Fading Seminar
errajesh1717
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Jul 13, 2010
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About This Presentation
Loss of strength, A periodic reduction in the received strength of a radio transmission.
This is about the phenomenon of loss of signal in telecommunications.Fading refers to the
time variation of the received signal power caused by changes in the transmission medium or path.
Slide Content
Presented By :Presented By :
Er. Rajesh Kumar Er. Rajesh Kumar
INDIAINDIA
Er. Rajesh Kumar Er. Rajesh Kumar
INDIAINDIA
FADINGFADING
““This is about the phenomenon of This is about the phenomenon of
loss of signal in telecommunicationsloss of signal in telecommunications.“ .“
““This is about the phenomenon of This is about the phenomenon of
loss of signal in telecommunicationsloss of signal in telecommunications.“ .“
INDEXINDEX
SMALL SCALE FADINGSMALL SCALE FADING
1.1.Small scale multipath propagationSmall scale multipath propagation
2.2.Multipath fading channelMultipath fading channel
FACTORS INFLUENCING SMALL SCALE FADINGFACTORS INFLUENCING SMALL SCALE FADING
DOPPLER SHIFTDOPPLER SHIFT
TYPES OF SMALL SCALE FADINGTYPES OF SMALL SCALE FADING
1.1.Fading effect due to multipath time delay spreadFading effect due to multipath time delay spread
• Flat FadingFlat Fading
• Frequency Selective FadingFrequency Selective Fading
2. Fading effect due to Doppler Spread2. Fading effect due to Doppler Spread
• Fast FadingFast Fading
• Slow FadingSlow Fading
STATISTICAL MODELS FOR MULTIPATH FADINGSTATISTICAL MODELS FOR MULTIPATH FADING CHANNELSCHANNELS
1.1.Clarke’s modelClarke’s model
2.2.Two ray Rayleigh Fading modelTwo ray Rayleigh Fading model
3.3.Saleh and Valenzuele Indoor statistical modelSaleh and Valenzuele Indoor statistical model
4.4.SIRCIM AND SMRCIM Indoor and Outdoor statistical modelSIRCIM AND SMRCIM Indoor and Outdoor statistical model
SMALL SCALE FADINGSMALL SCALE FADING
1.1.Small scale multipath propagationSmall scale multipath propagation
2.2.Multipath fading channelMultipath fading channel
FACTORS INFLUENCING SMALL SCALE FADINGFACTORS INFLUENCING SMALL SCALE FADING
DOPPLER SHIFTDOPPLER SHIFT
TYPES OF SMALL SCALE FADINGTYPES OF SMALL SCALE FADING
1.1.Fading effect due to multipath time delay spreadFading effect due to multipath time delay spread
• Flat FadingFlat Fading
• Frequency Selective FadingFrequency Selective Fading
2. Fading effect due to Doppler Spread2. Fading effect due to Doppler Spread
• Fast FadingFast Fading
• Slow FadingSlow Fading
STATISTICAL MODELS FOR MULTIPATH FADINGSTATISTICAL MODELS FOR MULTIPATH FADING CHANNELSCHANNELS
1.1.Clarke’s modelClarke’s model
2.2.Two ray Rayleigh Fading modelTwo ray Rayleigh Fading model
3.3.Saleh and Valenzuele Indoor statistical modelSaleh and Valenzuele Indoor statistical model
4.4.SIRCIM AND SMRCIM Indoor and Outdoor statistical modelSIRCIM AND SMRCIM Indoor and Outdoor statistical model
FADINGFADING
Selective fading causes a cloudy pattern to appear on Selective fading causes a cloudy pattern to appear on
an an FFTFFT display. display.
FadingFading (or (or fading channelsfading channels) refers to mathematical ) refers to mathematical
models for the distortion that a carrier-modulated models for the distortion that a carrier-modulated
telecommunication signal experiences over certain telecommunication signal experiences over certain
propagation media. Short-term fading, also known as propagation media. Short-term fading, also known as
multipathmultipath induced fading induced fading , is due to , is due to multipathmultipath
propagationpropagation. Fading results from the . Fading results from the superpositionsuperposition of of
transmitted signals that have experienced differences in transmitted signals that have experienced differences in
attenuationattenuation, , delaydelay and and phase shiftphase shift while traveling from the while traveling from the
source to the receiver. It may also be caused by attenuation source to the receiver. It may also be caused by attenuation
of a single signal.of a single signal.
The most common types of fading, known as "slow The most common types of fading, known as "slow
fading" and "fast fading", as they apply to a mobile radio fading" and "fast fading", as they apply to a mobile radio
environment, are explained below.environment, are explained below.
Selective fading causes a cloudy pattern to appear on Selective fading causes a cloudy pattern to appear on
an an FFTFFT display. display.
