A Primer on Cellular Network Analysis Using Stochastic Geometry
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This tutorial is intended as an accessible but rigorous first reference for someone interested in learning how to model and analyze cellular network performance using stochastic geometry. In particular, we focus on computing the signal-to-interference-plus-noise ratio (SINR) distribution, which can be characterized by the coverage probability (the SINR CCDF) or the outage probability (its CDF). We model base stations (BSs) in the network as a realization of a homogeneous Poisson point process of density $\lambda$, and compute the SINR for three main cases: the downlink, uplink, and finally the multi-tier downlink, which is characterized by having $k$ tiers of BSs each with a unique density $\lambda_i$ and transmit power $p_i$. These three baseline results have been extensively extended to many different scenarios, and we conclude with a brief summary of some of those extensions.
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Seasonal Statistics of Shannon Capacity in a Dynamical Poisson-Voronoi Cellular Network
Analysis of Shannon capacity statistics at handover, proximity, and interference epochs in a dynamical Poisson-Voronoi network with an analogy to seasonal fluctuations in signal quality.
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