Z. Ghassemlooy Mobile Communications Part IV- Propagation Characteristics Multi-path Propagation - Fading Part IV- Propagation Characteristics Multi-path.

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1 Z. Ghassemlooy Mobile Communications Part IV- Propagation Characteristics Multi-path Propagation - Fading Part IV- Propagation Characteristics Multi-path Propagation - Fading Professor Z Ghassemlooy School of Computing, Engineering and Information Sciences, University of Northumbria U.K. http://soe.unn.ac.uk/ocr Professor Z Ghassemlooy School of Computing, Engineering and Information Sciences, University of Northumbria U.K. http://soe.unn.ac.uk/ocr

2 Z. Ghassemlooy Contents  Fading  Doppler Shift  Dispersion  Summary

3 Z. Ghassemlooy Fading  Is due to multipath propagation. With respect to a stationary base station, multipath propagation creates a stochastic standing wave pattern, through which the mobile station moves.  Caused by shadowing: when the propagation environment is changing significantly, but this fading is typically much slower than the multipath fading.  Modem design is affected mainly by the faster multipath fading, which can be normally assumed to be locally wide-sense stationary (WSS).

4 Z. Ghassemlooy Multipath Propagation - Fading Antenna a b y = a + b a & b are in phase a & b are out of phase by  Complete fading when 2  d/ = n , d is the path difference Diffracted wave Reflected wave No direct path a b Antenna b y = 0 a

5 Z. Ghassemlooy Multipath Propagation - contd. For a stationary mobile unit with no direct path, the received signal can be expressed as a sum of delayed components or in terms of phasor notation: A single pulse Pulse train Where: a i is the amplitude of the scattered signal, p(t) is the transmitted signal (pulse) shape,  i is the time taken by the pulse to reach the receiver, N is the number of different paths f c is the carrier frequency

6 Z. Ghassemlooy Fading - Types Slow (Long) Term 0 5 10152025 Distance ( ) Signal strength relative to 1uV (db) 0 10 20 30 Slow fading Fast fading Exact representation of fading characteristics is not possible, because of infinite number of situation. Exact representation of fading characteristics is not possible, because of infinite number of situation. Fast (Short) Term (Also known as Rayleigh fading)

7 Z. Ghassemlooy Fading - Slow (Long) Term  Slower variation in mean signal strength (distance 1-2 km)  Produced by movement over much longer distances  Caused by: - Terrain configuration (hill, flat area etc.): Results in local mean (long term fading) attenuation and fluctuation. - The built environment (rural and urban areas etc.), between base station and the mobile unit: Results in local mean attenuation

8 Z. Ghassemlooy Fading - Slow (Long) Term C. D. Charalambous et al Transmitter  n,1 Receiver  k,1  or  d  n,3  n,2  k,2  k,3  k,4 one subpath LOS path k path n Sr(t)Sr(t) path attenuation factor for the ith path Number of path

9 Z. Ghassemlooy Fading- Fast (Short) Term  Describes the constant amplitude fluctuations in the received signal as the mobile moves.  Caused by - multipath reflection of transmitted signal by local scatters (houses, building etc.) - random fluctuations in the received power  Observed over distances = /2  Signal variation up to 30 dB.  Is a frequency selective phenomenon.  Can be described using - Rayleigh statistics, (no line of sight). - Rician statistics, (line of sight).

10 Z. Ghassemlooy Fading- Fast (Short) Term - contd. A received signal amplitude is given as the sum of delayed components. In terms of phasor notation it is given as: Or In-phaseQuadrature

11 Z. Ghassemlooy Fading- Fast (Short) Term - contd. The phase  i can be assumed to be uniformly distributed in the range (0, 2  ), provided the locations of buildings etc. are completely random. For a large N, the amplitude of the received signal is: where X and Y are independent, identically distributed Gaussian random variables.

12 Z. Ghassemlooy Fading- Fast (Short) Term - contd. Rayleigh Exponential A or power P Probability density function The envelope of the received signal is: Which will be Rayleigh distributed: Assuming all components received have approximately the same power and that all are resulting from scattering. Where 0< r < ,   is variance of A (the total received power in the multipath signal).