FadingFading (or (or fading channelsfading channels) refers to mathematical ) refers to mathematical
models for the distortion that a carrier-modulated models for the distortion that a carrier-modulated
telecommunication signal experiences over certain telecommunication signal experiences over certain
propagation media. Short-term fading, also known as propagation media. Short-term fading, also known as
multipathmultipath induced fading induced fading , is due to , is due to multipathmultipath
propagationpropagation. Fading results from the . Fading results from the superpositionsuperposition of of
transmitted signals that have experienced differences in transmitted signals that have experienced differences in
attenuationattenuation, , delaydelay and and phase shiftphase shift while traveling from the while traveling from the
source to the receiver. It may also be caused by attenuation source to the receiver. It may also be caused by attenuation
of a single signal.of a single signal.
The most common types of fading, known as "slow The most common types of fading, known as "slow
fading" and "fast fading", as they apply to a mobile radio fading" and "fast fading", as they apply to a mobile radio
environment, are explained below.environment, are explained below.
FadingFading refers to the time variation of the refers to the time variation of the
received signal power caused by changes in the received signal power caused by changes in the
transmission medium or path.transmission medium or path.
Small scale fading or simply fading is used to Small scale fading or simply fading is used to
describe the rapid fluctuations of the amplitude, describe the rapid fluctuations of the amplitude,
phases or multipath delays of a radio signal over phases or multipath delays of a radio signal over
a short period of time or travel distance, so that a short period of time or travel distance, so that
large scale path loss effects may be ignored. large scale path loss effects may be ignored.
Fading is caused by interference between two or Fading is caused by interference between two or
more versions of the transmitted signal which more versions of the transmitted signal which
arrives at the receiver at slightly different times.arrives at the receiver at slightly different times.
These waves, called multipath waves, combine at These waves, called multipath waves, combine at
the receiver antenna to give a resultant signal, the receiver antenna to give a resultant signal,
which can vary widely in amplitude and phase, which can vary widely in amplitude and phase,
depending on the distribution of the intensity and depending on the distribution of the intensity and
relative propagation time of the waves and the relative propagation time of the waves and the
bandwidth of the transmitted signal. bandwidth of the transmitted signal.
received signal power caused by changes in the received signal power caused by changes in the
transmission medium or path.transmission medium or path.
Small scale fading or simply fading is used to Small scale fading or simply fading is used to
describe the rapid fluctuations of the amplitude, describe the rapid fluctuations of the amplitude,
phases or multipath delays of a radio signal over phases or multipath delays of a radio signal over
a short period of time or travel distance, so that a short period of time or travel distance, so that
large scale path loss effects may be ignored. large scale path loss effects may be ignored.
Fading is caused by interference between two or Fading is caused by interference between two or
more versions of the transmitted signal which more versions of the transmitted signal which
arrives at the receiver at slightly different times.arrives at the receiver at slightly different times.
These waves, called multipath waves, combine at These waves, called multipath waves, combine at
the receiver antenna to give a resultant signal, the receiver antenna to give a resultant signal,
which can vary widely in amplitude and phase, which can vary widely in amplitude and phase,
depending on the distribution of the intensity and depending on the distribution of the intensity and
relative propagation time of the waves and the relative propagation time of the waves and the
bandwidth of the transmitted signal. bandwidth of the transmitted signal.
EXAMPLEEXAMPLE
For example, consider the common experience of For example, consider the common experience of
stopping at traffic lights and hearing a lot of static stopping at traffic lights and hearing a lot of static
on your FM broadcast radio, which is immediately on your FM broadcast radio, which is immediately
corrected if you move less than a meter. Cellular corrected if you move less than a meter. Cellular
phones also exhibit similar momentary fades. The phones also exhibit similar momentary fades. The
reason for these losses of signal is the destructive reason for these losses of signal is the destructive
interference that multiple reflected copies of the interference that multiple reflected copies of the
signal make with itself. To understand how a signal make with itself. To understand how a
signal can destructively interfere with itself, signal can destructively interfere with itself,
consider the sum of two consider the sum of two sinusoidalsinusoidal waveforms waveforms
(which are similar to modulated carrier signals) (which are similar to modulated carrier signals)
with different phases. with different phases.
For example, consider the common experience of For example, consider the common experience of
stopping at traffic lights and hearing a lot of static stopping at traffic lights and hearing a lot of static
on your FM broadcast radio, which is immediately on your FM broadcast radio, which is immediately
corrected if you move less than a meter. Cellular corrected if you move less than a meter. Cellular
phones also exhibit similar momentary fades. The phones also exhibit similar momentary fades. The
reason for these losses of signal is the destructive reason for these losses of signal is the destructive
interference that multiple reflected copies of the interference that multiple reflected copies of the
signal make with itself. To understand how a signal make with itself. To understand how a
signal can destructively interfere with itself, signal can destructively interfere with itself,
consider the sum of two consider the sum of two sinusoidalsinusoidal waveforms waveforms
(which are similar to modulated carrier signals) (which are similar to modulated carrier signals)
with different phases. with different phases.
