CSN405 Handout 4_pdf.pdf

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Handout 4

Radio Frequency Signal and
Antenna Concepts
Course Name: Wireless Networks
Course Code: CSN 405
Notes appended and modified
to those accompanying
“CWNA Certified Wireless Network Administrator: Official
Study Guide”, D. Coleman & D. Westcott, John Wiley &
Sons - Sybex, 6th Ed., 2021, Ch. 5

Chapter 5 Overview
•
•
•
•
•
•
•
•

Active and Passive Gain
Azimuth and Elevation Charts
Interpreting Polar Charts
Beamwidth
Antenna Types
Visual Line of Sight
RF Line of Sight
Fresnel Zone

Certified Wireless Network Administrator: CWNA – PW0-108

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Chapter 5 Overview (continued)
•
•
•
•
•
•

Earth Bulge
Antenna Polarization
Antenna Diversity
Multiple-Input Multiple-Output (MIMO)
Antenna Connection and Installation
Antenna Accessories

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Isotropic Radiator

 An isotropic radiator is a point source
that radiates signal equally in all
directions.
 The sun is probably one of the best
examples of an isotropic radiator. It
generates equal amounts of energy in all
directions.

4

Electromagnetic Field
Electric and Magnetic fields are perpendicular to one
another, moving into space away from the source
 Electric Field – E-Plane
 Magnetic Field – H-Plane

Electric Field
Direction

Magnetic Field

5

Passive Amplifier

Antenna
Radios modulate a
baseband signal onto
an electrical current

Radio
Transceiver

RF Cable

The electrical current
is carried by a
conductive RF cable.

Antennas convert
electrical current into
RF waves.

6

Passive Antenna Gain: dBi and dBd
Isotropic
Radiator

dBi - Decibels relative to an isotropic radiator
 Used to measure passive antenna gain
 0 dBi = no directivity / passive gain

HalfWave
Dipole

dBd - Decibels relative to a half-wave dipole
 Lesser used unit to measure antenna
gain
 Half-wave dipole = 2.14 dBi
 0 dBd = 2.14 dBi

7

Azimuth and Elevation
 To assist potential buyers
with their purchasing
decisions, antenna
manufacturers create
azimuth charts and
elevation charts, commonly
known as radiation
patterns, for their antennas.
 These radiation patterns
are created in controlled
environments, where the
results cannot be skewed by
outside influences and
represent the signal pattern
that is radiated by a
particular model of
antenna.
 These charts are commonly
known as polar charts or
antenna radiation
envelopes.

8

Azimuth and Elevation
omnidirectional

Elevation

semidirectional

Azimuth

Elevation

Azimuth

Azimuth chart = H-plane = top-down view
Elevation chart = E-plane = side view

9

Azimuth and Elevation Charts
• Commonly known as radiation patterns
• Created in controlled environments
• Also known as polar charts

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Azimuth and Elevation Charts (continued)
•
•
•
•
•

Azimuth chart = H-plane = top-down view
Elevation chart = E-plane = side view
Outer ring usually represents strongest signal
Scale of chart is in dB from outer ring inward
Therefor chart is logarithmic not linear

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Interpreting Polar Charts
• Often misinterpreted and misread
• dB aspect of chart is often misunderstood
• If you have 4 boxes and each is double the previous,
it is simpler to represent them as the first image
versus the second

1

2 4 8 16

32 64 128

256

512

• However many people do not realize that the first
image is a logarithmic representation, not the actual
linear coverage
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Interpreting Polar Charts (continued)
• Left images show logarithmic and linear
representation of an omnidirectional antenna
• Right images show logarithmic and linear
representation of a directional antenna
• Remember the 6 dB rule when creating a normalized
view of a polar chart

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Beamwidth
• Measurement of how broad or narrow the
focus of an antenna is
• Measured both horizontally and vertically
• Measurement from the strongest point on
polar chart to the half power (-3 dB) points
• Measured in degrees

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Beamwidth
 Beamwidth is the measurement
of how broad or narrow the focus
of an antenna is— and is
measured both horizontally and
vertically.

Main lobe

60º

Side/back lobes

 It is the measurement from the
center, or strongest point, of the
antenna signal to each of the
points along the horizontal and
vertical axes, where the signal
decreases by half power (–3 dB).
 These –3 dB points are often
referred to as half-power points.