13 Z. Ghassemlooy Ricean Fading If there is one direct component in addition to scattered components, the envelope received multipath is Ricean, where the impulse response has a non zero mean. Ricean distribution = Rayleigh signal + direct line of sight signal. The distribution is:  2 is the power of the line of sight signal and I 0 is a Bessel function of the first kind

14 Fading- Fast (Short) Term - contd.  The probability that the realization of the random variable has a value smaller than x is defined by the cumulative distribution function:  Applying it to the Rayleigh distribution  For small r Z. Ghassemlooy

15 Fast Fading – Cases 1: Stationary Mobile 5 4 2 1 3 6 44 55 22 11 33 66 v v Stationary t Field strength

16 Z. Ghassemlooy Fast Fading – Cases 1  The number of fading depends on: – Traffic flow – Distance between the mobile and moving cars  The received signal at the MU is:

17 Z. Ghassemlooy is additional relative delay (positive or negative)where and envelope Thus Fast Fading – Cases 1

18 18  1 (t 1 )  2 (t 2 ) Fast Fading – Cases 2  2 = d 2 /c  1 = d 1 /c

19 Z. Ghassemlooy Fast Fading – Cases 3: Non-stationary Mobile The received signal at the mobile is: Amplitude x = Vt Wave number =2  / Transmitting frequency V t Field strength Signal level No scattered signals 

20 Z. Ghassemlooy Fast Fading – Cases 3: Doppler Frequency A moving object causes the frequency of a received wave to change Substituting for  and x, the expression for the received signal is The Doppler frequency The received signal frequency

21 Z. Ghassemlooy Fast Fading – Cases 3: Doppler Frequency When  = 0 o (mobile moving away from the transmitter) When  = 90 o (I.e. mobile circling around) When  = 180 o (mobile moving towards the transmitter)

22 Z. Ghassemlooy Fast Fading – Cases 4: Moving MU + Stationary Scatterer x(t)x(t) Voltage Standing Wave Pattern V so(t)so(t) so(t)so(t) t = 0 t = round trip time MU

23 Z. Ghassemlooy and for q = 0 Incident signalReflected signal Fading with zero amplitude occurs when Fast Fading – Cases 4 Received signal at the MU:

24 Z. Ghassemlooy Fast Fading – Cases 5: Moving MU and Scatterers The resultant received signal is the sum of all the scattered waves from different angles q i depending upon the momentary attitude of the various scatterers.

25 Z. Ghassemlooy Channel Fading Effects Transmitting a short pulse over a (i) frequency-selective (time-spread) fading channel: (ii) time-selective (Doppler-spread) fading channel: t t TpTp T p + dt Transmitted Received tt TpTp TpTp Transmitted Received

26 Z. Ghassemlooy Effects of Doppler shifts  Bandwidth of the signal could increase or decrease leading to poor and/or missed reception.  The effect in time is coherence time variation and signal distortion –Coherence time: Time duration over which channel impulse response is invariant, and in which two signals have strong potential for amplitude correlation –Coherence time is expressed by: –where f D-max is the maximum Doppler shift, which occurs when  = 0 degrees  To avoid distortion due to motion in the channel, the symbol rate must be greater than the inverse of coherence time. 2 16 9 D-max c f T  

27 Z. Ghassemlooy Coherence Distance  Coherence distance is the minimum distance between points in space for which the signals are mostly uncorrelated.  This distance is usually grater than 0.5 wavelengths, depending on antenna beamwidth and angle of arrival distribution.  At the BTS, it is common practice to use spacing of about 10 and 20 wavelengths for low-medium and high antenna heights, respectively (120 o sector antennas).

28 Z. Ghassemlooy Coherence Bandwidth (Bc) Effect of frequency selective fading on the received signal spectrum Signal bandwidth B s Freq. Power Describes frequency selective phenomenon of fast fading Coherence Bandwidth B c  Range of frequency over which channel is “flat”  It is the bandwidth over which two frequencies have a strong potential for amplitude correlation

29 Z. Ghassemlooy Estimation of Coherence Bandwidth Coherence bandwidth is estimated using the value of delay spread of the channel, s t For correlation > 0.9 For correlation > 0.5 Typical values of delay spreads for various types of terrain: t c B  2.0  t c B  02.0  Delay spread figures at 900 MHz Delay in microseconds Urban1.3 Urban, worst-case10 - 25 Suburban, typical0.2 - 0.31 Suburban, extreme1.96 - 2.11 Indoor, maximum0.27 Delay Spread at 1900 MHz Buildings, average0.07 - 0.094 Buildings, worst - case 1.47