FADING IN WIRELESS COMMUNICATIONSFADING IN WIRELESS COMMUNICATIONS
In wireless communications, signal fading is In wireless communications, signal fading is
caused by multi-path effect. Multi-path effect caused by multi-path effect. Multi-path effect
means that a signal transmitted from a means that a signal transmitted from a
transmitter may have multiple copies traversing transmitter may have multiple copies traversing
different paths to reach a receiver. different paths to reach a receiver.
At the receiver, the received signal should be the At the receiver, the received signal should be the
sum of all these multi-path signals. Because the sum of all these multi-path signals. Because the
paths traversed by these signals are different; paths traversed by these signals are different;
some are longer and some are shorter. some are longer and some are shorter.
The one at the direction of light of signal (LOS) The one at the direction of light of signal (LOS)
should be the shortest. These signals interact should be the shortest. These signals interact
with each other. If signals are in phase, they with each other. If signals are in phase, they
would intensify the resultant signal; otherwise, would intensify the resultant signal; otherwise,
the resultant signal is weakened due to out of the resultant signal is weakened due to out of
phase. This phenomenon is called channel fading. phase. This phenomenon is called channel fading.
In wireless communications, signal fading is In wireless communications, signal fading is
caused by multi-path effect. Multi-path effect caused by multi-path effect. Multi-path effect
means that a signal transmitted from a means that a signal transmitted from a
transmitter may have multiple copies traversing transmitter may have multiple copies traversing
different paths to reach a receiver. different paths to reach a receiver.
At the receiver, the received signal should be the At the receiver, the received signal should be the
sum of all these multi-path signals. Because the sum of all these multi-path signals. Because the
paths traversed by these signals are different; paths traversed by these signals are different;
some are longer and some are shorter. some are longer and some are shorter.
The one at the direction of light of signal (LOS) The one at the direction of light of signal (LOS)
should be the shortest. These signals interact should be the shortest. These signals interact
with each other. If signals are in phase, they with each other. If signals are in phase, they
would intensify the resultant signal; otherwise, would intensify the resultant signal; otherwise,
the resultant signal is weakened due to out of the resultant signal is weakened due to out of
phase. This phenomenon is called channel fading. phase. This phenomenon is called channel fading.
SMALL SCALE MULTIPATH PROPAGATIONSMALL SCALE MULTIPATH PROPAGATION
Multipath in the radio channel creates small Multipath in the radio channel creates small
scale fading effects. The three most scale fading effects. The three most
important effects are :important effects are :
Rapid changes in signal strength over a Rapid changes in signal strength over a
small travel distance or time interval.small travel distance or time interval.
Random frequency distribution due to Random frequency distribution due to
varying Doppler shifts on different varying Doppler shifts on different
multipath signals.multipath signals.
Time dispersion (Echoes) caused by Time dispersion (Echoes) caused by
multipath propagation delays.multipath propagation delays.
Multipath in the radio channel creates small Multipath in the radio channel creates small
scale fading effects. The three most scale fading effects. The three most
important effects are :important effects are :
Rapid changes in signal strength over a Rapid changes in signal strength over a
small travel distance or time interval.small travel distance or time interval.
Random frequency distribution due to Random frequency distribution due to
varying Doppler shifts on different varying Doppler shifts on different
multipath signals.multipath signals.
Time dispersion (Echoes) caused by Time dispersion (Echoes) caused by
multipath propagation delays.multipath propagation delays.
FACTORS INFLUENCING SMALL SCALE FADINGFACTORS INFLUENCING SMALL SCALE FADING
Many physical factors in the radio propagation channel Many physical factors in the radio propagation channel
influence small-scale fading. These include the following :influence small-scale fading. These include the following :
(1) (1) Multipath PropagationMultipath Propagation : :
The presence of reflecting objects and scatters in the channel The presence of reflecting objects and scatters in the channel
creates a constantly changing environment that dissipates the signal creates a constantly changing environment that dissipates the signal
energy in amplitude, phase and time. These effects results in multiple energy in amplitude, phase and time. These effects results in multiple
versions of the transmitted signal that arrive at the receiving antenna, versions of the transmitted signal that arrive at the receiving antenna,
displaced with respect to one another in time and spatial orientation. displaced with respect to one another in time and spatial orientation.
The random phase and amplitude of the different multipath The random phase and amplitude of the different multipath
components caused fluctuations in signal strength, thereby inducing components caused fluctuations in signal strength, thereby inducing
Small scale fading, Signal distortion, or both. Multipath propagation Small scale fading, Signal distortion, or both. Multipath propagation
often lengthens the time required for the base band portion of the often lengthens the time required for the base band portion of the
signal to reach the receiver which can cause signal smearing due to signal to reach the receiver which can cause signal smearing due to
inter symbol interference. inter symbol interference.
