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TRANSCRIPT
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Lecture 3
� Signal Propagation Overview
� Path Loss Models● Free-space Path Loss● Ray Tracing Models● Simplified Path Loss Model● Empirical Models● Empirical Models
� Log Normal Shadowing
� Combined Path Loss and Shadowing
�Outage Probability
�Model Parameters are Obtained from Empirical Measurements
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Propagation Characteristics
� Path Loss (includes average shadowing)
� Shadowing (due to obstructions)
� Multipath Fading� Multipath Fading
Pr/Pt
d=vt
PrPt
d=vt
v Very slow
SlowFast
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Lecture 3
� Signal Propagation Overview
� Path Loss Models● Free-space Path Loss● Ray Tracing Models● Simplified Path Loss Model● Empirical Models● Empirical Models
� Log Normal Shadowing
� Combined Path Loss and Shadowing
�Outage Probability
�Model Parameters are Obtained from Empirical Measurements
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Path Loss Modeling
� Maxwell’s equations� Complex and impractical
� Free space path loss model� Too simple� Too simple
� Ray tracing models�Requires site-specific information
� Empirical Models�Don’t always generalize to other environments
� Simplified power falloff models�Main characteristics: good for high-level analysis
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� Linear path loss
� Path loss in dB
� The dB path gain
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Transmit signal
� The transmitted signal
u(t): complex baseband signal
fc: carrier frequency
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Free-Space Path Loss
� The received signal
where the product of the transmit and
receive antenna field radiation patterns in
the LOS direction.
LOS: Line-Of-Sight
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Free-Space Path Loss
� The ratio between the power of the
received signal and the power of transmit
signal issignal is
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Free-Space Path Loss
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Free-Space Path Loss
d=vt
� Path loss for unobstructed LOS path
� Power falls off :
� Proportional to d2
� Inversely proportional to λλλλ2 (proportional to f2)
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Ray Tracing Approximation
� Represent wavefronts as simple particles
� Geometry determines received signal from each signal componenteach signal component
� Typically includes reflected rays, can also include scattered and defracted rays.
� Requires site parameters
�Geometry
�Dielectric properties
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Two Path Model
� Path loss for one LOS path and 1 ground (or reflected) bouncereflected) bounce
� Ground bounce approximately cancels LOS path above critical distance
� Power falls off
� Proportional to d2 (small d)
� Proportional to d4 (d>dc) (dc: critical distance)
� Independent of λ λ λ λ (f)
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Two Path Model
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General Ray Tracing
� Models all signal components
�Reflections
� Scattering� Scattering
�Diffraction
� Requires detailed geometry and dielectric properties of site� Similar to Maxwell, but easier math.
� Computer packages often used
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Simplified Path Loss Model
� Used when path loss dominated by reflections.
� Most important parameter is the path loss exponent γγγγ, determined empirically.
82,0 ≤≤
= γγ
d
dKPP tr
Most important parameter is the path loss exponent γγγγ, determined empirically.
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Empirical Models
� Okumura model� Empirically based (site/freq specific)
� Awkward (uses graphs)
� L(fc, d): free space path loss at distance d
� Carrier frequency fc
� Amu(fc, d): median attenuation
�G(ht) base station antenna height gain factor
�G(hr) mobile antenna height gain factor
�GAREA: gain due to the type of environment
Commonly used in cellular system simulations
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Empirical Models
� Hata model� Analytical approximation to Okumura model
� COST 231 Model: � Extends Hata model to higher frequency (2 GHz)
Commonly used in cellular system simulations
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Empirical Models
� Indoor
� FAF: floor attenuation factorFAF: floor attenuation factor
� PAF: partition attenuation factor
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Bài tập
� Under a free space path loss model, find
the transmit power required to obtain a
received power of 1 dBm for a wireless received power of 1 dBm for a wireless
system with isotropic antennas (Gl = 1)
and a carrier frequency f = 5 GHz,
assuming a distance d = 10m. Repeat for d
= 100m
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Lecture 3
� Signal Propagation Overview
� Path Loss Models● Free-space Path Loss● Ray Tracing Models● Simplified Path Loss Model● Empirical Models● Empirical Models
� Log Normal Shadowing
� Combined Path Loss and Shadowing
�Outage Probability
�Model Parameters are Obtained from Empirical Measurements
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Shadowing
� Models attenuation from obstructionsXc
� Random due to random # and type of obstructions
� Typically follows a log-normal distribution
� dB value of power is normally distributed
� µµµµ=0 (if mean captured in path loss), 4 dB < σσσσ2 < 12 dB (empirical)
� CLT (Central Limit Theorem) used to explain this
model
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Shadowing
Xc
� The probability
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Lecture 3
� Signal Propagation Overview
� Path Loss Models● Free-space Path Loss● Ray Tracing Models● Simplified Path Loss Model● Empirical Models● Empirical Models
� Log Normal Shadowing
� Combined Path Loss and Shadowing
�Outage Probability
�Model Parameters are Obtained from Empirical Measurements
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Combined Path Loss and Shadowing
� Linear Model: ψψψψ lognormal
ψγ
=d
dK
P
P
t
r 0 Slow10logΚΚΚΚ
� dB Model
dPt
),0(~
,log10log10)(
2
01010
ψσψ
ψγ
N
d
dKdB
P
P
dB
dBt
r +
−=
Pr/Pt (dB)
log d
Very slow
-10γγγγ
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Lecture 3
� Signal Propagation Overview
� Path Loss Models● Free-space Path Loss● Ray Tracing Models● Simplified Path Loss Model● Empirical Models● Empirical Models
� Log Normal Shadowing
� Combined Path Loss and Shadowing
�Outage Probability
�Model Parameters are Obtained from Empirical Measurements
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Outage Probability
� Path loss: circular cells
� Path loss+shadowing: amoeba cells� Tradeoff between coverage and interference
rP
� Outage probability� Probability that received power is below a given minimum
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Lecture 3
� Signal Propagation Overview
� Path Loss Models● Free-space Path Loss● Ray Tracing Models● Simplified Path Loss Model● Empirical Models● Empirical Models
� Log Normal Shadowing
� Combined Path Loss and Shadowing
�Outage Probability
�Model Parameters are Obtained from Empirical Measurements
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Model Parameters fromEmpirical Measurements
� Fit model to data
� Path loss (K,γγγγ), d0 known:� “Best fit” line through dB data
Pr/Pt(dB)
log(d)10γγγγ
K (dB)
log(d0)
σσσσψψψψ2
� “Best fit” line through dB data� K obtained from measurements at d0.
�Exponent is MMSE (Minimum Mean Square Error) estimate based on data
� Captures mean due to shadowing
� Shadowing variance� Variance of data relative to path loss model (straight line) with MMSE estimate for γγγγ
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Main Points
� Path loss models simplify Maxwell’s equations
� Models vary in complexity and accuracy
� Power falloff with distance is proportional to d2 � Power falloff with distance is proportional to d2
in free space, d4 in two path model
� General ray tracing computationally complex
� Empirical models used in 2G simulations
� Main characteristics of path loss captured in
simple model Pr=PtK[d0/d]γγγγ
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Main Points
� Random attenuation due to shadowing modeled as log-normal (empirical parameters)
� Shadowing decorrelates over decorrelation distance
� Combined path loss and shadowing leads to outage and amoeba-like cell shapes
� Path loss and shadowing parameters are obtained from empirical measurements