TELECOMMUNICATION NETWORK PLANNING AND OPTIMISATION NUMBER
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Jun 15, 2024
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About This Presentation
The transmission from the BS in the downlink can be
heard by every mobile user in the cell and is referred to
as broadcasting.
▪ Transmission from the mobile users in the uplink to the
BS is many-to-one and is referred to multiple access.
▪ For voice or data communications, must ensure two-way
c...
Slide Content
MODULE CODE AND TITLE:
ETTNO801:TELECOMMUNICATION NETWORK
PLANNING AND OPTIMISATION
NUMBER OF CREDITS: 15
B.Tech Electronics and Telecommunication Technology , Academic year 2024/2025 1
Btech in
Electronics and Telecommunication Technology
ETTNO801:TELECOMMUNICATION NETWORK
PLANNING AND OPTIMISATION
NUMBER OF CREDITS: 15
B.Tech Electronics and Telecommunication Technology , Academic year 2024/2025 1
Btech in
Electronics and Telecommunication Technology
Mobile Multiple Access Techniques and Interference
Management
Management
Reuse Frequency Distance and Co-channel Interference
•But D (distance between any two cells) is a function of NI and S/I. NI is
the number of co-channel-interfering cells in the first tier.
•Where S is the desired signal power from the desired base station and Ii
is the interference power caused by the ith interfering co-channel cell
base station.
•But D (distance between any two cells) is a function of NI and S/I. NI is
the number of co-channel-interfering cells in the first tier.
•Where S is the desired signal power from the desired base station and Ii
is the interference power caused by the ith interfering co-channel cell
base station.
Mobile Multiple Access Techniques
▪The transmission from the BS in the downlink can be
heard by every mobile user in the cell and is referred to
as broadcasting.
▪Transmission from the mobile users in the uplink to the
BS is many-to-one and is referred to multiple access.
▪For voice or data communications, must ensure two-way
communication (duplexing, it is possible to talk and listen
simultaneously).
▪Duplexing may be done using frequency or time domain
techniques
▪The transmission from the BS in the downlink can be
heard by every mobile user in the cell and is referred to
as broadcasting.
▪Transmission from the mobile users in the uplink to the
BS is many-to-one and is referred to multiple access.
▪For voice or data communications, must ensure two-way
communication (duplexing, it is possible to talk and listen
simultaneously).
▪Duplexing may be done using frequency or time domain
techniques
Mobile Multiple Access Techniques
•Multiple access schemes are used to allow many users
to share simultaneously a finite amount of radio spectrum
resources.
•For high-quality communication this sharing of spectrum
should not degrade performance of the system.
•Duplexing is generally required
•Frequency domain
•Time domain
•Transmission modes can be categorized into three
distinct types: simplex, half-duplex, and full-duplex.
•Multiple access schemes are used to allow many users
to share simultaneously a finite amount of radio spectrum
resources.
•For high-quality communication this sharing of spectrum
should not degrade performance of the system.
•Duplexing is generally required
•Frequency domain
•Time domain
•Transmission modes can be categorized into three
distinct types: simplex, half-duplex, and full-duplex.
DUPLEXING communication
What is Duplexing?
•to talk and listen simultaneously is called
duplexing.
•Classification of communication systems
according to their connectivity.
What is Duplexing?
•to talk and listen simultaneously is called
duplexing.
•Classification of communication systems
according to their connectivity.
DUPLEXING communication(Cont’d)
▪In simplex mode, transmission is unidirectional (i.e., transmission
always occurs only in one direction). The simplex mode uses the entire
capacity of the channel to send data in one direction. Examples of
simplex communication are used in commercial broadcasting.
•Inhalf-duplex mode, transmission is bi-directional, but only in one
direction at a time. The end devices can both transmit and receive, but
not at the same time. In half-duplex mode, the entire capacity of the
channel is taken over by whichever of the two devices is transmitting at
the time. Examples of half-duplex communication are walkie-
talkies and CB radios as well as dial-up fax machines.
