Sumber : D ata and Computer Communications Eighth Edition William Stallings
Channel Modeling and Characteristics · " Good for satellite communications ... Theodore S....
Transcript of Channel Modeling and Characteristics · " Good for satellite communications ... Theodore S....
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Channel Modeling and Characteristics
Dr. Farid Farahmand Updated:10/15/13, 10/20/14
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Line-of-Sight Transmission (LOS) Impairments o The received signal is different from the transmitted
signal due to transmission impairments o Most significant impairments
n Thermal noise n Free space loss
o Attenuation and attenuation distortion n Atmospheric absorption
o water vapor and oxygen contribute to attenuation n Noise n Shadowing
o due to reflection and diffraction n Multipath and fading
o due to reflection, scattering, and diffraction n Refraction
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Review - Categories of Noise o Thermal Noise o Intermodulation noise o Crosstalk o Impulse Noise
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Other Types of Noise - Example Intermodulation noise (Diff. signals sharing the Same medium)
Crosstalk (coupling)
Impulse noise
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The Effects of Multipath Propagation o Multiple copies of a signal may arrive at different phases
n obstacles reflect signals so that multiple copies with varying delays are received
n If phases add destructively, the signal level relative to noise declines, making detection more difficult
o Intersymbol interference (ISI) n Direct result of multipathà One or more delayed copies of a pulse
may arrive at the same time as the primary pulse for a subsequent bit
Each arrive with diff. delay!
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Fading
Fading
Reflection S>>λ
Contact with large surface Large surfaceà φ shift à
cancellation Interference
(major issue for LOS)
Diffraction S>>λ
Cause by knife-edge The smoother the edge more loss
Prop. In different directions Bouncing off the edge
Scattering S<=λ
Scattering into several weaker signal
o Time variation of received signal due to multiple paths n Atmosphere changes n Moving antennas
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Propagation Mechanism (1) Reflection o Occurs when signal encounters a surface
that is large relative to the wavelength of the signal n Generally flat surface n Examples: Building, walls, Earth surface n The surface can be dielectric or conductor n The reflected field is diminished
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Propagation Mechanism (2) Diffraction o Occurs at the edge of an impenetrable body
that is large compared to wavelength of radio wave
o Radio path is obstructed by a surface with sharp edges
o Secondary waves are generated
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Propagation Mechanism (3) Scattering o occurs when incoming signal hits an object
whose size is the order of the wavelength of the signal or less
o The flat surfaces can cause protuberance (projection)
o Surface can be rough or smooth o Example: foliage, street signs, etc.
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Different Propagation Mechanisms
Reflection
Diffraction
Scattering
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Impact of Fading
Line-of-Sight Pulse
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Impact of Fading o Beam bending o Ducting o Fast fading o Slow fading o Flat fading o Selective fading o Rayleigh fading o Rician fading
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Refraction bending of radio waves as they propagate through the atmosphere
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Refraction o Refraction – bending of
microwaves by the atmosphere n Velocity of electromagnetic
wave is a function of the density of the medium
n When wave changes medium, speed changes
n Wave bends at the boundary between mediums
Thin Air
Dense Air
Returning signal
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Remember: Reflection