15

Beamwidth (continued)
• Start at the strongest point (1)
• On each side, move along
the antenna pattern to 3 dB
closer to center of polar
chart (2)
• Draw a line to these points
and measure the degrees
between the lines (3)

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Beamwidth (continued)

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Antenna Types
• Omnidirectional – radiates in all directions,
provides general coverage
• Semidirectional – wide directional focus
• Highly directional – narrow directional focus
• Antennas focus both transmitted and
received signals

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Antenna Types

 Omnidirectional: Antennas that radiate RF in a fashion similar
to the way a table or floor-lamp radiates light. They are
designed to provide general coverage horizontally in all
directions.
 Semidirectional: Antennas that radiate RF in a fashion similar
to the way a wall sconce radiates light away from the wall or the
way a street lamp shines light down on a street or a parking lot,
providing a directional light across a large area.
 Highly directional: These highly directional antennas radiate RF
in a fashion similar to the way a spotlight focuses light on a
stage or a sign.

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Omnidirectional Antennas
•
•
•
•
•

Dipole antenna is typical
Coverage pattern is bagel shaped
Typically used for point-to-multipoint networks
Top view (azimuth) is circular
Side view (elevation) is shown below, varies
with gain

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Half-wave dipole antenna
Improperly installed

Note: For this antenna, Lambda = λ = C/F
λ = 3 * 10^8 / 2.4 * 10^9 = 3/24 = 1/8 = 0.125 (m)
and λ/4 = 0.03125 (m) = 3.125 cm

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Semidirectional Antennas
• Directs signal in a specific direction
• Short to medium distance communications
• Three types of antennas

Patch

– Patch
– Panel
– Yagi

• Planar Antennas (Patch & Panel)
• Horizontal beamwidth < 180 degrees
Yagi
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Highly Directional Antennas
• Most focused, narrow beamwidth
• Strictly point-to-point communications
• Two types of antennas
– Parabolic Dish
– Grid
• Grid antenna less susceptible to wind load
Grid

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Sector Antennas
• High-gain, semidirectional
• Generates very little RF signal
behind the antenna (back lobe)
• Pie-shaped coverage – 60 to 180
degrees
• Sectorized array – multiple sector
antennas installed as a group to
provide 360 degrees of horizontal
coverage
• Narrow vertical beamwidth – 7 to 17
degrees (slight downtilt)
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Antenna Arrays
• Group of two or more antennas integrated to
provide coverage
• Perform beamforming – concentrating RF
energy
• Three types of beamforming
• Static
• Dynamic
• Transmit

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Static Beamforming
• Using directional
antennas to
provide a fixed
radiation pattern
• Another term for
sectorized array
• Slight overlap
between antenna
patterns can
improve roaming

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Dynamic Beamforming
• Focuses the RF energy in a specific direction and
particular shape in the direction of an individual client
• Broadcast frames are sent omnidirectionally
• Pattern can change on a frame-by-frame basis
• Uses an adaptive antenna array
• Known as smart antenna technology or beamstearing

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Transmit Beamforming (TxBF)
• Multiple phase-shifted signals are transmitted
to arrive in-phase at the location of the
receiver
• A digital signal processing technology
• Technically not an antenna technology
• 802.11n amendment defines two types
– Implicit TxBF (uses an implicit channel-sounding process
to optimize the phase difference of the transmitted chains)

– Explicit TxBF (uses feedback from the user station to
determine the amount of phase shift required for each signal)

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Visual Line of Sight (LOS)
• Perceived straight line that light travels along
• Due to refraction, diffraction, and reflection,
there is a slight chance that it is not
• Has no bearing on successful RF
transmission

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Indoor Antennas – Directional

 It is common for patch antennas to be connected to
access points to provide directional coverage within a
building.
 Because Omnidirectional antennas often have
difficulty providing effective RF coverage in areas with
shelving.
 MIMO patch antennas, such as the one shown, can
be used effectively in libraries, warehouses, and
retail stores with long aisles of shelves.

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Indoor Antennas – Directional
Another common use case for deploying
MIMO patch antennas indoors is in very
high- density (VHD) environments.
 The use of directional antennas
reduces Cochannel Interference, CCI,
especially when a 40 MHz channel
reuse pattern is deployed.
 Directional antennas are often used in
very high density environments to
sector the coverage.
 Examples: lecture halls, gymnasiums,
libraries, cafeterias, etc.

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Outdoor – Semidirectional

 Yagi and sector antennas
 Used for building-to-building WLAN
communications

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Downtilt

0°
Angle of
Downtilt

 Antenna downtilt is a vertical alignment principle designed to point the
antenna’s main lobe in the proper direction
 The downtilt angle is determined by the antenna height (at both
locations, if bridging two radios) and distance
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Outdoor – Highly Directional
Root bridge

Non-root bridge

 Dish and grid antennas
 Used for long-distance point-to-point
bridge links

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Polarization
 Describes the antenna structure or
the orientation of an antenna’s
wave oscillations
 Determined by the E-field
 Polarization of Tx and Rx antennas
should match
When discussing antennas, the proper
term is antenna polarization, which
refers to the alignment or orientation of
the waves. The use of the term polarity
is incorrect. Polarity refers to positive or
negative voltage, which has no
relevance to antenna orientation.
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Antenna Polarization
• Orientation of the amplitude of the RF waves
– Vertical
– Horizontal

