程序代写 ECE5884 Wireless Communications @ Monash Uni. August 8, 2022 1 / 17

ARC Future Fellow at The University of Melbourne Sessional Lecturer at Monash University
August 8, 2022
ECE5884 Wireless Communications @ Monash Uni. August 8, 2022 1 / 17

ECE5884 Wireless Communications Week 3 Workshop: Wireless Channel Models

Course outline
This week: Ref. Ch. 3 of [Goldsmith, 2005]
● Week 1: Overview of Wireless Communications
● Week 2: Wireless Channel (Path Loss and Shadowing)
● Week 3: Wireless Channel Models
● Week 4: Capacity of Wireless Channels
● Week 5: Digital Modulation and Detection
● Week 6: Performance Analysis
● Week 7: Equalization
● Week 8: Multicarrier Modulation (OFDM)
● Week 9: Diversity Techniques
● Week 10: Multiple-Antenna Systems (MIMO Communications) ● Week 11: Multiuser Systems
● Week 12: Guest Lecture (Emerging 5G/6G Technologies)
ECE5884 Wireless Communications @ Monash Uni. August 8, 2022 2 / 17

Doppler effect and delay
Figure 1: Illustration of the Doppler effect.
vc8 Dopplerfrequency:fD = λcosθ whereλ= f andc=3×10 m/s (1)
1 Doppler effect. 2 Scatters.
⎞ ⎤⎥ ⎢⎣⎝ i=0 ⎠ ⎥⎦
αi (t ) is fading (also a function of path loss and shadowing). φi (t ) depends on delay and Doppler. These two random processes are independent.
⎡⎢ ⎛ N ( t ) − 1
Receivedsignal r(t)=R⎢ ∑ αi(t)e−jφi(t)u(t−τi(t)) ej2πfct⎥ (2)
ECE5884 Wireless Communications @ Monash Uni. August 8, 2022 3 / 17