•Infull-duplex mode, transmission is simultaneously bi-directional. The
end devices can transmit and receive simultaneously. A prime example of
full-duplex communications is the PSTN which provides two-way
communications
▪In simplex mode, transmission is unidirectional (i.e., transmission
always occurs only in one direction). The simplex mode uses the entire
capacity of the channel to send data in one direction. Examples of
simplex communication are used in commercial broadcasting.
•Inhalf-duplex mode, transmission is bi-directional, but only in one
direction at a time. The end devices can both transmit and receive, but
not at the same time. In half-duplex mode, the entire capacity of the
channel is taken over by whichever of the two devices is transmitting at
the time. Examples of half-duplex communication are walkie-
talkies and CB radios as well as dial-up fax machines.
•Infull-duplex mode, transmission is simultaneously bi-directional. The
end devices can transmit and receive simultaneously. A prime example of
full-duplex communications is the PSTN which provides two-way
communications
▪Frequency division Duplexing (FDD) : Uplink (UL) and
Downlink (DL) communication are separated in the frequency
domain by assigning two different frequency
▪Time division Duplexing (TDD) : UL and DL communication
take place over the same frequency but at different instants
of time but this time is too small to be perceived by us.
DUPLEXING communication
Downlink (DL) communication are separated in the frequency
domain by assigning two different frequency
▪Time division Duplexing (TDD) : UL and DL communication
take place over the same frequency but at different instants
of time but this time is too small to be perceived by us.
DUPLEXING communication
FDMA: All users share the available frequency spectrum
at the same time. Each users has its frequency portion.
Channel Capacity of FDMA System :
N=(Bt-2Bg)/Bc Where
:Bc: Channel bandwidth
:Bg: indicates guard band
:Bt: represent transmission
band width
Example: Advanced Mobile Phone System
Frequency Division Multiple Access (FDMA)
at the same time. Each users has its frequency portion.
Channel Capacity of FDMA System :
N=(Bt-2Bg)/Bc Where
:Bc: Channel bandwidth
:Bg: indicates guard band
:Bt: represent transmission
band width
Example: Advanced Mobile Phone System
Frequency Division Multiple Access (FDMA)
EXAMPLE: A DVANCED MOBILE PHONE SYSTEM(AMPS)
AMPS
FDMA/FDD
Analog cellularsystem
12.5 MHz per simplex band -Bt
Bguard = 10 kHz ; Bc = 30kHz
30E3
N=
12.5E6-2*(10E3)
= 416channels
20
AMPS
FDMA/FDD
Analog cellularsystem
12.5 MHz per simplex band -Bt
Bguard = 10 kHz ; Bc = 30kHz
30E3
N=
12.5E6-2*(10E3)
= 416channels
20
FDMA/FDD FDMA/TDD
FDMA Disadvantages
•FDMA has a drawback that if a channel is assigned to the
user most of the time it is idle.
•Bandwidth requirement is more.
•Lower spectral efficiency
•FDMA has a drawback that if a channel is assigned to the
user most of the time it is idle.
•Bandwidth requirement is more.
•Lower spectral efficiency
Time Division Multiple Access (TDMA)
TDMA: A group of users use the same frequency
channel but during different time intervals (Time
Slot).
•TDMA systems divide each FDMA channel line to
time slots
•Each user occupies a cyclically repeating time
slot
•TDMA can allow different number of time slots for
separate user
Non-continuous transmission
Most of second generation systems use TDMA
Example: Global
System for Mobile
(GSM)
TDMA: A group of users use the same frequency
channel but during different time intervals (Time
Slot).