(2) (2) Speed of the mobileSpeed of the mobile : :
The relative motion between the base station and the mobile The relative motion between the base station and the mobile
results in random frequency modulation due to different Doppler results in random frequency modulation due to different Doppler
Shifts on each of the multipath components. Doppler Shift will be Shifts on each of the multipath components. Doppler Shift will be
positive or negative depending on whether the mobile receiver is positive or negative depending on whether the mobile receiver is
moving towards or away from the base station. moving towards or away from the base station.
Many physical factors in the radio propagation channel Many physical factors in the radio propagation channel
influence small-scale fading. These include the following :influence small-scale fading. These include the following :
(1) (1) Multipath PropagationMultipath Propagation : :
The presence of reflecting objects and scatters in the channel The presence of reflecting objects and scatters in the channel
creates a constantly changing environment that dissipates the signal creates a constantly changing environment that dissipates the signal
energy in amplitude, phase and time. These effects results in multiple energy in amplitude, phase and time. These effects results in multiple
versions of the transmitted signal that arrive at the receiving antenna, versions of the transmitted signal that arrive at the receiving antenna,
displaced with respect to one another in time and spatial orientation. displaced with respect to one another in time and spatial orientation.
The random phase and amplitude of the different multipath The random phase and amplitude of the different multipath
components caused fluctuations in signal strength, thereby inducing components caused fluctuations in signal strength, thereby inducing
Small scale fading, Signal distortion, or both. Multipath propagation Small scale fading, Signal distortion, or both. Multipath propagation
often lengthens the time required for the base band portion of the often lengthens the time required for the base band portion of the
signal to reach the receiver which can cause signal smearing due to signal to reach the receiver which can cause signal smearing due to
inter symbol interference. inter symbol interference.
(2) (2) Speed of the mobileSpeed of the mobile : :
The relative motion between the base station and the mobile The relative motion between the base station and the mobile
results in random frequency modulation due to different Doppler results in random frequency modulation due to different Doppler
Shifts on each of the multipath components. Doppler Shift will be Shifts on each of the multipath components. Doppler Shift will be
positive or negative depending on whether the mobile receiver is positive or negative depending on whether the mobile receiver is
moving towards or away from the base station. moving towards or away from the base station.
(3) Speed of surrounding objects :
If objects in the radio channel are in motion, they induced a time
varying Doppler Shift on multipath components. If the surrounding
objects move at a greater rate than the mobile, then this effect
dominates the Small scale Fading. Otherwise, motion of surrounding
objects may be ignored and only the speed of the mobile need be
considered. The coherence time defines the “static ness” of the
channel, and is directly impacted by the Doppler shift.
(4) The transmission bandwidth of the signal :
If the transmitted radio signal bandwidth is greater than the
“bandwidth” of the multipath channel, the received signal will be
distorted, but the received signal strength will not fade much over a
local area (i.e., the small scale signal fading will not be significant). As
will be shown, the bandwidth of the channel can be quantified by the
coherence bandwidth which is related to the specific multipath structure
of the channel. The coherence bandwidth is a measure of the maximum
frequency difference for which signals are still strongly correlated in
amplitude. If the transmitted signal has a narrow bandwidth as
compared to the channel, the amplitude of the signal change rapidly,
but the signal will not be distorted in time.
If objects in the radio channel are in motion, they induced a time
varying Doppler Shift on multipath components. If the surrounding
objects move at a greater rate than the mobile, then this effect
dominates the Small scale Fading. Otherwise, motion of surrounding
objects may be ignored and only the speed of the mobile need be
considered. The coherence time defines the “static ness” of the
channel, and is directly impacted by the Doppler shift.
(4) The transmission bandwidth of the signal :
If the transmitted radio signal bandwidth is greater than the
“bandwidth” of the multipath channel, the received signal will be
distorted, but the received signal strength will not fade much over a
local area (i.e., the small scale signal fading will not be significant). As
will be shown, the bandwidth of the channel can be quantified by the
coherence bandwidth which is related to the specific multipath structure
of the channel. The coherence bandwidth is a measure of the maximum
frequency difference for which signals are still strongly correlated in
amplitude. If the transmitted signal has a narrow bandwidth as
compared to the channel, the amplitude of the signal change rapidly,
but the signal will not be distorted in time.