Refraction
Diffraction
Refraction (bending by atmosphere)
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Shadowing and Multipath Impairments
Shadowing is large scale fading (slow; e.g. moving around a building)
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Fast and Slow Fading
Fast (small scale) and slow (large scale) fading Large scale fading is also called shadowing
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Path Loss Channel Models o Free space modes are limited
n Good for satellite communications n Assumes line-of-sight n P_received is proportional to 1/d^2
o Other more realistic models n The receiver is not moving n The receiver is moving
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Path Loss Channel Models - Assume Stationary Receiver
o Macroscopic Fading or large scale shadowing (fading) n The received power changes over as the
distance varies n Models include:
o 2-Ray; Statistical; Empirical
o Microscopic fading or small scale fading n The received power changes quickly n Models include:
o 2-Ray, statistical
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2-Ray Model (Earth Reflection) Assumptions
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2-Ray Propagation Model – Earth Reflection Model
See notes
E_TOT (V/m) = E_LOS + Eg
E_LOS
Using geometric optics; We assume d >> ht+ hr
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2-Ray Propagation Model – Earth Reflection Model
Rdir = (ht − hr)2 + d 2 ≈ d 1+(ht − hr)2
2d 2#
$%
&
'(
Rindir = (ht + hr)2 + d 2 ≈ d 1+(ht + hr)2
2d 2#
$%
&
'(
rdir (t) = Adir cos(2π fc (t − Rdir / c))rindir (t) = Aindir cos(2π fc (t − Rindir / c)+φind )r(t) = rdir (t)+rindir (t) = Acos(2π fct +φ)
What is A? A = 2Adir sin(2πhr ⋅ht)
dλ≈ 2Adir
(2πhr ⋅ht)dλ
Adir = A0 / d
Pr0 = A02 / 2 = PtGtGrλ
2
(4π )2Lsys→ A0
2 =2PtGtGrλ
2
(4π )2Lsys
Pr = A2 / 2 = 2A2dir(2πhr ⋅ht)
dλ
2
= 2 (2πhr ⋅ht)(dλ)2
2
×1d 2×2PtGtGrλ
2
(4π )2Lsys
Pr = PtGtGrhr2 ⋅ht2
Lsys⋅1d 4
Key assumptions: Aind and Adir are almost the same The angle of incident is about 180 deg. d>>ht.hr
Power at the receiver Path_ Loss = d 4
GtGrhr2 ⋅ht2
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A = 2Adir sin(2πhr ⋅ht)
dλ≈ 2Adir
(2πhr ⋅ht)dλ
Adir = A0 / d
Pr0 = A02 / 2 = PtGtGrλ
2
(4π )2Lsys→ A0
2 =2PtGtGrλ
2
(4π )2Lsys
Pr = A2 / 2 = 2A2dir(2πhr ⋅ht)
dλ
2
= 2 (2πhr ⋅ht)(dλ)2
2
×1d 2×2PtGtGrλ
2
(4π )2Lsys
Pr = PtGtGrhr2 ⋅ht2
Lsys⋅1d 4
2-Ray Propagation Model – Earth Reflection Model
Approximated Power at the receiver
Path_ Loss = d 4
GtGrhr2 ⋅ht2
Approximate to be à
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2-Ray Model (Earth Reflection) Example – A
See notes
d
H1 H2
Ht = 30 m Hr = 2 m Gr = 2 dB Gt = 6 dB F = 850 MHz Conductive Earth Lsys = 2 dB Using the 2-ray fading model find the RX power
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Propagation Modes o Radio wave reaches the receiver by
one of the three signal paths: n Sky-wave propagation n Direct-wave or Line-of-sight propagation n Ground-wave propagation
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Sky Wave Propagation
o Signal reflected from ionized layer of atmosphere (ionosphere) back down to earth n Ionosphere is a region of atmosphere that is
ionized (charged) n This region of atmosphere has free electrons à
different index of refraction o Signal can travel a number of hops, back and forth
between ionosphere and earth’s surface o Reflection effect caused by refraction (this is because the
signal bends and reflects back) o Examples
n Amateur radio n CB radio
Refracted (reflects due to bending)
Reflected
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Sky Wave Propagation o D-layer is close to earth (45-55 miles
altitude) n Absorbs RF (f>300MHz) – RF Sponge n For RF <300MHz D-layer ends the
signal (refraction) n Ionization fades at night n Highly ionized during day time
o It occupies denser atmosphere (electrons are denser)
o Absorbs most of the RF except the ones radiated with critical angle
Distant AM broadcast can be received much better at night!
D,E, F1, F2 layers; Each deal with RF In different ways!