•TDMA systems divide each FDMA channel line to
time slots
•Each user occupies a cyclically repeating time
slot
•TDMA can allow different number of time slots for
separate user
Non-continuous transmission
Most of second generation systems use TDMA
Example: Global
System for Mobile
(GSM)
TDMA/FDD TDMA/TDD
22
Channel Capacity of TDMA System
Channel Capacity of TDMA System
EXAMPLE: GLOBAL SYSTEM FOR MOBILE (GSM)
200E3
N=
8*25E6
= 1000 simultaneoususers
25
GSM is a TDMA/FDD system that uses 25 MHz for the forward link,
with channels of 200 KHz. If 8 speech channels are supported on a
single radio channel, and if no guard band is assumed, find the
number of simultaneous users that can be accommodated in GSM.
Thus, GSM can accommodate 1000 simultaneous users.
200E3
N=
8*25E6
= 1000 simultaneoususers
25
GSM is a TDMA/FDD system that uses 25 MHz for the forward link,
with channels of 200 KHz. If 8 speech channels are supported on a
single radio channel, and if no guard band is assumed, find the
number of simultaneous users that can be accommodated in GSM.
Thus, GSM can accommodate 1000 simultaneous users.
Code Division Multiple Access (CDMA)
In CDMA, all users use the same carrier frequency
and transmit simultaneously “Wideband system”
Each user has its own pseudo random
code word which is approximately
orthogonal to other codes.
•CDMA permits using same set of frequencies in
all the cells “ Universal Frequency reuse”. This
eliminates the frequency of planning
•Some second-generation systems use CDMA
• Most of the third-generation systems use CDMA
In CDMA, all users use the same carrier frequency
and transmit simultaneously “Wideband system”
Each user has its own pseudo random
code word which is approximately
orthogonal to other codes.
•CDMA permits using same set of frequencies in
all the cells “ Universal Frequency reuse”. This
eliminates the frequency of planning
•Some second-generation systems use CDMA
• Most of the third-generation systems use CDMA
SDMA is a multiple access technique, takes the
advantage of the directional nature of space.
Using a directional antenna the transmission
power is focused in a desired direction and
reduces the interferences.
SDMA can be used in combination with other
multiple access technique, since user in
different space domain can use the same
frequency, time and code resources, without
creating interferences.
advantage of the directional nature of space.
Using a directional antenna the transmission
power is focused in a desired direction and
reduces the interferences.
SDMA can be used in combination with other
multiple access technique, since user in
different space domain can use the same
frequency, time and code resources, without
creating interferences.
Introduction
Coverage Dimensioning Process
B.Tech Electronics and Telecommunication Technology , Academic year 2024/2025 20
Coverage planning consists of an evaluation of Down Link and
Upper Link radio link budgets. The maximum path loss is
calculated based on service throughput defined by the cell
edge user that requires SINR level at the receiver
B.Tech Electronics and Telecommunication Technology , Academic year 2024/2025 20
Coverage planning consists of an evaluation of Down Link and
Upper Link radio link budgets. The maximum path loss is
calculated based on service throughput defined by the cell
edge user that requires SINR level at the receiver
Academic Year: 2021-2022
Mechanism of EM Wave Propagation
Mechanism of EM Wave Propagation
Mechanism of Wave Propagation
•In general, radio wave propagation consists of three main attributes: reflection,
diffraction and scattering
•Reflection occurs when radio wave propagating in one medium impinges upon
another medium with different electromagnetic properties (permittivity,
permeability, and conductivity).
•Diffraction is a phenomenon by which propagating radio waves bend or deviate in
the neighborhood of obstacles. Diffraction results from the propagation of
wavelets into a shadowy region caused by obstructions such as walls, buildings,
mountains, and so on.
•Scattering occurs when a radio signal hits a rough surface or an object having a
size much smaller than or on the order of the signal wavelength. This causes
the signal energy to spread out in all directions.
•In general, radio wave propagation consists of three main attributes: reflection,
diffraction and scattering
•Reflection occurs when radio wave propagating in one medium impinges upon
another medium with different electromagnetic properties (permittivity,
permeability, and conductivity).