DOPPLER SHIFTDOPPLER SHIFT
Consider a mobile moving at a Consider a mobile moving at a
constant velocity constant velocity vv, along a path , along a path
segment having length segment having length dd between between
points X and Y, while it receives points X and Y, while it receives
signals from a remote source as signals from a remote source as
illustrated in Fig (1) in previous slide :illustrated in Fig (1) in previous slide :
The difference in path length traveled The difference in path length traveled
by the wave from source S to the by the wave from source S to the
mobile at points X and Y is mobile at points X and Y is
∆∆l = dcosθ = v∆tcosθ l = dcosθ = v∆tcosθ
constant velocity constant velocity vv, along a path , along a path
segment having length segment having length dd between between
points X and Y, while it receives points X and Y, while it receives
signals from a remote source as signals from a remote source as
illustrated in Fig (1) in previous slide :illustrated in Fig (1) in previous slide :
The difference in path length traveled The difference in path length traveled
by the wave from source S to the by the wave from source S to the
mobile at points X and Y is mobile at points X and Y is
∆∆l = dcosθ = v∆tcosθ l = dcosθ = v∆tcosθ
The phase change in received signal The phase change in received signal
due to difference in path lengths is due to difference in path lengths is
therefore,therefore,
∆ ∆ Φ = Φ = 2 π ∆ 2 π ∆ l l = = 2 π v ∆ 2 π v ∆ tt cos θ cos θ
λ λ λ λ
and hence the apparent change in and hence the apparent change in
frequency or Doppler shift, is given frequency or Doppler shift, is given
by by fdfd, where, where
fd fd = = 1 1 . . ∆Φ∆Φ = = v v . cosθ. cosθ
2π ∆ t λ2π ∆ t λ
due to difference in path lengths is due to difference in path lengths is
therefore,therefore,
∆ ∆ Φ = Φ = 2 π ∆ 2 π ∆ l l = = 2 π v ∆ 2 π v ∆ tt cos θ cos θ
λ λ λ λ
and hence the apparent change in and hence the apparent change in
frequency or Doppler shift, is given frequency or Doppler shift, is given
by by fdfd, where, where
fd fd = = 1 1 . . ∆Φ∆Φ = = v v . cosθ. cosθ
2π ∆ t λ2π ∆ t λ
TYPES OF SMALL SCALE FADINGTYPES OF SMALL SCALE FADING
Fig. (2) : Types of small scale fading
Fig. (2) : Types of small scale fading
FLAT FADINGFLAT FADING
Flat fadingFlat fading, where the bandwidth of , where the bandwidth of
the signal is less than the the signal is less than the
coherence bandwidthcoherence bandwidth of the channel of the channel
or the or the delay spreaddelay spread is less than the is less than the
symbol periodsymbol period. .
Flat fadingFlat fading, where the bandwidth of , where the bandwidth of
the signal is less than the the signal is less than the
coherence bandwidthcoherence bandwidth of the channel of the channel
or the or the delay spreaddelay spread is less than the is less than the
symbol periodsymbol period. .
Fig. (3): Fig. (3): Flat Fading channel characteristicsFlat Fading channel characteristics
FREQUENCY SELECTIVE FADINGFREQUENCY SELECTIVE FADING
Frequency selective fadingFrequency selective fading , where , where
the bandwidth of the signal is greater the bandwidth of the signal is greater
than the coherence bandwidth of the than the coherence bandwidth of the
channel or the delay spread is channel or the delay spread is
greater than the symbol period. greater than the symbol period.
Frequency selective fadingFrequency selective fading , where , where
the bandwidth of the signal is greater the bandwidth of the signal is greater
than the coherence bandwidth of the than the coherence bandwidth of the
channel or the delay spread is channel or the delay spread is
greater than the symbol period. greater than the symbol period.
Fig. (4) : Fig. (4) : Frequency selective fading channel characteristicsFrequency selective fading channel characteristics
FADING EFFECT DUE TO DOPPLER SPREADFADING EFFECT DUE TO DOPPLER SPREAD
Due to Doppler Effect, if a transmitter is Due to Doppler Effect, if a transmitter is
moving away from a receiver, the moving away from a receiver, the
frequency of the received signal is lower frequency of the received signal is lower
than the one sent out from the transmitter; than the one sent out from the transmitter;
otherwise, the frequency is increased. otherwise, the frequency is increased.
In wireless communications, there are In wireless communications, there are
many factors that can cause relative many factors that can cause relative
movement between a transmitter and a movement between a transmitter and a
receiver. receiver.
It can be the movement of a mobile such It can be the movement of a mobile such
as a cell phone. as a cell phone.
It can be the movement of some It can be the movement of some
background objectives, which causes the background objectives, which causes the
change of path length between the change of path length between the
transmitter and the receiver. transmitter and the receiver.
Due to Doppler Effect, if a transmitter is Due to Doppler Effect, if a transmitter is
moving away from a receiver, the moving away from a receiver, the
frequency of the received signal is lower frequency of the received signal is lower
than the one sent out from the transmitter; than the one sent out from the transmitter;
otherwise, the frequency is increased. otherwise, the frequency is increased.
In wireless communications, there are In wireless communications, there are
many factors that can cause relative many factors that can cause relative
movement between a transmitter and a movement between a transmitter and a
receiver. receiver.
It can be the movement of a mobile such It can be the movement of a mobile such
as a cell phone. as a cell phone.
It can be the movement of some It can be the movement of some
background objectives, which causes the background objectives, which causes the
change of path length between the change of path length between the
transmitter and the receiver. transmitter and the receiver.
FASTFAST FADINGFADING
Fast FadingFast Fading is a kind of fading occurring with small is a kind of fading occurring with small
movements of a mobile or obstacle. movements of a mobile or obstacle.
