Chapter 3. Mobile Radio Propagation
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1 Chapter 3 Mobile Radio Propagation Based on the slides of Dr. Dharma P. Agrawal, University of Cincinnati and Dr. Andrea Goldsmith, Stanford University Propagation Mechanisms Outline Radio Propagation Effects Free-Space Propagation Land Propagation Path Loss Fading: Slow Fading / Fast Fading Delay Spread Doppler Shift Co-Channel Interference
2 Speed, Wavelength, Frequency Light speed = Wavelength x Frequency = 3 x 10 8 m/s = 300,000 km/s System AC current FM radio Cellular Ka band satellite Ultraviolet light Frequency 60 Hz 100 MHz 800 MHz 0 GHz Hz Wavelength 5,000 km 3 m 37.5 cm 15 mm 10-7 m Types of Waves Sky wave Ionosphere (80-70 km) Mesosphere (50-80 km) Transmitter Space wave Ground wave Earth Receiver Stratosphere (1-50 km) Troposphere (0-1 km)
3 Radio Frequency Bands Classification Band Initials Frequency Range Characteristics Extremely low ELF < 300 Hz Infra low ILF 300 Hz - 3 khz Ground wave Very low VLF 3 khz - 30 khz Low LF 30 khz khz Medium MF 300 khz - 3 MHz Ground/Sky wave High HF 3 MHz - 30 MHz Sky wave Very high VHF 30 MHz MHz Ultra high UHF 300 MHz - 3 GHz Super high SHF 3 GHz - 30 GHz Space wave Extremely high EHF 30 GHz GHz Tremendously high THF 300 GHz GHz Propagation Mechanisms Reflection Propagation wave impinges on an object which is large as compared to wavelength - e.g., the surface of the Earth, buildings, walls, etc. Diffraction Radio path between transmitter and receiver obstructed by surface with sharp irregular edges Waves bend around the obstacle, even when LOS (line of sight) does not exist Scattering Objects smaller than the wavelength of the propagation wave - e.g.street signs, lamp posts
4 Radio Propagation Effects Building Direct Signal h b Diffracted Signal Reflected Signal h m Transmitter d Receiver Free-space Propagation h b h m Transmitter Distance d Receiver The received signal power at distance d: P r = AeG tp 4πd t where P t is transmitting power, A e is effective area, and G t is the transmitting antenna gain. Assuming that the radiated power is uniformly distributed over the surface of the sphere.
5 Antenna Gain For a circular reflector antenna Gain G = η ( π D / λ ) η = net efficiency (depends on the electric field distribution over the antenna aperture, losses, ohmic heating, typically 0.55) D = diameter thus, G = η (π D f /c ), c = λ f (c is speed of light) Example: Antenna with diameter = m, frequency = 6 GHz, wavelength = 0.05 m G = 39.4 db Frequency = 14 GHz, same diameter, wavelength = 0.01 m G = 46.9 db * Higher the frequency, higher the gain for the same size antenna Land Propagation The received signal power: P r = GtGr Pt L where G r is the receiver antenna gain, L is the propagation loss in the channel, i.e., L = L P L S L F Fast fading Slow fading Path loss
6 Path Loss (Free-space) Definition of path loss L P : L = P Pt P r Path Loss in Free-space: L, PF ( + 10 db) = log10 fc ( MHz) 0log d( km), where f c is the carrier frequency. This shows greater the f c, more is the loss. Path Loss (Land Propagation) Simplest Formula: L p = A d -α where A and α: propagation constants d : distance between transmitter and receiver α : value of 3 ~ 4 in typical urban area
7 Example of Path Loss (Free-space) Path Loss in Free-space Path Loss Lf (db) Distance d (km) fc=150mhz fc=00mhz fc=400mhz fc=800mhz fc=1000mhz fc=1500mhz α Path Loss (Urban, Suburban and Open areas) Urban area: L PU where [ h ( m) ] m ( db) = log f ( MHz) 13.8 log h ( m) α = + [ log h ( m) ] log d( km) Suburban area: LPS ( db) = LPU ( db) log Open area: L PO b c [ 1.1log10 fc ( MHz) 0.7] hm ( m) [ 1.56 log10 fc ( MHz) 0.8 ], 8.9[ log h m ] for f MHz m( ) 1.1, c 00, for 3.[ log 11.75h ( m) ] 4.97, for f 400MHz 10 m 10 fc 10 ( MHz) 8 c b [ h ( m) ] m for l arg e city small & medium city [ f ( MHz) ] log f ( ) ( db) = LPU ( db) 4.78 log c 10 c MHz 10
8 Path Loss Path loss in decreasing order: Urban area (large city) Urban area (medium and small city) Suburban area Open area Example of Path Loss (Urban Area: Large City) Path Loss in Urban Area in Large City Path Loss Lpu (db) Distance d (km) fc=00mhz fc=400mhz fc=800mhz fc=1000mhz fc=1500mhz fc=150mhz
9 Example of Path Loss (Urban Area: Medium and Small Cities) Path Loss in Urban Area for Small & Medium Cities Path Loss Lpu (db) Distance d (km) fc=150mhz fc=00mhz fc=400mhz fc=800mhz fc=1000mhz fc=1500mhz Example of Path Loss (Suburban Area) Path Loss in Suburban Area Path Loss Lps (db) Distance d (km) fc=150mhz fc=00mhz fc=400mhz fc=800mhz fc=1000mhz fc=1500mhz