•Diffraction is a phenomenon by which propagating radio waves bend or deviate in
the neighborhood of obstacles. Diffraction results from the propagation of
wavelets into a shadowy region caused by obstructions such as walls, buildings,
mountains, and so on.
•Scattering occurs when a radio signal hits a rough surface or an object having a
size much smaller than or on the order of the signal wavelength. This causes
the signal energy to spread out in all directions.
▪The main goal of coverage planning is to estimate the
coverage distance of a BTS with parameter settings
based on actual cell edge coverage requirements to meet
network size requirements
▪The initial planning of a cellular network is selecting an
adequate propagation model for the frequency range and
type of region considered.
▪Radio Link Budget is the most prominent component of a
coverage planning exercise
B.Tech Electronics and Telecommunication Technology , Academic year 2024/2025 23
Introduction
coverage distance of a BTS with parameter settings
based on actual cell edge coverage requirements to meet
network size requirements
▪The initial planning of a cellular network is selecting an
adequate propagation model for the frequency range and
type of region considered.
▪Radio Link Budget is the most prominent component of a
coverage planning exercise
B.Tech Electronics and Telecommunication Technology , Academic year 2024/2025 23
Introduction
▪The necessary parameter to characterize when the signal
in a mobile receiver is obtained, is the path loss or
propagation loss (L), which is defined by
B.Tech Electronics and Telecommunication Technology , Academic year 2024/2025 24
Propagation Methods
•Then, the main objective of a tool that aims to obtain the
received power based on the positions of the transmitter
(Tx) and the receiver (Rx) is to characterize the propagation
loss in a given environment
Path Loss
in a mobile receiver is obtained, is the path loss or
propagation loss (L), which is defined by
B.Tech Electronics and Telecommunication Technology , Academic year 2024/2025 24
Propagation Methods
•Then, the main objective of a tool that aims to obtain the
received power based on the positions of the transmitter
(Tx) and the receiver (Rx) is to characterize the propagation
loss in a given environment
Path Loss
Free-Space Attenuation
•The most simple wave propagation case is that of a direct
wave propagation in free space . In this special case of line-
of-sight (LOS) propagation there are no obstructions due to
the earth’s surface or other obstacles.
Attenuation: Reduction in amplitude of signal level
•The most simple wave propagation case is that of a direct
wave propagation in free space . In this special case of line-
of-sight (LOS) propagation there are no obstructions due to
the earth’s surface or other obstacles.
Attenuation: Reduction in amplitude of signal level
Free-Space Attenuation
The received power, Pr, at the receiving antenna (mobile station),
located at a distance, d, from the transmitter (base station) is
given for free space propagation as:
If other losses (not related to propagation) are also present, we
can rewrite Equation as
The received power, Pr, at the receiving antenna (mobile station),
located at a distance, d, from the transmitter (base station) is
given for free space propagation as:
If other losses (not related to propagation) are also present, we
can rewrite Equation as
Academic Year: 2021-2022
Free-Space Attenuation
Free-Space Attenuation
Free-Space Attenuation
•Obviously, this situation does not happen in a real
environment, and the loss is modified by different natural
(mountains, vegetation) and artificial (buildings) obstacles
in the environment.
•Obviously, this situation does not happen in a real
environment, and the loss is modified by different natural
(mountains, vegetation) and artificial (buildings) obstacles
in the environment.
NOISE TEMPERATURE, NOISE FIGURE AND SNR
•The noise introduced by a network may also be expressed as effective
noise temperature (Te).
•Effective noise temperature defined as that fictional temperature at the
input of the network, which would account for additional noise introduced
by the network itself at the output.
•Effective noise temperature (Te) is related to noise figure (F) as follows.
B.Tech Electronics and Telecommunication Technology , Academic year 2024/2025 29
Check Page 84-87: Yadaav
•The noise introduced by a network may also be expressed as effective
noise temperature (Te).
•Effective noise temperature defined as that fictional temperature at the
input of the network, which would account for additional noise introduced
by the network itself at the output.