• Transmitting and receiving antennas must
have the same orientation
• “Antenna Properties.wmv” from the book’s
website www.sybex.com/go/cwna3e presents
this well

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RF Line of Sight
• Required unobstructed LOS between two
antennas
• Additional area needed around the visual
LOS
• Additional area = Fresnel zone

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Fresnel Zone
• Imaginary American football-shaped area that
surrounds the visual LOS between two point-to-point
antennas
• Theoretically an infinite number of zones
• Closest zone is the first Fresnel zone
• First two zones are most relevant
• Only frequency and distance affect size of Fresnel
zone (unaffected by antenna gain)

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Fresnel Zone (continued)
• Obstruction of first Fresnel zone will negatively
influence the integrity of the RF communication
• Obstruction decreases the energy of the received
signal
• Ideally no obstructions at all
• > 40 percent obstruction will likely make the link
unreliable

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Fresnel Zone Formula (at midpoint)
Radius of first Fresnel Zone
radius = 72.2 x [D÷ (4 x F)]
D = distance of the link in miles
F = transmitting frequency in GHz

Minimum clearance formula (60% unobstructed)
radius (60%) = 43.3 x [D ÷ (4 x F)]
D = distance of the link in miles
F = transmitting frequency in GHz

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Fresnel Zone Formula (at any point)
Radius of first Fresnel Zone at any point
radius = 72.2 x

[(N x d1 x d2) ÷ (F x D)]

N = which Fresnel zone you are calculating (usually 1 or 2)
d1 = distance from one antenna to the location of the obstacle in miles
d2 = distance from the obstacle to the other antenna in miles
D = total distance between the antennas in miles (D = d1 + d2)
F = frequency in GHz

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Fresnel Zone – RF Line of Sight

 The first Fresnel zone is technically
the area around the point source,
where the waves are in phase with
the point source signal.
 The second Fresnel zone is then the
area beyond the first Fresnel zone,
where the waves are out of phase
with the point source signal.
 All the odd-numbered Fresnel zones
are in phase with the point source
signal, and all the even-numbered
Fresnel zones are out of phase.

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Fresnel Zone

Entire Fresnel zone - 100%

Fresnel zone - 60% clearance

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Earth Bulge
• Curvature of the earth
• Must be considered if link is > 7 miles
H = D2 ÷ 8
H = height of the earth bulge in feet
D = distance between the antennas in miles
• Overall antenna height formula
H = obstacle height + earth bulge + Fresnel zone

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Earth Bulge

When you are installing long-distance point-to-point
RF communications, another variable that must be
considered is the curvature of the earth.
FZ3
FZ2
FZ1

H = D2 ÷ 8
H = height of the earth bulge in feet
D = distance between the antennas in miles

455

Antenna Diversity
• Exists when wireless device has two
antennas and receivers functioning together
• Pre-802.11n radios use switched diversity
• Listens with multiple antennas but only
processes the signal with the best amplitude
– known as receive diversity
• When transmitting, the device will the
antenna that was last used to receive –
known as transmit diversity

Certified Wireless Network Administrator: CWNA – PW0-108

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Simple Antenna Diversity
 Legacy APs: 802.11a/b/g use switched
antenna diversity to minimize the negative
effects of multipath.

802.11a/b/g WLAN Radio

Antennas

Antenna
Switch

Multiple antennas connected to
same radio via a single radio chain

 When receiving incoming transmissions,
switched diversity listens with multiple
antennas. Multiple copies of the same signal
arrive at the receiver antennas with different
amplitudes.
 The signal with the best amplitude is chosen,
and the other signals are ignored.
 This method of listening for the best received
signal is also known as receive diversity.

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Simple Antenna Diversity

802.11a/b/g WLAN Radio

Antennas

 Switched diversity is also used when
transmitting, but only one antenna is
used.
 The transmitter will transmit out of the
diversity antenna where the best
amplitude signal was last heard.

Antenna
Switch

Multiple antennas connected to
same radio via a single radio chain

 The method of transmitting out of the
antenna where the last best-received
signal was heard is known as transmit
diversity.

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Multiple-Input Multiple-Output (MIMO)
• More sophisticated form of antenna diversity
• Radio architecture that can receive or
transmit using multiple antennas concurrently
• Uses complex signal-processing techniques
• Enhances
– Reliability
– Range
– Throughput

• Used by 802.11n and 802.11ac radios
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MIMO Antennas
• Indoor MIMO Antennas
– Typically not much choice
– Usually 3 omnidirectional antennas
– One antenna vertical, other two slightly tilted

• Outdoor MIMO Antennas
– Usually 2 antennas per radio
– Multipath is provided by using different polarization
– Special pairs of omnidirectional antennas provide
horizontal and vertical polarization
– Directional MIMO antennas incorporated two
antenna elements within one physical antenna
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MIMO Antenna Diversity

802.11n/ac MIMO Radio

Antennas

 Multiple-input, multiple-output (MIMO) is
more sophisticated form of antenna
diversity that takes advantage of multipath.
 MIMO is a wireless radio architecture that
can receive or transmit using multiple
antennas concurrently.