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Sky Wave (Skip) Propagation
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Line-of-Sight Propagation o Transmitting and receiving antennas must be
within line-of-sight n Example: Satellite communication n Dominant for signals above 30 MHz; no reflection due
ionosphere à can be transmitted via LOS n For ground communication – antennas must be
within effective line-of-site o Note that microwaves are bent or refracted by the
atmosphere
Wave bending!! Pulled toward the earth
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Line-of-Sight Propagation o Requires tall antennas:
Note: The radius of the Earth is 3,960 statute miles. However, at LOS radio frequencies the effective Earth radius is 4/3x(3,960) miles à 4/3 is the adjustment factor K
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Line-of-Sight Equations
o Optical line of sight Max. distance between two Antennas for LOS when there is no obstacles o Effective, or radio, line of
sight (longer than optical)
hd 57.3=
hd Κ= 57.3
Bending downward – K>4/3
d = distance between antenna and horizon (km) h = antenna height (m) K = adjustment factor to account for refraction, rule of thumb K = 4/3
Bending upward – K< 4/3
Bending property à effective LOS
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Line-of-Sight Equations o Maximum distance between two
antennas for LOS propagation:
o h1 = height of antenna one o h2 = height of antenna two
( )2157.3 hh Κ+Κ
Antennas placed in higher towers can have better reception!
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What is the benefit of raising the antenna?
d
H1 H2
Transmitting Case 1: H2 = 0; H1 = 100 m K=4/3 Find d (maximum distance between the two antennas)
Case 2: Let d = 41 Km H2 = 10 m Find H1
( )2157.3 hh Κ+Κ
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Ground-wave propagation o Follows contour of the earth
n Thus, goes beyond the radio horizon limit n RF follows the curvature of the earth
o The dominant mode of propagation n waves are refracted (i.e., bent) gradually in an inverted U shape
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Ground-wave propagation o Can Propagate considerable distances o Does not penetrate the upper atmosphere o Frequencies up to 2 MHz
n Example: AM radio o Not impacted by weather conditions s!o much o Highly impacted by earth conductivity
n When traveling over Salt water (good conductive) à ground wave propagation is good
n When the ground is dry or rocky à wave propagation is bad
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Diffraction: Fresnel (Freh-Nel) o Fresnel discovered
electromagnetic waves (light and RF signals) can bend (diffract) as they travel long distance and hit objects (S>>WL)
o As a result of bending multiple signals along various paths can results n The paths vary n(WL)/2 n Out of phase signals à signal
cancelation! o In order to minimize out-of-phase
signals we need to make sure there is no obstacle within the first Fresnel (%60 or F1)
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Fresnel Zone
where, Fn = The nth Fresnel Zone radius in metres d1 = The distance of P from one end in metres d2 = The distance of P from the other end in metres λ = The wavelength of the transmitted signal in metres
F1=
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Fresnel-Kirchoff Diffraction Parameter (V) o Radio
v =α 2d1d2(d1 + d2 )λ
α = β +γObstacle (Knife-Edge)_
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Given the Fresnel Effect (v) We can figure out the loss
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EXAMPLE Assume f=1900à WL=1/3 m Find the loss due to diffraction from the Knife edge obstacle
v =α 2d1d2(d1 + d2 )λ
α = β +γ
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Fresnel Effect
C1
0.6xr1
Read: http://www.zytrax.com/tech/wireless/fresnel.htm
At mid-point (same height antenna)
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References o Black, Bruce A., et al. Introduction to wireless systems. Prentice Hall
PTR, 2008, Chapter 3 o Rappaport, Theodore S. Wireless communications: principles and
practice. Vol. 2. New Jersey: Prentice Hall PTR, 1996, Chapter 3 o Stallings, William. Wireless Communications & Networks, 2/E. Pearson
Education India, 2009, Chapter 5 o Leon W. Couch, Digital and Analog Communication Systems, Chapter
1-8