•Effective noise temperature (Te) is related to noise figure (F) as follows.
B.Tech Electronics and Telecommunication Technology , Academic year 2024/2025 29
Check Page 84-87: Yadaav
Free-Space Attenuation
Signal to Noise Ratio (SNR)
•The SNR is defined as the ratio of power received to system noise
power.
in which the system noise power PN (in watts) is related with the
system noise temperature Ts as follows:
B.Tech Electronics and Telecommunication Technology , Academic year 2024/2025 30
•From Friis equation, the received power by an antenna
is
Check Page 84-87: Yadaav
Signal to Noise Ratio (SNR)
•The SNR is defined as the ratio of power received to system noise
power.
in which the system noise power PN (in watts) is related with the
system noise temperature Ts as follows:
B.Tech Electronics and Telecommunication Technology , Academic year 2024/2025 30
•From Friis equation, the received power by an antenna
is
Check Page 84-87: Yadaav
Free-Space Attenuation
Signal to Noise Ratio (SNR)
B.Tech Electronics and Telecommunication Technology , Academic year 2024/2025 31
If the receiver has its own centre temperature Tr (due to
thermal noise), the system noise power at the receiver
terminals is given by :
Check Page 84-87: Yadaav
Signal to Noise Ratio (SNR)
B.Tech Electronics and Telecommunication Technology , Academic year 2024/2025 31
If the receiver has its own centre temperature Tr (due to
thermal noise), the system noise power at the receiver
terminals is given by :
Check Page 84-87: Yadaav
Academic Year: 2021-2022
Free-Space Attenuation
Free-Space Attenuation
Free-Space Attenuation
•We assume that the base station and mobile station antenna
heights, hb and hm, are much smaller compared to their
separation, d, and the reflecting earth surface is flat.
Attenuation over Reflecting Surface
heights, hb and hm, are much smaller compared to their
separation, d, and the reflecting earth surface is flat.
Attenuation over Reflecting Surface
•The received power at the antenna located at a distance, d,
from the transmitter, including other losses, L0, is given as
Attenuation over Reflecting Surface
•Note that under the assumed conditions the received signal
level depends only on the transmitted power, antenna
heights, and separation distance; no frequency dependence
from the transmitter, including other losses, L0, is given as
Attenuation over Reflecting Surface
•Note that under the assumed conditions the received signal
level depends only on the transmitted power, antenna
heights, and separation distance; no frequency dependence
Attenuation over Reflecting Surface
1ft = 0.3048m
1ft = 0.3048m
Attenuation over Reflecting Surface
•The expression for the effects of ground reflections from a flat (or
plane) earth provides results that are approximately correct for
•The results are not valid for
In this case, the attenuation factor will be:
•The expression for the effects of ground reflections from a flat (or
plane) earth provides results that are approximately correct for
•The results are not valid for
In this case, the attenuation factor will be:
Effect of Earth’s Curvature
•The curvature of the earth further affects the propagation of
the space wave since the ground-reflected wave is reflected
from a curved surface.
•Therefore, the energy on a curved surface diverges more
than it does from a flat surface and the ground-reflected wave
reaching the receiver is weaker than for a flat earth
•The divergence factor D that describes this effect is less than unity
and is given as:
•The curvature of the earth further affects the propagation of
the space wave since the ground-reflected wave is reflected
from a curved surface.
•Therefore, the energy on a curved surface diverges more
than it does from a flat surface and the ground-reflected wave
reaching the receiver is weaker than for a flat earth
•The divergence factor D that describes this effect is less than unity
and is given as:
Effect of Earth’s Curvature
•D ranges from unity for a small value of d and approaches zero
as d approaches the distance to the radio horizon.
•The equation for calculating the received power in dBm is given
as:
•D ranges from unity for a small value of d and approaches zero
as d approaches the distance to the radio horizon.
•The equation for calculating the received power in dBm is given
as:
NLO Propagation && Shadowing Effect
•Also called lognormal fading
•Lognormal fading, which could reduce the received power
at any location.