Depending upon how rapidly the transmitted base band Depending upon how rapidly the transmitted base band
signal changes as compared to the rate of change of the signal changes as compared to the rate of change of the
channel.channel.
The channel may be classified either as a The channel may be classified either as a Flat fadingFlat fading or or
Slow fadingSlow fading channel. channel.
In a In a Fast fadingFast fading channel, the impulse response changes channel, the impulse response changes
rapidly within the symbol duration. That is, the coherence rapidly within the symbol duration. That is, the coherence
time of the channel is smaller than the symbol period of the time of the channel is smaller than the symbol period of the
transmitted signal. This causes frequency dispersion (also transmitted signal. This causes frequency dispersion (also
called the selective fading) due to Doppler spreading, which called the selective fading) due to Doppler spreading, which
leads to signal distortion. leads to signal distortion.
Fast FadingFast Fading is a kind of fading occurring with small is a kind of fading occurring with small
movements of a mobile or obstacle. movements of a mobile or obstacle.
Depending upon how rapidly the transmitted base band Depending upon how rapidly the transmitted base band
signal changes as compared to the rate of change of the signal changes as compared to the rate of change of the
channel.channel.
The channel may be classified either as a The channel may be classified either as a Flat fadingFlat fading or or
Slow fadingSlow fading channel. channel.
In a In a Fast fadingFast fading channel, the impulse response changes channel, the impulse response changes
rapidly within the symbol duration. That is, the coherence rapidly within the symbol duration. That is, the coherence
time of the channel is smaller than the symbol period of the time of the channel is smaller than the symbol period of the
transmitted signal. This causes frequency dispersion (also transmitted signal. This causes frequency dispersion (also
called the selective fading) due to Doppler spreading, which called the selective fading) due to Doppler spreading, which
leads to signal distortion. leads to signal distortion.
SLOWSLOW FADINGFADING
Slow Fading Slow Fading is a kind of fading caused by larger is a kind of fading caused by larger
movements of a mobile or obstructions within the movements of a mobile or obstructions within the
propagation environment. This is often modeled propagation environment. This is often modeled
as as log-normal distributionlog-normal distribution with a standard with a standard
deviation according to the deviation according to the
Log Distance Path Loss ModelLog Distance Path Loss Model..
In a slow fading channel, the channel impulse In a slow fading channel, the channel impulse
response changes at a rate much slower than the response changes at a rate much slower than the
transmitted base band signal s(t). In this case, transmitted base band signal s(t). In this case,
channel may be assumed to be static over one or channel may be assumed to be static over one or
several reciprocal bandwidth intervals. several reciprocal bandwidth intervals.
Slow Fading Slow Fading is a kind of fading caused by larger is a kind of fading caused by larger
movements of a mobile or obstructions within the movements of a mobile or obstructions within the
propagation environment. This is often modeled propagation environment. This is often modeled
as as log-normal distributionlog-normal distribution with a standard with a standard
deviation according to the deviation according to the
Log Distance Path Loss ModelLog Distance Path Loss Model..
In a slow fading channel, the channel impulse In a slow fading channel, the channel impulse
response changes at a rate much slower than the response changes at a rate much slower than the
transmitted base band signal s(t). In this case, transmitted base band signal s(t). In this case,
channel may be assumed to be static over one or channel may be assumed to be static over one or
several reciprocal bandwidth intervals. several reciprocal bandwidth intervals.
Fig. (5) : Type of fading experienced by a signal as a functionFig. (5) : Type of fading experienced by a signal as a function
(a) Symbol period(a) Symbol period (b) Base band signal bandwidth (b) Base band signal bandwidth
(a) Symbol period(a) Symbol period (b) Base band signal bandwidth (b) Base band signal bandwidth
STATISTICAL MODELS FOR MULTIPATH STATISTICAL MODELS FOR MULTIPATH
FADING CHANNELSFADING CHANNELS
Several multipath models have been suggested to Several multipath models have been suggested to
explain the observed statistical nature of a mobile explain the observed statistical nature of a mobile
channel. channel.
The first model presented by ossana was based on The first model presented by ossana was based on
interference of waves incident and reflected from the interference of waves incident and reflected from the
flat sides of randomly located buildings. flat sides of randomly located buildings.
Ossana’s model is therefore rather inflexible and Ossana’s model is therefore rather inflexible and
inappropriate for urban areas where the direct path is inappropriate for urban areas where the direct path is
almost always blocked by buildings or other obstacles. almost always blocked by buildings or other obstacles.
Clarke’s model is based on scattering and is widely Clarke’s model is based on scattering and is widely
used.used.
FADING CHANNELSFADING CHANNELS
Several multipath models have been suggested to Several multipath models have been suggested to
explain the observed statistical nature of a mobile explain the observed statistical nature of a mobile
channel. channel.