30 Z. Ghassemlooy Channel Classification Based on Time-Spreading Flat Fading 1.B S < B C  T m < T s 2.Rayleigh, Ricean distrib. 3.Spectral chara. of transmitted signal preserved Frequency Selective 1.B S > B C  T m > T s 2.Intersymbol Interference 3.Spectral chara. of transmitted signal not preserved 4.Multipath components resolved Signal Channel freq. BSBS BCBC BCBC BSBS Channel Signal C. D. Charalambous et al

31 Z. Ghassemlooy Fading in Digital Mobile Communications If B s >> B c, then a notch appears in the spectrum. Thus resulting in inter-symbol interference (ISI). - To overcome this, an adaptive equaliser (AE) with inverse response may be used at the receiver. Training sequences are transmitted to update AE. If B s << B c, then flat fading occurs, resulting in a burst of error. - Error correction coding is used to overcome this problem.

32 Z. Ghassemlooy Multipath Delay Spread  First-arrival delay (τ A )  Mean excess delay

33 Z. Ghassemlooy Multipath Delay Spread  The standard deviation of the distribution of multipath signal amplitudes is called delay spread. For directive antenna is characterized by the rms delay spread of the entire delay profile, which is defined as: where  avg = Σ j P j  j,  j is the delay of the j th delay component of the profile P j = (power in the j th delay component) / (total power in all components Delay spread varies with the terrain with typical values for rural, urban and suburban areas:  rurals  2.0   urbans  0.3   suburbans  5.0 

34 Z. Ghassemlooy Multipath Delay Spread - Dispersion  The delay spread limits the maximum data rate: –No new impulses should arrive at the receiver before the last replica of the pervious impulse has perished. –Otherwise symbol spreads (dispersion) into its adjacent slot, thus resulting in Inter Symbol Interference (ISI)  The signal arrived at the receiver directly and phase shifted –Distorted signal depending on the phases of the different parts Transmitted symbols Received symbols

35 Z. Ghassemlooy Mitigation Techniques for the Multipath Fading Channel  Space diversity – –Signals at the same frequency using two or three antennas located several wavelengths a part. –Antennas are connected to two or three radio receivers. –The receiver will the strongest signal is elected –Disadvantage: Uses two or more antennas, therefore the need for a large site.  Frequency diversity – –Signals at different frequencies received by the same antenna very rarely fade simultaneously. Thus the use of several carrier frequencies or the use of a wideband signal to combat fading. –A single aerial connected to a number receiver, each tuned to a different frequency, whose outputs are connected in parallel. The receiver with the strongest instantaneous signal will provide the output. –Disadvantage: Uses two or more frequencies to transmit the same signal.

36 Z. Ghassemlooy Mitigation Techniques for the Multipath Fading Channel  Time diversity – Spread out the effects of errors through interleaving and coding  Multipath diversity –Consider the tapped delay line model of a channel shown previously –If multipaths can be put together coherently at the receiver, diversity improvement results –This is what the RAKE receiver does (see next viewgraph)

37 Z. Ghassemlooy RAKE Multipath Signal Processing R.E. Ziemer 2002

38 Z. Ghassemlooy System Design and Performance Prediction  Base station placement dependent on –Propagation environment –Anticipated geographic distribution of users –Economic considerations (minimize number of base stations) –Political and public opinion considerations –Traffic types (3G)  Performance figure of merit –Spectrum efficiency for voice: η v voice circuits/MHz/base station –Spectrum efficiency for information: η i bps/MHz/base station –Dropped call rate – fraction of calls ended prematurely

39 Z. Ghassemlooy Summary If there is a relative motion between transmitter and receiver (mobile) the result is Doppler shift If maximum Doppler shift is less than the data rate, there is “slow” fading channel. If maximum Doppler shift is larger than the data rate, there is “fast” fading channel. The random fluctuations in the received power are due to fading.

40 Z. Ghassemlooy Questions and Answers TTell me what you think about this lecture –f–fary@ieee.org NNext lecture: Modulation Techniques