•Also called lognormal fading
•Lognormal fading, which could reduce the received power
at any location.
NLO Propagation && Shadowing Effect
The received power under non-line-of-sight propagation conditions
can be written as:
The received power under non-line-of-sight propagation conditions
can be written as:
NLO Propagation && Shadowing Effect
Propagation Path-Loss Models
•Propagation path-loss models play an important role in the
design of cellular systems to specify key system parameters
such as transmission power, frequency, antenna heights,
and so on.
•Propagation models are used to determine the number of
cell sites required to provide coverage for the network.
•The propagation model is also used in other system
performance aspects including handoff optimization, power
level adjustments, and antenna placements.
•We discuss two widely used empirical models:
Okumura/Hata and COST 231 models.
•Propagation path-loss models play an important role in the
design of cellular systems to specify key system parameters
such as transmission power, frequency, antenna heights,
and so on.
•Propagation models are used to determine the number of
cell sites required to provide coverage for the network.
•The propagation model is also used in other system
performance aspects including handoff optimization, power
level adjustments, and antenna placements.
•We discuss two widely used empirical models:
Okumura/Hata and COST 231 models.
B.Tech Electronics and Telecommunication Technology , Academic year 2024/2025 44
Okumura-Hata Propagation Model
•Okumura analyzed path-loss characteristics based on a large
amount of experimental data collected around Tokyo, Japan
•He selected propagation path conditions and obtained the
average path-loss curves under flat urban areas. Then he
applied several correction factors for other propagation
conditions, such as:
Okumura-Hata Propagation Model
•Okumura analyzed path-loss characteristics based on a large
amount of experimental data collected around Tokyo, Japan
•He selected propagation path conditions and obtained the
average path-loss curves under flat urban areas. Then he
applied several correction factors for other propagation
conditions, such as:
B.Tech Electronics and Telecommunication Technology , Academic year 2024/2025 45
Okumura-Hata Propagation Model
Typical Urban
Okumura-Hata Propagation Model
Typical Urban
B.Tech Electronics and Telecommunication Technology , Academic year 2024/2025 46
Okumura-Hata Propagation Model
Okumura-Hata Propagation Model
B.Tech Electronics and Telecommunication Technology , Academic year 2024/2025 47
Okumura-Hata Propagation Model
Okumura-Hata Propagation Model
B.Tech Electronics and Telecommunication Technology , Academic year 2024/2025 48
Cost 231-Hata Model
•This model is a combination of empirical and deterministic models
for estimating the path loss in an urban area over the frequency
range of 800 MHz to 2000 MHz.
Cost 231-Hata Model
•This model is a combination of empirical and deterministic models
for estimating the path loss in an urban area over the frequency
range of 800 MHz to 2000 MHz.
B.Tech Electronics and Telecommunication Technology , Academic year 2024/2025 49
Cost 231-Hata Model
Cost 231-Hata Model
B.Tech Electronics and Telecommunication Technology , Academic year 2024/2025 50
Cost 231-Hata Model
Cost 231-Hata Model
B.Tech Electronics and Telecommunication Technology , Academic year 2024/2025 51
Cost 231-Hata Model
Cost 231-Hata Model
B.Tech Electronics and Telecommunication Technology , Academic year 2024/2025 52
Cost 231-Hata Model
Cost 231-Hata Model
B.Tech Electronics and Telecommunication Technology , Academic year 2024/2025 53
Path Loss Propagation Models
Path Loss Propagation Models
B.Tech Electronics and Telecommunication Technology , Academic year 2024/2025 54
Path Loss Propagation Models
Path Loss Propagation Models
B.Tech Electronics and Telecommunication Technology , Academic year 2024/2025 55
Path Loss Propagation Models
Path Loss Propagation Models
B.Tech Electronics and Telecommunication Technology , Academic year 2024/2025 56
Path Loss Propagation Models
Path Loss Propagation Models
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