KAUST Digital Communication EE – 242
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Transcript of KAUST Digital Communication EE – 242
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Prepared by: Ahmad Dehwah & Emad Al-Hemyari 1
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Introduction. Approaches of analyzing the outage. Motivation and previous work System Model. Conclusion. References. Q & A.
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Outage models are applied in wireless communication systems, which are subjected to ◦ fading ◦ and other interfering signalsto predict their performance. The performance of a given system is considered to be unacceptable when the Signal to Interference plus Noise Ratio (SINR) is below a given threshold. i.e,
SINR<z0
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Different analysis ways to approach this problem can be followed depending on the way an outage model is defined:
The simplest definition introduced before: SINR<z0
Interference-limited model: SIRSignal power < defined power protection ratio
neglecting the receiver background noise and the thermal noise Noise-Limited model: where noise is treated as co-channel
interference. Signal power< the powers of (total interference + noise) by
power protection margins Minimum Signal Power Constraint:
signal power< total interference power by a protection ratio andSignal power<minimum power level in the presence of thermal noise.
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Such reliability study of outage is conducted in terms of error probability given that the SINR is above the given threshold.
Pr(Error|SINR>z0)
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The motivation behind this study of outage models:
No closed form expression of the probability of outage for a sum of K multiple interfering signals with different powers of the same distribution.
Previous work either considered limited number of interferers or numerical approximations.
Different communication systems require different conditions on the definition of the outage to achieve certain reliability.
Performance analysis of BPSK system through a Rayleigh fading channel is conducted in terms of
Pr(Error|SINR>z0)rather than just studying the probability of outage.
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The signal at the receiver front is of the following form:
Where ◦ Sk(t): is the kth interfering signal (k=0, 1, …, K).◦ n(t): is a Gaussian noise of two sided power
spectral density N0/Tb.◦ τ: is a uniform time offset of S(t) over [0,2π].
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There are three combinations to consider the SINR components according to our system model.
-Signal -Interference - Noise
◦ Each of these parameters can be either deterministic or random.
Signal Random Random Random
Interference
constant Random Random
Noise constant constant Random
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The kth interfering signal (k=0, 1, …., K) is:
Where Sk: is the average received power Xk: is the Rayliegh fading level of the kth signal
with . φk: is uniform over [0,2π] and φ0=0. Xk and φk are mutually independent random
variables Ψ(t): is the shaping waveform
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Now the decision variable at the output of the correlator is given by:
Where η: is Gaussian Random variable with variance . Ik: is the multiple access interference component
due to the kth signal given by:
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Q & A
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1. A. Annamalai, C. Tellambura, and V. K. Bhargava, .Simple and accurate methods for outage analysis in cellular mobile radio systems-a uni_ed approach,. IEEE Trans. Commun., vol. 49, pp. 303-316, Feb. 2001.
http://ieeexplore.ieee.org/xpl/freeabs_all.jsp?arnumber=905889 2. D. Dardari, V. Tralli, and R. Verdone, .On the capacity of slotted Aloha with
Rayleigh fading: the role played by the number of interferers,. IEEE Commun. Lett., vol. 4, pp. 155-157, May 2000.
http://ieeexplore.ieee.org/xpl/freeabs_all.jsp?arnumber=846496 3. K. A. Hamdi, . Exact probability of error of BPSK communication links subjected
to asynchronous interference in Rayleigh fading environment,. IEEE Trans. Commun., vol. 50, pp. 1577 - 1579, Oct. 2002
http://ieeexplore.ieee.org/xpl/freeabs_all.jsp?arnumber=1044597 4. K. A. Hamdi, On the reliability of outage modelshttp://cat.inist.fr/?aModele=afficheN&cpsidt=18184207
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