Fast/slow fading (w.r.t. time)
Figure 2: Received signal.
● In Coherence time (Tc ), channel is not varying.
1 Fast fading: Tc < Ts where Ts is the transmitted symbol duration. 2 Slow fading: Tc ≫ Ts, e.g. Shadowing (Log-normal model). ECE5884 Wireless Communications @ Monash Uni. August 8, 2022 4 / 17 Flat/frequency-selective fading (w.r.t. frequency) Figure 3: Wireless channel as a filter. ● In coherence bandwidth (Bc ), channel response is not varying. 1 Flat fading: Bs ≪ Bc where Bs is the signal bandwidth. 2 Frequency-selective fading: Bs ≫ Bc , OFDM (Week 8). ECE5884 Wireless Communications @ Monash Uni. August 8, 2022 5 / 17 Intersymbol interference (ISI) ISI is a form of distortion of a signal in which one symbol interferes with subsequent symbols. (a) One symbol Tx (No ISI). (b) Four symbols Tx (ISI). Figure 4: Illustration of ISI effect. ● Send the next symbol after the delay spread, Tm, to avoid ISI. https://www.telecomhall.net/t/what- is- isi- inter- symbol- interference- in- lte/6370 ECE5884 Wireless Communications @ Monash Uni. August 8, 2022 6 / 17 Narrowband/wideband communications 1 Narrowband communications use a narrow bandwidth; are used in a slower form of communication as we allow a longer time for a symbol. 2 Wideband communications use a higher bandwidth; apply Wifi, 4G LTE and beyond, HSPA. ● OFDM (Week 8) ECE5884 Wireless Communications @ Monash Uni. August 8, 2022 7 / 17 Multipath fading 1 Fast fading: Ts ≪ Tc 2 Flat fading: Bs ≪ BD 3 Narrowband comm.: Tm ≪ Ts (a) Combined all. (b) Narrowband fading. Figure 5: Ref. Ch. 3 of [Goldsmith, 2005]. ECE5884 Wireless Communications @ Monash Uni. August 8, 2022 8 / 17 System model Thereceivedsignal: r(t)=hs(t)+n(t) (3) ● h− the multipath channel gain, usually a complex number; s(t)− the transmit signal with Ps power; and n(t)− the additive noise. The received signal power: Multipath channel gain: Channel envelop: Pr = ∣h∣2Ps (4) h = hr + jhi = z ejθ (5) ∣h∣ = z = hr2 + hi2 (6) ● Additive white Gaussian noise: n(t ) = nr + jni ; noise power is constant for all frequencies; n(t) follows circularly symmetric complex Gaussian distribution with zero mean and N0 variance, i.e., n(t) ∼ CN(0,N0) where nr ∼ N(0,No/2) and ni ∼ N(0,No/2). Instantaneous SNR: γ = Noise power = N Signal power ∣h∣2Ps We need distributions of ∣h∣ and ∣h∣2 – Multipath fading models!!! ECE5884 Wireless Communications @ Monash Uni. August 8, 2022 Rayleigh distribution ● Rayleigh fading is a model that can be used to describe the form of fading that occurs when multipath propagation exists with no Los component. h=hr+jhi=zejθ and ∣h∣=z= hr2+hi2 (8) ● When hr and hi are two independent and identical distributed (i.i.d.) Gaussian random variables with mean zero and variance σ2, i.e., hr,hi ∼N(0,σ2), 1 The average envelope power is Ωp = 2σ2. √ hr2 + hi2 is Rayleigh distributed; 22 2 the envelop ∣h∣ = z = fZ(z)= Ω e Ωp andFZ(z)=1−e Ωp 2z −z −z p 3 the power ∣h∣2 is Exponentially distributed; 1−t −t fZ2(t)= Ω e Ωp andFZ2(t)=1−e Ωp ECE5884 Wireless Communications @ Monash Uni. August 8, 2022 Rician distribution ● The channel has a LOS component with a much larger signal power than the other multipath components. ● hr ∼ N(mr,σ2) and hi ∼ N(mi,σ2); ● 2σ2 is the average power in the non-LOS multipath components and s2 = mr2 + mi2 is the power in the LOS component. 1 Average envelope power: Ωp = s2 + 2σ2 2 the envelopis Rician/Ricean/Rice distributed; z −(z2+s2) zs fZ(z)=σ2e 2σ2 I0(σ2) (11) 3 The Rice factor K (fading parameter): K = s2 where K = 0 for no LoS; 2σ2 K → ∞ for no scatter; and a small K implies severe fading. 􏰂 fZ(z)= wheres2=KΩp andσ2= Ωp ⎛ 􏰄K(K +1)⎞ e Ωp I0 2z􏰄􏰃 2(K +1)z −K−(K+1)z K +1 2(K +1) ECE5884 Wireless Communications @ Monash Uni. August 8, 2022 Nakagami-m distribution 1 The Nakagami distribution was selected to fit empirical data and is known to provide a closer match to some measurement data than either the Rayleigh, Ricean, or log-normal distributions. 2 the envelop ∣h∣ is Nakagami-m distributed; m2m−1 2 mz−mz 1 fZ(z)=2( ) e Ωp ;m≥ 3 Average envelope power: Ωp ● m = 1: Rayleigh distribution. ● m = 1/2: a one-sided Gaussian distribution ● m → ∞: approaches an impulse (no fading). ● m ≈ (K +1)2 : approximation for Rician distribution. (2K +1) 4 the power ∣h∣2 is Gamma distributed; mz−mz 1 fZ2(z)=( ) e Ωp ;m≥ Ωp Γ(m) 2 ECE5884 Wireless Communications @ Monash Uni. August 8, 2022 SNR outage probability ● The SNR outage probability is the probability that the SNR γ falls below a certain predetermined threshold SNR γth Pout =Pr[γ<γth] (15) ∣h∣2Ps 2 N0γth N0γth =Pr[ N <γth]=Pr[∣h∣ < P ]=F∣h∣2 ( P ) (16) ● For Rayleigh fading (use (10)) Ps γth N0 γth 1 Pout =1−e− 2σ2 =1−e−(2σ2 Ps ) =1−e−(2σ2 γ ̄ ) (17) γth 1 γth 1 Whenγ ̄→∞;Pout →1−(1−2σ2γ ̄)=2σ2γ ̄ Asymptoticanalysis (18) where γ ̄ = Ps (we sometime call this as the average transmit SNR!). ● Similarly, you can evaluate the SNR outage probabilities for Rician and Nakagami-m fading channels! ECE5884 Wireless Communications @ Monash Uni. August 8, 2022 13 / 17 SNR outage probability 102 101 100 10-1 10-2 10-3 10-4 10-5 Outage probability Analytical Asymptotic -10 0 10 20 30 40 50 ECE5884 Wireless Communications @ Monash Uni. August 8, 2022 14 / 17 Figure 6: Example. SNR outage probability 102 101 100 10-1 10-2 10-3 10-4 10-5 Outage probability Analytical Asymptotic -10 0 10 20 30 40 50 ECE5884 Wireless Communications @ Monash Uni. August 8, 2022 15 / 17 Figure 7: Example. References A. Goldsmith, Wireless Communications, Cambridge University Press, USA, 2005. ECE5884 Wireless Communications @ Monash Uni. August 8, 2022 16 / 17 Thank You! See you again 􏰀 程序代写 CS代考加微信: powcoder QQ: 1823890830 Email: powcoder@163.com

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