristics of a transmission line. Secondary constants

28) Impedance seen looking into an infinitely long line. Surge impedance

Expressed the attenuation and the phase shift per
29) Propagation constants
unit length of a transmission line.

Ratio of the actual velocity of propagation of an
30) electromagnetic wave through a given medium to Velocity factor.
the velocity of propagation through a vacuum.

31) Relative permittivity of a material. Dielectric constant

Conductor loss, radiation
loss, dielectric heating
32) Several ways in which signal power is lost.
loss, coupling loss and
corona

Voltage that propagates from the source toward the
33) Incident voltage
load.

Voltage that propagates that propagates from the
34) Reflected voltage
load toward the source.

35) Transmission line with no reflected power. Flat or non resonant line

Vector quantity that represents the ratio of reflected
36) voltage to incident voltage or reflected current to Reflection coefficient
incident current.

37) Incident power is absorbed by the load. Matched line

Prepared By : MA. ELAINE L. CORTEZ 80
BOOK REVIEW IN COMMUNICATIONS Electronic Communications System By Wayne Tomasi

Unmatched or
38) Incident power returned (reflected) to the source.
mismatched line

39) Two travelling waves set up an interference pattern. Standing wave

Ratio of the maximum voltage to the minimum
40) voltage or the maximum current to the minimum Standing-wave ratio
current of a standing wave on a transmission line.

Used to matched transmission lines to purely resistive
Quarter-wavelength
41) loads whose resistance is not equal to the
transformers
characteristic impedance of the line.

A technique that can be used to locate an Time domain
42)
impairment in a metallic cable reflectometry (TDR)

43) Return signal. Echo

Simply a flat conductor separated from a ground
44) Microstrip
plane by an insulating di-electric material.

Simply a flat conductor sandwiched between two
45) Stripline
ground planes.

Prepared By : MA. ELAINE L. CORTEZ 81