The first model presented by ossana was based on The first model presented by ossana was based on
interference of waves incident and reflected from the interference of waves incident and reflected from the
flat sides of randomly located buildings. flat sides of randomly located buildings.
Ossana’s model is therefore rather inflexible and Ossana’s model is therefore rather inflexible and
inappropriate for urban areas where the direct path is inappropriate for urban areas where the direct path is
almost always blocked by buildings or other obstacles. almost always blocked by buildings or other obstacles.
Clarke’s model is based on scattering and is widely Clarke’s model is based on scattering and is widely
used.used.
CLARKE’S MODELCLARKE’S MODEL
Clarke developed a model where the statistical Clarke developed a model where the statistical
characteristics of the electromagnetic fields of the characteristics of the electromagnetic fields of the
received signals of the mobile are deduced from received signals of the mobile are deduced from
scattering. scattering.
The model assumes a fixed transmitter with a The model assumes a fixed transmitter with a
vertically polarized antenna. The field incident on the vertically polarized antenna. The field incident on the
mobile antenna is assumed to be comprised of N mobile antenna is assumed to be comprised of N
azimuthal plane waves with arbitrary carrier phases, azimuthal plane waves with arbitrary carrier phases,
arbitrary azimuthal angles of arrival, and each wave arbitrary azimuthal angles of arrival, and each wave
having equal average amplitude. having equal average amplitude.
It should be noted that the equal average amplitude It should be noted that the equal average amplitude
assumption is based on the fact that in the absence of assumption is based on the fact that in the absence of
a direct line-of-sight path, the scattered arriving at a a direct line-of-sight path, the scattered arriving at a
receiver will experience similar attenuation over small-receiver will experience similar attenuation over small-
scale distances. scale distances.
Clarke developed a model where the statistical Clarke developed a model where the statistical
characteristics of the electromagnetic fields of the characteristics of the electromagnetic fields of the
received signals of the mobile are deduced from received signals of the mobile are deduced from
scattering. scattering.
The model assumes a fixed transmitter with a The model assumes a fixed transmitter with a
vertically polarized antenna. The field incident on the vertically polarized antenna. The field incident on the
mobile antenna is assumed to be comprised of N mobile antenna is assumed to be comprised of N
azimuthal plane waves with arbitrary carrier phases, azimuthal plane waves with arbitrary carrier phases,
arbitrary azimuthal angles of arrival, and each wave arbitrary azimuthal angles of arrival, and each wave
having equal average amplitude. having equal average amplitude.
It should be noted that the equal average amplitude It should be noted that the equal average amplitude
assumption is based on the fact that in the absence of assumption is based on the fact that in the absence of
a direct line-of-sight path, the scattered arriving at a a direct line-of-sight path, the scattered arriving at a
receiver will experience similar attenuation over small-receiver will experience similar attenuation over small-
scale distances. scale distances.
TWO-RAY RAYLEIGH FADING MODELTWO-RAY RAYLEIGH FADING MODEL
Clarke’s model and the statistics for Rayleigh Clarke’s model and the statistics for Rayleigh
fading are for that fading conditions and do not fading are for that fading conditions and do not
consider multipath time delay. consider multipath time delay.
In modern mobile communication systems with In modern mobile communication systems with
high data rates, it has become necessary to high data rates, it has become necessary to
model the effects of multipath delay spread as model the effects of multipath delay spread as
well as fading. well as fading.
A commonly used multipath model is an A commonly used multipath model is an
independent Rayleigh fading two-ray model independent Rayleigh fading two-ray model
(which is a specific implementation of the (which is a specific implementation of the
generic fading simulator shown in figure generic fading simulator shown in figure
below). below).
Clarke’s model and the statistics for Rayleigh Clarke’s model and the statistics for Rayleigh
fading are for that fading conditions and do not fading are for that fading conditions and do not
consider multipath time delay. consider multipath time delay.
In modern mobile communication systems with In modern mobile communication systems with
high data rates, it has become necessary to high data rates, it has become necessary to
model the effects of multipath delay spread as model the effects of multipath delay spread as
well as fading. well as fading.
A commonly used multipath model is an A commonly used multipath model is an
independent Rayleigh fading two-ray model independent Rayleigh fading two-ray model
(which is a specific implementation of the (which is a specific implementation of the
generic fading simulator shown in figure generic fading simulator shown in figure
below). below).
The figure shows a block diagram of the two-ray The figure shows a block diagram of the two-ray
independent Rayleigh fading channel model.independent Rayleigh fading channel model.
INPUTINPUT OUTPUTOUTPUT
independent Rayleigh fading channel model.independent Rayleigh fading channel model.
INPUTINPUT OUTPUTOUTPUT
SALEH AND VALENZUELA INDOOR STATISTICAL MODEL
Saleh and Valenzuela reported the results of Saleh and Valenzuela reported the results of
indoor propagation measurements between two indoor propagation measurements between two
vertically polarized omni directional antennas vertically polarized omni directional antennas
located on the same floor of a medium sized located on the same floor of a medium sized
office building. Measurements were made using office building. Measurements were made using
10 ns, 1.5 GHz, radar-like pulses. 10 ns, 1.5 GHz, radar-like pulses.