10 Example of Path Loss (Open Area) Path Loss in Open Area 150 Path Loss Lpo (db) Distance d (km) fc=150mhz fc=00mhz fc=400mhz fc=800mhz fc=1000mhz fc=1500mhz Fading Fast Fading (Short-term fading) Slow Fading (Long-term fading) Signal Strength (db) Path Loss Distance
11 Slow Fading The long-term variation in the mean level is known as slow fading (shadowing or log-normal fading). This fading caused by shadowing. Log-normal distribution: -The pdfof the received signal level is given in decibels by p ( M ) = e πσ ( M M ) σ, 1 where M is the true received signal level m in decibels, i.e., 10log 10 m, M is the area average signal level, i.e., the mean of M, σ is the standard deviation in decibels Log-normal Distribution σ p(m) M M The pdf of the received signal level
12 Fast Fading The signal from the transmitter may be reflected from objects such as hills, buildings, or vehicles. When MS far from BS (no line of sight component), the envelope distribution of received signal is Rayleigh distribution. The pdf is r r σ p() r = e, r > 0 σ where σ is the standard deviation. Middle value r m of envelope signal within sample range to be satisfied by P( r rm) = 0.5. We have r m = P(r) 1.0 Rayleigh Distribution σ=1 0.4 σ= 0. σ= The pdf of the envelope variation r
13 Fast Fading (Continued) When MS is near BS (and there is a line of sight component), the envelope distribution of received signal is Rician distribution. The pdf is p r σ r + α σ () r = e I, r 0 0 rα σ where σ is the standard deviation, I 0 (x) is the zero-order Bessel function of the first kind, α is the amplitude of the direct signal Rician Distribution α= 0 (Rayleigh) α = 1 α = α = 3 Pdf p(r) σ = r The pdf of the envelope variation 8 r
14 Characteristics of Instantaneous Amplitude Level Crossing Rate: Average number of times per second that the signal envelope crosses the level in positive going direction. Fading Rate: Number of times signal envelope crosses middle value in positive going direction per unit time. Depth of Fading: Ratio of mean square value and minimum value of fading signal. Fading Duration: Time for which signal is below given threshold. Doppler Shift Doppler Effect: When a wave source and a receiver are moving towards each other, the frequency of the received signal will not be the same as the source. When they are moving toward each other, the frequency of the received signal is higher than the source. When they are opposing each other, the frequency decreases. Thus, the frequency of the received signal is f R = f C f D where f C is the frequency of source carrier, f D is the Doppler frequency. Doppler Shift in frequency: v f λ cosθ D = where v is the moving speed, λ is the wavelength of carrier. Signal MS Moving speed v
15 Delay Spread When a signal propagates from a transmitter to a receiver, signal suffers one or more reflections. This forces signal to follow different paths. Each path has different path length, so the time of arrival for each path is different. This effect which spreads out the signal is called Delay Spread. Moving Speed Effect V 1 V V 3 V 4 Signal strength Time
16 Delay Spread The signals from close by reflectors Signal Strength The signals from intermediate reflectors The signals from far away reflectors Delay Intersymbol Interference (ISI) Caused by time delayed multipath signals Has impact on burst error rate of channel Second multipath is delayed and is received during next symbol For low bit-error-rate (BER) 1 R < τ d R (digital transmission rate) limited by delay spread τ d.
17 Intersymbol Interference (ISI) Transmission signal 1 1 Time 0 Received signal (short delay) Time Propagation time Received signal (long delay) Delayed signals Time Coherence Bandwidth Coherence bandwidth B c : Represents correlation between fading signal envelopes at frequencies f 1 and f. Is a function of delay spread. Two frequencies that are larger than coherence bandwidth fade independently. Concept useful in diversity reception Multiple copies of same message are sent using different frequencies.
18 Cochannel Interference Cells having the same frequency interfere with each other. r d is the desired signal r u is the interfering undesired signal β is the protection ratio for which r d βr u (so that the signals interfere the least) If P(r d βr u ) is the probability that r d βr u, Cochannel probability P co = P(r d βr u )
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