Transcript
8/11/2019 Channel in Digital communication
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Mobile Radio Propagation:
Fading and Multipath
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Large scale propagation effectsPath loss (function of distance)Shadowing (obstacle between Tx and Rx)
Small scale propagation effectsMultipath (short distance ~ signal
wavelength)
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Simplified path loss model:
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Log-normal shadowing: isassumed random with log-normal distribution (basedon LLN applied to many attenuating objects) :
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Combined Path Loss and Shadowing
),(~,log10log10)( 2
01010 N d
d
K dB P
P dBdB
t
r
=0 when average shadowing incorporated into K and , else <0
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Model Parameters fromEmpirical Measurements
Fit model to data
Path loss (K, ), d 0 known:“Best fit” line through dB data K obtained from measurements at d 0.Exponent is MMSE estimate based on data
Captures mean due to shadowingShadowing variance
Variance of data relative to path loss model
(straight line) with MMSE estimate for
P r (dB)
log(d)10
K (dB)
log(d 0)
2
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Small-Scale Multipath Propagation
The three most important effectsRapid changes in signal strength over a small travel distance or timeintervalRandom frequency modulation due to varying Doppler shifts on
different multipath signals Time dispersion caused by multipath propagation delays
Factors influencing small-scale fadingMultipath propagation: reflection objects and scattersSpeed of the mobile: Doppler shiftsSpeed of surrounding objects
Transmission bandwidth of the signal The received signal will be distorted if the transmission bandwidth isgreater than the bandwidth of the multipath channel.Coherent bandwidth: bandwidth of the multipath channel.
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Statistical Multipath Model
Random # of multipath components, each withRandom amplitudeRandom phaseRandom Doppler shiftRandom delay
Random components change with time
Leads to time-varying channel impulse response
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Time Varying Impulse Response
Response of channel at t to impulse at t- t :
t is time when impulse response is observed
t-t is time when impulse put into the channelt is how long ago impulse was put into the
channel for the current observation path delay for MP component currently observed
))(()(),(1
)( t e t t c n
N
n
t j n
n t t t
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Received Signal Characteristics
Received signal consists of many multipathcomponents
Amplitudes change slowlyPhases change rapidly
Constructive and destructive addition of signal
components Amplitude fading of received signal (both wideband and narrowband signals)
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Narrowband Model
Assume delay spread max m,n | t n (t)- t m (t) | <<1/B
Then u(t) u(t- t ).
Received signal given by
No signal distortion (spreading in time)Multipath affects complex scale factor in brackets.
Characterize scale factor by setting u(t)=e j 0
)(
0
)(2 )()()(t N
n
t jn
t f j nc et et ut r f
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In-Phase and Quadratureunder CLT Approximation
In phase and quadrature signal components:
For N(t) large, r I(t) and r Q(t) jointly Gaussian byCLT (sum of large # of random vars).
Received signal characterized by its mean,autocorrelation, and cross correlation.
If n (t) uniform, the in-phase/quad components are
mean zero, indep., and stationary.
),2cos()()()(
0
)( t f et t r c
t N
n
t jn I
n f
)2sin()()()(
0
)( t f et t r c
t N
n
t jnQ
n f
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Auto and Cross Correlation(Section 3.2.1)
Assume n~U[0,2 ]Recall that qn is the multipath arrival angle
Autocorrelation of inphase/quad signal is
Cross Correlation of inphase/quad signal is
Autocorrelation of received signal is
q t t t q /cos],2[cos)()( n D Dr r v f f PE A AnnnQ I
)(]2[sin)( ,, t t t q Q I nnQ I r r Dr r A f PE A
)2sin()()2cos()()(,
t t t t t cr r cr r
f A f A AQ I I
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Envelope and Power Distributions
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Main PointsPath loss and shadowing parameters are obtainedfrom empirical measurements
Statistical multipath model leads to a time-varyingchannel impulse response
Narrowband model has in-phase and quad. compsthat are zero-mean stationary Gaussian processes Auto and cross correlation depends on AOAs of multipath
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