The method involved averaging the square law The method involved averaging the square law
detected pulse response while sweeping the detected pulse response while sweeping the
frequency of the transmitted pulse. Using this frequency of the transmitted pulse. Using this
method, multipath components within 5 ns were method, multipath components within 5 ns were
resolvable.resolvable.
Saleh and Valenzuela reported the results of Saleh and Valenzuela reported the results of
indoor propagation measurements between two indoor propagation measurements between two
vertically polarized omni directional antennas vertically polarized omni directional antennas
located on the same floor of a medium sized located on the same floor of a medium sized
office building. Measurements were made using office building. Measurements were made using
10 ns, 1.5 GHz, radar-like pulses. 10 ns, 1.5 GHz, radar-like pulses.
The method involved averaging the square law The method involved averaging the square law
detected pulse response while sweeping the detected pulse response while sweeping the
frequency of the transmitted pulse. Using this frequency of the transmitted pulse. Using this
method, multipath components within 5 ns were method, multipath components within 5 ns were
resolvable.resolvable.
SIRCIM AND SMRCIM INDOOR AND OUTDOOR SIRCIM AND SMRCIM INDOOR AND OUTDOOR
STATISTICAL MODELSSTATISTICAL MODELS
Rappaport and Seidel reported measurement at 1300 MHz in five Rappaport and Seidel reported measurement at 1300 MHz in five
factory buildings and carried out subsequent measurements in factory buildings and carried out subsequent measurements in
other types of buildings. The authors developed an elaborate, other types of buildings. The authors developed an elaborate,
empirically derived statistical model to generate measured empirically derived statistical model to generate measured
channels based on the discrete impulse response channel model channels based on the discrete impulse response channel model
and wrote a computer program called and wrote a computer program called SIRCIM (simulation of SIRCIM (simulation of
indoor radio channel impulse-response models)indoor radio channel impulse-response models) . .
SIRCIM generates realistic samples of small-scale indoor channel SIRCIM generates realistic samples of small-scale indoor channel
impulse response measurements. Subsequent work by Huang impulse response measurements. Subsequent work by Huang
produced produced SMRCIM (simulation of mobile radio channel SMRCIM (simulation of mobile radio channel
impulse response models)impulse response models) , a similar program that generates , a similar program that generates
small-scale urban cellular and microcellular channel impulse small-scale urban cellular and microcellular channel impulse
responses. responses.
These programs are currently in use at over 100 institutions These programs are currently in use at over 100 institutions
throughout the world, and have been updated to include angle of throughout the world, and have been updated to include angle of
arrival information for micro cell, indoor, and macro cell channels. arrival information for micro cell, indoor, and macro cell channels.
STATISTICAL MODELSSTATISTICAL MODELS
Rappaport and Seidel reported measurement at 1300 MHz in five Rappaport and Seidel reported measurement at 1300 MHz in five
factory buildings and carried out subsequent measurements in factory buildings and carried out subsequent measurements in
other types of buildings. The authors developed an elaborate, other types of buildings. The authors developed an elaborate,
empirically derived statistical model to generate measured empirically derived statistical model to generate measured
channels based on the discrete impulse response channel model channels based on the discrete impulse response channel model
and wrote a computer program called and wrote a computer program called SIRCIM (simulation of SIRCIM (simulation of
indoor radio channel impulse-response models)indoor radio channel impulse-response models) . .
SIRCIM generates realistic samples of small-scale indoor channel SIRCIM generates realistic samples of small-scale indoor channel
impulse response measurements. Subsequent work by Huang impulse response measurements. Subsequent work by Huang
produced produced SMRCIM (simulation of mobile radio channel SMRCIM (simulation of mobile radio channel
impulse response models)impulse response models) , a similar program that generates , a similar program that generates
small-scale urban cellular and microcellular channel impulse small-scale urban cellular and microcellular channel impulse
responses. responses.
These programs are currently in use at over 100 institutions These programs are currently in use at over 100 institutions
throughout the world, and have been updated to include angle of throughout the world, and have been updated to include angle of
arrival information for micro cell, indoor, and macro cell channels. arrival information for micro cell, indoor, and macro cell channels.
REFERENCESREFERENCES
Wireless Communication Wireless Communication
(T. S. RAPPAPORT, EEE Pub.)(T. S. RAPPAPORT, EEE Pub.)
Wikipedia, the free encyclopediaWikipedia, the free encyclopedia
Google.co.inGoogle.co.in
Wireless Communication Wireless Communication
(T. S. RAPPAPORT, EEE Pub.)(T. S. RAPPAPORT, EEE Pub.)
Wikipedia, the free encyclopediaWikipedia, the free encyclopedia
Google.co.inGoogle.co.in
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