Mixture-Based Modeling of Spatially Correlated Interference in a Poisson Field of Interferers

As the interference in PPP-based wireless networks exhibit spatial correlation, any joint analysis involving multiple spatial points either end up with numerical integrations over \mathbb {R}^{2} or become analytically too intractable. To tackle these issues, we present an alternate approach which...

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Bibliographic Details
Published in:IEEE communications letters 2017-11, Vol.21 (11), p.2496-2499
Main Author: Ghosh, Arindam
Format: Article
Language:English
Subjects:
Analytical models
Correlation
Interference
mixture distribution
Numerical models
Poisson point process
Random variables
SIR joint CCDF
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Summary:As the interference in PPP-based wireless networks exhibit spatial correlation, any joint analysis involving multiple spatial points either end up with numerical integrations over \mathbb {R}^{2} or become analytically too intractable. To tackle these issues, we present an alternate approach which not only offers a simpler analytical structure, but also closely mimics the PPP characteristics. This approach at its core models the correlated interferences using a correlation framework constructed using random variable mixtures . In addition, a correlation framework based on the more standard method of linear combination of random variables is also presented for comparison purpose. The performance of these models is studied by deriving the joint complementary cumulative distribution function of signal-to-interference ratios at N arbitrary points. The plots are found to tightly approximate the exact PPP-based results, with the tightness depending on the values of \lambda p (interferer intensity), \alpha (path loss exponent), and N . The applicability of the mixture-based model is also shown for a multi-antennae MRC receiver where only major derivation steps that simplify the outage probability analysis are shown.
ISSN:1089-7798
1558-2558
DOI:10.1109/LCOMM.2017.2740922