Multiple antennas connected to
multiple radio chains

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Antenna Connection and Installation
• Voltage Standing Wave Ratio (VSWR)
• Signal Loss
• Antenna Mounting
– Placement
– Mounting
• Indoor mounting considerations
• Outdoor mounting considerations

– Appropriate use and environment
• Ingress Protection Rating (IP Code)
• National Electrical Manufacturers Association (NEMA)
Enclosure Rating
• "Appareils destinés à être utilisés en ATmosphères
Explosives" (ATEX) Directives
• National Electrical Code (NEC) hazardous locations
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Antenna Connection and Installation (continued)
• Antenna Mounting (continued)
– Orientation and alignment
– Safety
– Maintenance

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Antenna Accessories
•
•
•
•

Cables
Connectors
Splitters
Amplifiers
– Fixed-gain
– Fixed-output

• Attenuators
• Lightning arrestors
• Grounding rods and wires
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RF Connectors

55

RF Cabling
Outer jacket

Braided shield
Inner Conductor

 Cable introduce signal loss into a
communications link.
 Higher the grade of cable, the less
the loss.
 Cable must be rated for proper
frequency response.

56

Impedance

 Access Point connectors
 Cabling
 Connectors
 Antennas

50 Ohms

50 Ohms

 Impedance is a value of ohms of electrical resistance to an AC
signal.
 Impedance must match when connecting RF equipment.

57

Regulatory Compliance
• For an access point manufacturer to sell its product within a
country or region, it must prove that its product operates within
the rules of the relevant regulatory domain, such as the FCC.
• The FCC does allow an antenna to be substituted with a
different one, providing two key conditions are met:
The gain of the new antenna must be the same or lower
than the antenna that the system was certified with.
• The new antenna must be of the same type, which means
that the antenna must have the same in-band and out-ofband characteristics.
•

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VSWR

 Voltage standing wave ratio (VSWR) is a
measurement of the change in impedances to an AC
signal.
50 Ohms

 Voltage standing waves exist because of impedance
mismatches or variations between devices in an RF
communications system.
 When the transmitter generates the AC radio signal,
the signal travels along the cable to the antenna.
Some of the energy is reflected back toward the
transmitter because of impedance mismatch.

75 Ohms

59

VSWR
VSWR is a ratio measurement of an impedance mismatch:
 1:1 (no impedance) being optimal but unobtainable.
 Typical values range from 1.1:1 to as much as 1.5:1.
 VSWR military specs are 1.1:1.
50 Ohms

Negative effects of VSWR:
 Decreased signal amplitude (return loss)
 Erratic signal amplitude
 Transmitter or amplifier failure
75 Ohms

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Lightning Arrestors

 Bi-metal conductors or gas
discharge tubes
 Detect incoming over-voltages
induced by nearby lightning strikes
 Shunt the current to earth ground
 Cannot fully protect against a
direct lightning strike

Coaxial Gas Discharge Tube Surge Protectors

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Lightning Protection

WLAN Bridge

Lightning
Arrestor

Antenna

Partially Protected
Network Segment
Copper
Copper / Fiber
Transceiver
Fiber
Fully Protected
Network Segment

Ground
Wire

Copper / Fiber
Transceiver
Grounding
Rod

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FCC Certified System
 Regulators require
wireless systems to be
authorized as a system
 Use of non-certified
equipment with an
intentional radiator
must follow specific
guidelines
 Third-party antennas
may be used (in FCC)
with restrictions
 The FCC maintains
public documents
about authorized
equipment

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Indoor AP and Antenna Mounting

64

Chapter 5 Summary
•
•
•
•
•
•
•
•

Active and Passive Gain
Azimuth and Elevation Charts
Interpreting Polar Charts
Beamwidth
Antenna Types
Visual Line of Sight
RF Line of Sight
Fresnel Zone

Certified Wireless Network Administrator: CWNA – PW0-108

65

Chapter 5 Summary (continued)
•
•
•
•
•
•

Earth Bulge
Antenna Polarization
Antenna Diversity
Multiple-Input Multiple-Output (MIMO)
Antenna Connection and Installation
Antenna Accessories

Certified Wireless Network Administrator: CWNA – PW0-108

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Questions

Home Work
1. Open your book and go through all the review questions
at the end of the chapter.
2. Review the answers by using Appendix A.
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